L O G A R I T H M S.

INTRODUCTION.

THE labour and time required for performing the arithmetical operations of multiplication, division, and the extraction of roots, were at one time considerable obstacles to the improvement of various branches of knowledge, and in particular the science of astronomy. But about the end of the 16th century, and the beginning of the 17th, several mathematicians be-

gan to consider by what means they might simplify these operations, or substitute for them others more easily performed. Their efforts produced some ingenious contrivances for abridging calculations; but of these the most complete by far was that of John Napier Baron of Merchiston in Scotland, who invented a system of numbers called logarithms, which were so adapted to the numbers to be multiplied, or divided, that these being arranged in the form of a table, each opposite to the number

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number called its logarithm, the product of any two numbers in the table was found by the addition of their logarithms; and, on the contrary, the quotient arising from the division of one number by another was found by the subtraction of the logarithm of the divisor from that of the dividend; and similar simplifications took place in the still more laborious operations of involution and evolution. But before we proceed to relate more particularly the circumstances of this invention, it will be proper to give a general view of the nature of logarithms, and of the circumstances which render them of use in calculation.

Let there be formed two series of numbers, the one constituting a geometrical progression, the first term of which is unity or 1, and the common ratio any number whatever, and the other an arithmetical progression, the first term of which is 0, and the common difference also any number whatever; (but as a particular example we shall suppose the common ratio of the geometrical series to be 2, and the common difference of the arithmetical series 1), and let the two series be written opposite to each other in the form of a table, thus:

Geom. Prog. Arith. Prog.
1 0
2 1
4 2
8 3
16 4
32 5
64 6
128 7
256 8
512 9
1024 10
2048 11
4096 12
&c. &c.

The two series being thus arranged, the terms in the arithmetical series are called the logarithms of the corresponding terms of the geometrical series; that is, 0 is the logarithm of 1, and 1 is the logarithm of 2, and 2 is the logarithm of 4, and 3 that of 8, and so on.

From the manner in which the two series are related to each other, it will readily appear by induction that the logarithms of the terms of the geometrical series have the two following properties:

1. The sum of the logarithms of any two numbers or terms in the geometrical series is equal to the logarithm of that number, or term of the series, which is equal to their product.

For example, let the terms of the geometrical series be 4 and 32; the terms of the arithmetical series corresponding to them (that is, their logarithms) are 2 and 5; now the product of the numbers is 128, and the sum of their logarithms is 7; and it appears by inspection of the two series, that the latter number is the logarithm of the former, agreeing with the proposition we are illustrating. In like manner, if the numbers or terms of the geometrical series be 16 and 64, the logarithms of which are 4 and 6, we find from the table that 10 = 4 + 6 is the logarithm of 1024 = 16 \times 64; and so of any other numbers in the table.

2. The difference of the logarithms of any two numbers, or terms of the geometrical series, is equal to the logarithm of that term of the series which is equal to the quotient arising from the division of the one number by the other.

Take for example the terms 128 and 32, the logarithms of which are 7 and 5; the greater of these numbers divided by the less is 4, and the difference of their logarithms is 2; and by inspecting the two series, this last number will be found to be the logarithm of the former. In like manner, if the terms of the geometrical series be 1024 and 16, the logarithms of which are 10 and 4, we find that 1024 \div 16 = 64, and that 10 - 4 = 6; now it appears from the table that the latter number, viz. 6, is the logarithm of the former 64.

These two properties of logarithms, the second of which indeed is an immediate consequence of the first, enable us to find with great facility the product or the quotient of any two terms of a geometrical series to which there is adapted an arithmetical series, so that each number has its logarithm opposite to it, as in the preceding short table. For it is evident, that to multiply two numbers we have only to add their logarithms, and opposite to that logarithm which is the sum we shall find the product required. Thus, to multiply 16 by 128; to the logarithm of 16, which is 4, we add the logarithm of 128, which is 7, and opposite to the sum 11, we find 2048, the product sought. On the other hand, to divide any number in the table by any other number, we must subtract the logarithm of the divisor from that of the dividend, and look for the remainder among the logarithms, and opposite to it we shall find the number sought. Thus, to divide 2048 by 128, from 11, which is the logarithm of 2048 we subtract 7, the logarithm of 128, and opposite to the remainder 4 we find 16, the quotient sought.

Let us now suppose any number of geometrical means to be interposed between each two adjoining terms of the preceding geometrical series, and the same number of arithmetical means between every two adjoining terms of the arithmetical series; then, as the results will still be a geometrical and an arithmetical series, the interpolated terms of the latter will be the logarithms of the corresponding terms of the former, and the two new series will have the very same properties as the original series.

If we suppose the number of interpolated means to be very great, it will follow that among the terms of the resulting geometrical series, some one or other will be found nearly equal to any proposed number whatever. Therefore, although the preceding table exhibits the logarithms of 1, 2, 4, 8, 16, &c. but does not contain the logarithms of the intermediate numbers, 3, 5, 6, 7, 9, 10, &c. yet it is easy to conceive that a table might be formed by interpolation which should contain, among the terms of the geometrical series, all numbers whatever to a certain extent, (or at least others very nearly equal to them) together with their logarithms. If such a table were constructed, or at least if such terms of the geometrical progression were found together with their logarithms, as were either accurately equal to, or coincided nearly with, all numbers

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bers within certain limits, (for example between 1 and 100000) then, as often as we had occasion to multiply or divide any numbers contained in that table we might evidently obtain the products or quotients by the simple operations of addition and subtraction.

The first invention of logarithms has been attributed by some to Longomontanus, and by others to Johes Burge, two mathematicians who were contemporary with Lord Napier; but there is no reason to suppose that either of these anticipated him, for Longomontanus never published any thing on the subject, although he lived thirty-three years after Napier had made known his discovery; and as to Burge, he is indeed known to have printed a table containing an arithmetical and a geometrical progression written opposite to each other, so as to form in effect a system of logarithms of the same kind as those invented by Napier, without however explaining their nature and use, although it appears from the title he intended to do so, but was probably prevented by some cause unknown to us. But this work was not printed till 1620, six years after Napier had published his discovery.

It is therefore with good reason that Napier is now universally considered as the first, and most probably as the only inventor. This discovery he published in the year 1614 in a book entitled Mirifici Logarithmorum Canonis Descriptio, but he referred the construction of the numbers till the opinion of the learned concerning his invention should be known. His work contains a table of the natural sines and cosines, and their logarithms for every minute of the quadrant, as also the differences between the logarithmic sines and cosines, which are in effect the logarithmic tangents. There is no table of the logarithms of numbers; but precepts are given, by which they, as well as the logarithmic tangents, may be found from the table of natural and logarithmic sines.

In explaining the nature of logarithms, Napier supposes some determinate line which represents the radius of a circle to be continually diminished, so as to have successively all possible values, and thus to be equal to every sine, one after another, throughout the quadrant. And he supposes this diminution to be effected by a point moving from one extremity towards the other extremity, (or rather some point very near it), with a motion that is not uniform, but becomes slower and slower, and such, that if the whole time between the beginning and the end of the motion be conceived to be divided into a very great number of equal portions, the decrements taken away in each of these shall be to one another as the respective remainders of the line. According to this mode of conceiving the line to decrease, it is easy to shew that at the end of any successive equal intervals of time from the beginning of the motion, the portions of the line which remain will constitute a decreasing geometrical progression.

Again, he supposes another line to be generated by a point which moves along it equably, or which passes over equal intervals of it in equal times. Thus the portions of the line generated at the end of any equal successive intervals of time from the beginning of the motion will form a series of quantities in arithmetical progression. Now if the two motions be supposed to begin together, at the end of any equal intervals of time the remainders of the one line will form a series of

quantities in geometrical progression, and the corresponding portions generated of the other line, will constitute a series in arithmetical progression, so that the latter will be the logarithms of the former. And as the terms of the geometrical progression decrease continually from radius, which is the greatest term, to 0, while the terms of the corresponding arithmetical progression increase from 0 upwards, according to Napier's system the logarithm of radius is 0, and the logarithms of the sines from radius down to 0, are a series of numbers increasing from 0 to infinite.

The velocities or degrees of quickness with which the motions commence may have to each other any ratio whatever, and by assuming different ratios we shall have different systems of logarithms. Napier supposed the velocities to be equal; but the system of logarithms produced in consequence of this assumption having been found to have some disadvantages, it has been long disused, and a more convenient one substituted instead of it, as we shall presently have occasion to explain.

Napier's work having been written in Latin was translated into English by Mr Edward Wright, an ingenious mathematician of that period, and the inventor of the principles of what is commonly though erroneously called Mercurator's sailing. The translation was sent to Napier for his perusal, and returned with his approbation, and the addition of a few lines, intimating that he intended to make some alteration in the system of logarithms in a second edition. Mr Wright died soon after he received back his translation; but it was published after his death, in the year 1616, accompanied with a dedication by his son to the East India Company, and a preface by Henry Briggs, who afterwards distinguished himself so much by his improvement of logarithms. Mr Briggs likewise gave in this work the description and draught of a scale which had been invented by Wright, as also various methods of his own for finding the logarithms of numbers, and the contrary, by means of Napier's table, the use of which had been attended with some inconvenience on account of its containing only such numbers as were the natural sines to every minute of the quadrant and their logarithms. There was an additional inconvenience in using the table, arising from the logarithms being partly positive and partly negative; the latter of these was, however, well remedied by John Speidell in his New Logarithms, first published in the year 1619, which contained the sines, cosines, tangents, cotangents, secants, and cosecants, and given in such a form as to be all positive; and the former was still more completely removed by an additional table, which he gave in the sixth impression of his work, in the year 1624, and which contained the logarithms of the whole numbers 1, 2, 3, 4, &c. to 1000, together with their differences and arithmetical complements, &c. This table is now commonly called hyperbolic logarithms, because the numbers serve to express the areas contained between a hyperbola and its asymptote, and limited by ordinates drawn parallel to the other asymptote. This name, however, is certainly improper, as the same spaces may represent the logarithms of any system whatever, (see FLUXIONS § 152. Ex. 5.)

In 1719 Robert Napier, son of the inventor of logarithms, published a second edition of his father's Logarithmorum Canonis Descriptio. And along with this

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this the promised Logarithmorum Canonis Constructio, and other pieces written by his father and Mr Briggs. An exact copy of the same two works in one volume was also printed in 1620 at Lyons in France. In 1618 or 1619 Benjamin Ursinus, mathematician to the elector of Brandenburg, published Napier's tables of logarithms in his Curfus Mathematicus, to which he added some tables of proportional parts; and in 1624 he printed his Trigonometria, with a table of natural sines, and their logarithms of the Napierian kind and form, to every ten seconds of the quadrant.

In the same year, 1624, the celebrated John Kepler published at Marburg logarithms of nearly the same kind, under the title of Chilias Logarithmorum ad totidem Numeros Rotundos, præmissa Demonstratione legitima Ortus Logarithmorum eorumque Usus, &c. and in the following year he published a supplement to this work. In the preface to this last he says, that several of the professors of mathematics in Upper Germany, and more especially those of them who were somewhat advanced in years, and were grown averse to new methods of reasoning that carried them out of the old doctrines and principles with which habit had rendered them familiar, doubted in some degree whether Napier's demonstration of the property of logarithms was perfectly true, and whether the application of them to trigonometrical calculations might not be unsafe and lead the calculator who should trust in them to erroneous results; and in either case, whether the doctrine were true or not, they considered Napier's demonstration of it as illegitimate and unsatisfactory. This opinion induced Kepler to compose the above-mentioned work, in which the whole doctrine is treated in a manner strictly geometrical, and free from the considerations of motion which the German mathematicians had objected to (and not without reason) in Napier's mode of treating the subject.

On the publication of Napier's logarithms, Mr Henry Briggs, some time professor of geometry in Greibam college London, and afterwards Savilian professor of geometry at Oxford (whom we have already mentioned) applied himself with great earnestness to their study and improvement, and it appears that he had projected at an early period that advantageous change in the system which has since taken place. From the particular view which Napier took of the subject, and the manner in which he conceived logarithms to be generated, it happened that in his system, the logarithms of a series of numbers which increased in a decuple ratio, (as 1, 10, 100, 1000, &c.) formed a decreasing arithmetical series, the common difference of the terms of which was 2.3205851. But it occurred to Briggs that it would be better and more conformable to the received decimal notation, to adopt a system in which the logarithms of the terms of such a geometrical series should differ from each other by unity or 1. This idea Briggs communicated to the public in his lectures, and also to Napier himself. He even went twice to Edinburgh to see him, and to converse with him upon the subject; and on his first visit Napier said that he had also formerly thought of the same improvement, but that he chose to publish the logarithms he had previously calculated, till such time as his health and convenience would allow him to make others more commodious. And whereas in the change which Briggs proposed, it

was intended to make the logarithms of the sines to increase from 0 (the logarithm of radius) to infinity, while the sines themselves should decrease, it was suggested to him by Napier that it would be better to make them increase so that 0, instead of being the logarithm of radius, should be the logarithm of 1; and that 100000, &c. should be the logarithm of radius; and this Briggs admitted would be an improvement; and having changed the numbers he had already calculated so as to make them suit Napier's modification of his plan, he returned with them next year to Edinburgh, and submitted them to his perusal.

It appears therefore that Briggs was the inventor of this improved system of logarithms which has since been universally adopted, and that the only share that Napier had in it was his suggesting to Briggs to begin with the low number 1, and to make the logarithms, or the artificial numbers, as Napier had always called them, to increase with the natural numbers, instead of decreasing, which made no alteration in the figures, but only in their affections or signs, changing them from negative to positive.

On Briggs's return from Edinburgh, in 1617, he printed the first thousand logarithms to eight places of figures, besides the index, with the title of Logarithmorum Chilias prima; but these seem not to have been published till after the death of Napier, which happened in 1618, for in his preface he expresses a hope, that the circumstances which led to a change in the system would be explained in Napier's posthumous work, which was presently to appear. But although Napier had intimated in a note he had given in Wright's translation of the Canon Mirificus, as well as his Rabdologia, printed in 1617, that he intended to alter the scale, yet he altogether omits to state that Briggs either was the first to think of this improvement, or at least to publish it to the world. And as the same silence on this point was observed in Napier's posthumous work published in 1619 by his son, Briggs took occasion in the preface to his Arithmetica Logarithmica to assert his claims to the improvement he had now carried into execution.

The studied silence which Napier seems to have observed respecting the improvement of the system, which Briggs had communicated to him, has given just reason to suspect that he wished to be considered as the author of that improvement, as well as the original inventor. But although it is possible that he thought of it as soon as Briggs, it would seem to have been no more than justice, if, when announcing his intended change of the scale, he had acknowledged that the same idea had occurred to Briggs as well as to himself.

In 1620 Mr Edmund Gunter published his Canon of Triangles, which contains the artificial or logarithmic sines and tangents to every minute to seven places of figures besides the index, the logarithm of radius being 10. These logarithms are of the kind which had been agreed upon between Napier and Briggs, and they were the first tables of logarithmic sines and tangents that were published of this sort. Gunter also in 1623 reprinted the same in his book de Sectore et Radio, together with the Chilias prima of Briggs; and in the same year he applied the logarithms of numbers, sines, and tangents, to straight lines drawn upon a ruler. This instrument is now in common use for navigation and other purposes, and is commonly called Gunter's scale.

The

The discoveries in Logarithms were first carried to France by Mr Edmund Wingate, but not first of all as he says in the preface to his book. He published at Paris in 1624 two small tracts in the French language upon logarithms, and these were reprinted with improvements at London in 1626.

In the year 1624, Briggs published his Arithmetica Logarithmica, a stupendous work considering the short time he had been in preparing it. He here gives the logarithms of 30000 natural numbers to fourteen places of figures, besides the index; namely, from 1 to 20000, and from 90000 to 100000, together with the differences of the logarithms. He also gives an ample treatise on their construction and use, and he earnestly solicits others to undertake the computation of the intermediate numbers, offering to give instructions, and paper ready ruled for that purpose, to any persons inclined to contribute to the completion of so valuable a work. By this invitation he had hopes of collecting materials for the logarithms of the intermediate 70000 numbers, while he should employ his time upon the Canon of Logarithmic sines and tangents, and so carry on both works at once.

Soon after this, Adrian Vlacz or Vlack of Gouda in Holland completed the intermediate 70 chiliads, and republished the Arithmetica Logarithmica in 1627 and 1628, with these intermediate numbers, making in all, the logarithms of all numbers to 100,000, but only to 10 places of figures. To these was added a table of artificial sines, tangents, and secants, to every minute of the quadrant.

Briggs himself lived also to complete a table of logarithmic sines and tangents, to the 100th part of every degree, to fourteen places of figures besides the index, together with a table of natural sines to the same parts to fifteen places, and the tangents and secants of the same to ten places, with the construction of the whole. But his death, which then happened, prevented him from completing the application and uses of them. However, when dying, he committed the performing of this office to his friend Henry Gellibrand, who accordingly added a preface, and the application of the logarithms to plane and spherical trigonometry. The work was called Trigonometria Britannica, and was printed at Gouda in the year 1633 under the care of Adrian Vlacz.

In the same year, 1633, Adrian Vlacz printed a work of his own, called Trigonometria Artificialis, five Magnus Canon Triangulorum Logarithmicus ad Decadas Secundorum Serupulorum Constructus. This work contains the logarithmic sines and tangents to 10 places of figures, with their differences for every 10 seconds in the quadrant. It also contains Briggs's table of the first 20000 logarithms to ten places, besides the index, with their differences; and to the whole is prefixed a description of the tables and their applications, chiefly extracted from Briggs's Trigonometria Britannica, which we have already mentioned.

Gellibrand published also, in 1635, An Institution Trigonometrical, containing the logarithms of the first 10,000 numbers, with the natural sines, tangents, and secants, and the logarithmic sines and tangents for degrees and minutes; all to seven places of figures besides the index.

The writers, whose works we have hitherto noticed, were for the most part computors of logarithms. But the system best adapted to practice being now well ascertained, and the labour of constructing the table accomplished, succeeding writers on the subject have had little more to do than to give the tables in the most convenient form. It is true that, in consequence of the numerous discoveries which were afterwards made in mathematics, particularly in the doctrine of series, great improvements were made in the method of computing logarithms; but these, for the most part, came too late to be of use in the actual construction of the table, although they might be applied with advantage to verify calculations previously performed by methods much more laborious.

As it is of importance that such as have occasion to employ logarithms should know what works are held in estimation on account of their extent and accuracy, we shall enumerate the following.

1. Sherwin's Mathematical Tables, in 8vo. These contain the logarithms of all numbers to 101,000; and the sines, tangents, secants, and versed sines, both natural and logarithmic, to every minute of the quadrant. The third edition, printed in 1742, which was revised by Gardiner, is esteemed the most correct; but, in the fifth edition, the errors are so numerous, that no dependence can be placed upon it when accuracy is required.

2. Gardiner's Tables of Logarithms for all numbers to 101,000, and for the sines and tangents to every ten seconds of the quadrant; also for the sines of the first 72 minutes to every single second, &c. This work, which is in 4to, was printed in 1742, and is held in high estimation for its accuracy.

3. An edition of the same work, with some additions, printed in 1770 in Avignon in France. The tables in both editions are to seven places of figures.

4. Tables Portatives de Logarithmes, publiées à Londres, par Gardiner, augmentées et perfectionnées dans leur disposition, par M. Callet.—This work is most beautifully printed in a small octavo volume, and contains all the tables in Gardiner's quarto volume; with some additions and improvements.

5. Dr Hutton's Mathematical Tables, containing common hyperbolic and logitific logarithms, &c.—This work has passed through several editions, under the care of the learned author: it is perhaps the most common of any in this country, and is deservedly held in the highest estimation, both on account of its accuracy, and the very valuable information it contains respecting the history of logarithms, and other branches of mathematics connected with them.

6. Taylor's Table of Logarithmic Sines and Tangents to every second of the quadrant; to which is prefixed a table of logarithms from 1 to 100,000, &c.—This is a most valuable work; but being a very large quarto volume, and also very expensive, it is less adapted to general use than the preceding, which is an octavo, and may be had at a moderate price.

7. Tables portatives des logarithmes, contenant les logarithmes des nombres depuis 1 jusqu'à 108,000; les logarithmes des sinus et tangentes, de seconde en seconde pour les cinq premiers degrés, de dix en dix secondes pour tous les degrés du quart de cercle, et suivant la nouvelle

Nature of nouvelle division centesimale de dix-millième en dix mil-logarithmes, &c. par Callet.—This work, which is in octavo, &c. may be reasonably expected to be very accurate, it being printed in the stereotype manner, by Didot.

In addition to these, it is proper that we should notice a stupendous work relating to logarithms, originally suggested by the celebrated Carnot, in conjunction with Prieur de la Côte d'Or, and Brunet de Montpellier, about the beginning of the French revolution. This enterprise was committed, in the year 1794, to the care of Prony, a French mathematician of great eminence, who was not only to compose tables which should leave nothing to be desired with respect to accuracy, but to make them the most extended and most striking monument of calculation which had ever been executed or ever imagined*. It appears that two manuscript copies of the work were formed, composed of 17 volumes large folio; and containing, besides an introduction, the following tables.

* Nicolson's Journal. vol. v. 470 series, p. 311.

  1. 1. The natural sines for each 10,000th part of the quadrant, calculated to twenty-five places of decimals, to be published with twenty-two decimals and five columns of differences.
  2. 2. The logarithms of these sines, calculated to fourteen decimals, with five columns of differences.
  3. 3. The logarithms of the ratios of the sines to the arcs for the first five thousand 100,000th parts of the quadrant, calculated to fourteen decimal places, with three columns of differences.
  4. 4. The logarithms of the tangents corresponding with the logarithms of the sines.
  5. 5. The logarithms of the ratios of the tangents to the arcs calculated like those of the third article.
  6. 6. Logarithms of numbers from 1 to 100,000, calculated to nineteen places of decimals.
  7. 7. The logarithms of numbers from 100,000 to 200,000, calculated to 24 decimals, in order to be published to 12 decimals and three columns of differences.

The printing of this work was begun at the expence of the French government, but was suspended at the fall of the assignats; whether it has been since resumed we cannot positively say, but it certainly is not yet completed.

SECT. I.

OF THE NATURE OF LOGARITHMS AND THEIR CONSTRUCTION.

WE have already shewn that the properties of logarithms are deducible from those of two series, the terms of one of which form a geometrical progression, and those of the other an arithmetical progression; and as this manner of treating the subject is simple, it is perhaps the best adapted of any to such of our readers as have not pursued the study of mathematics to any great extent. We shall now shew how, from the same principles, the logarithm of any proposed number whatever may be found.

The first step to be taken in constructing a system of logarithms is to assume the logarithm of some determinate number, besides that of unity or 1, which must necessarily be 0. From the particular view which Napier took of the subject, he was led to assume unity for the logarithm of the number 2.718282, by which it hap-

pened that the logarithm of 10 was 2.302585, and this Nature of assumption being made, the form of the system became Logarithms, determinate, and the logarithm of every number fixed &c. to one particular value.

Mr Briggs however observed, that it would be better to assume unity for the logarithm of 10, instead of making it the logarithm of 2.718282, as in Napier's system, and hence the logarithms of the terms of the geometrical progression

1, 10, 100, 1000, 10000, &c.

were necessarily fixed to the corresponding terms of this arithmetical progression,

0, 1, 2, 3, 4, &c.

That is, the logarithm of 1 being 0, and that of 10 being 1, the logarithm of 100 is 2, and that of 1000 is 3, and so on.

The logarithms of the terms of the progression, 1, 10, 100, 1000, &c. being thus determined; in order to form the logarithms of the numbers between 1 and 10, and between 10, and 100, and so on, we must conceive a very great number of geometrical means to be interpolated between each two adjoining terms of the preceding geometrical series, and as many arithmetical means between the corresponding terms of the arithmetical series; then, like as the terms of the arithmetical series 0, 1, 2, 3, &c. are the logarithms of the corresponding terms of the geometrical series 1, 10, 100, 1000, &c. the interpolated terms of the former will also be the logarithms of the corresponding interpolated terms of the latter. Now as by supposing the number of means interpolated between each two terms of the geometrical series to be sufficiently great, some one or other of them may be found which will be very nearly equal to any proposed number; it is evident that to find the logarithm of such a number, we have only to seek for one of the interpolated means which is very nearly equal to it, and to take the logarithm of that mean as a near value of the logarithm required.

As a particular example, let it be required to find the logarithm of the number 5, according to Briggs's system.

First step of the process.—The number 5 is between 1 and 10, the logarithms of which we already know to be 0 and 1. Let a geometrical mean be found between the two former, and an arithmetical mean between the two latter. The geometrical mean will be the square root of the product of the numbers 1 and 10, which is 3.162277; and the arithmetical mean will be half the sum of the logarithms 0 and 1, which is 0.5; therefore the logarithm of 3.162277 is 0.5. But as the mean thus found is not sufficiently near to the proposed number, we must proceed with the operation as follows:

Second step.—The number 5, whose logarithm is sought is between 3.162277, the mean last found, and 10, the logarithms of which we know to be 0.5 and 1; we must now find a geometrical mean between the two former, and an arithmetical mean between the two latter. The one of these is \sqrt{(3.162277 \times 10)} = 5.623413, and the other is \frac{1+0.5}{2} = 0.75; therefore the logarithm of 5.623413 is 0.75.

Third step.—We have now obtained two numbers, namely,

Nature of namely 3.162277 and 5.623413, one on each side of Logarithms 5, together with their logarithms 0.5 and .075, we &c. therefore proceed exactly as before, and accordingly we find the geometrical mean, or \sqrt{(3.162277 \times 5.623413)}, to be 4.216964, and the arithmetical mean, or \frac{0.5 + 0.75}{2} to be 0.625; therefore the logarithm of 4.216964 is 0.625.

Fourth step.—We proceed in the same manner with the numbers 4.216964, and 5.623413 (one of which is less, and the other greater than 5) and their logarithms 0.625 and 0.75, and find a new geometrical mean, viz. 4.869674, and its corresponding arithmetical mean, or logarithm, 0.6875.

We must go on in this way till we have found twenty-two geometrical means, and as many corresponding arithmetical means or logarithms. And that we may indicate how these are found from each other, let the numbers 1 and 10 be denoted by A and B, and their geometrical means taken in their order by C, D, E, &c. then the results of the successive operations will be as in the following table.

Numbers. Logarithms.
A = 1.000000 0.000000
B = 10.000000 1.000000
C = \sqrt{AB} = 3.162277 0.500000
D = \sqrt{BC} = 5.623413 0.750000
E = \sqrt{CD} = 4.216964 0.625000
F = \sqrt{DE} = 4.869674 0.687500
G = \sqrt{EF} = 5.232991 0.718750
H = \sqrt{FG} = 5.048065 0.703125
I = \sqrt{GH} = 4.958069 0.6953125
K = \sqrt{HI} = 5.002865 0.6992187
L = \sqrt{IK} = 4.980416 0.6972656
M = \sqrt{KL} = 4.991627 0.6982421
N = \sqrt{KM} = 4.997242 0.6987304
O = \sqrt{KN} = 5.000052 0.6989745
P = \sqrt{NO} = 4.998647 0.6988525
Q = \sqrt{OP} = 4.999350 0.6989135
R = \sqrt{OQ} = 4.999701 0.6989440
S = \sqrt{OR} = 4.999876 0.6989592
T = \sqrt{OS} = 4.999963 0.6989668
V = \sqrt{OT} = 5.000008 0.6989707
W = \sqrt{TV} = 4.999984 0.6989687
X = \sqrt{VW} = 4.999997 0.6989697
Y = \sqrt{VX} = 5.000003 0.6989702
Z = \sqrt{XY} = 5.000000 0.6989700

As the last of these means, viz. Z, agrees with 5, the proposed number, as far at least as the sixth place of decimals, we may safely consider them as very nearly equal, therefore their logarithms will also be very nearly equal, that is the logarithm of 5 will be 0.6989700 nearly.

In performing the operations indicated in the preceding table it will be necessary to find the geometrical means at the beginning to many more figures than are here put down, in order to obtain at last a result true to 7 decimal places. Thus it appears that the labour of computing logarithms by this method is indeed very great. It is, however, that which was employed by Briggs and Vlacq in the original construction of logarithms; but since the period in which they lived, others more easy have been found, as we shall presently have occasion to explain.

The logarithm of any number whatever may be

found by a series of calculations similar to that which we have just now explained. But in constructing the table it would only be necessary to have recourse to this method in calculating the logarithms of prime numbers; for as often as the logarithm of a number which was the product of other numbers, whose logarithms were known, was required, it would be immediately obtained by adding together the logarithms of its factors. On the contrary, if the logarithm of the product of two numbers were known, and also that of one of its factors, the logarithm of the other factor would be obtained from these, by simply taking their difference.

From this last remark it is obvious, that having now found the logarithm of 5, we can immediately find that of 2; for since 2 is the quotient of 10 divided by 5, its logarithm will be the difference of the logarithms of 10 and 5; now the logarithm of 10 is 1, and the logarithm of 5 is 0.6989700, therefore the logarithm of 2 is 0.3010300.

Having thus obtained the logarithms of 2 and 5, in addition to those of 10, 100, 1000, &c. we may thence find the logarithms of innumerable other numbers. Thus, because 4 = 2 \times 2, the logarithm of 4 will be the logarithm of 2 added to itself, or will be twice the logarithm of 2. Again, because 5 \times 10 = 50, the logarithm of 50 will be the sum of the logarithms of 5 and 10. In this manner it is evident we may find the logarithms of 8 = 2 \times 4, of 16 = 2 \times 8, of 25 = 5 \times 5, and of as many more such numbers as we please.

Besides the view we have hitherto taken of the theory of logarithms, there are others under which it has been presented by different authors. Some of these we proceed to explain, beginning with that in which they are defined to be the measures of ratios; but to see the propriety of this definition, it must be understood what is meant by the measure of a ratio.

According to the definition of a compound ratio, as laid down by writers on geometry, if there be any number of magnitudes A, B, C, D, which are continual proportionals, or such that the ratio of A to B is equal to the ratio of B to C, and that again is equal to the ratio of C to D, and so on, the ratio of the first of these magnitudes A to the third C is considered as made up of two equal ratios, each equal to the ratio of the first A to the second B. And in like manner the ratio of the first A to the fourth D is considered as made up of three equal ratios, each equal to the ratio of the first to the second, and so on. (See GEOMETRY Sect. III. Def. 10, 11, and 12.) Thus, to take a particular example in numbers, because the ratio of 8 to 3 may be considered as made up of the ratio of 8 to 27, and of 27 to 9, and of 9 to 3, which three ratios are equal among themselves, (GEOMETRY Sect. III. Def. 4.) the ratio of 8 to 3 will be triple the ratio of 9 to 3; and in like manner the ratio of 27 to 3 will be double the ratio of 9 to 3. Also, because the ratios of 1000 to 100, 100 to 10, 10 to 1, are all equal, the ratio of 1000 to 1 will be three times as great as the ratio of 100 to 1; and the ratio of 100 to 1 will be twice as great; and so on.

Taking this view of ratios, and considering them as a particular species of quantities, made up of others of the same kind, they may evidently be compared with each other, in respect of their magnitudes, in the same manner as we compare lines or quantities of any kind whatever.

Nature of whatever. And as when estimating the relative magnitudes of two quantities, two lines for example, if we find that the one contains five such equal parts as the other contains seven, we say the one line has to the other the proportion of 5 to 7; so, in like manner, if two ratios be such, that the one can be resolved into five equal ratios, and the other into seven of the same ratios, we may conclude that the magnitude of the one ratio is to that of the other as the number 5 to the number 7; and a similar conclusion may be drawn, when the ratios to be compared are any multiples whatever of some other ratio.

It is well known that there may be lines and other quantities, which, as they admit of no common measure, are said to be incommensurable to each other; and the same will also happen to ratios: That is, there may be two ratios such that into whatever number of equal ratios the one is divided, the other cannot possibly be exactly equal to a ratio composed of any number of these. We may however conceive the number of equal ratios into which the one is divided to be so great that a certain number of them shall compose a ratio more nearly equal to the other ratio than by any assignable difference. Therefore, like as we can always find numbers which shall have among themselves, either accurately, or as nearly as we please, the same ratios as any number of lines or other magnitudes have to each other, and which therefore may be taken as the measures, or representatives of the lines; so also, corresponding to any system of ratios, there may be always found a series of numbers which will have the same proportions among themselves as the ratios have to each other, and which may in like manner be called the measures of the ratios.

Let us now suppose that unity, or 1, is assumed as the common consequent of all ratios whatever; and that the ratio of 10 (or some particular number) to 1 is compounded of a very great number of equal ratios, as for example 1000,000: then, as each of these will be very near to the ratio of equality, (for it will be the ratio of the first term to the second of a series of one million and one continued proportionals, the first of which is 10 and last 1), it will follow, and is easy to conceive, that the ratios of all other numbers to unity will each be very nearly equal to some multiple of that small ratio. And by supposing the number of small equal ratios of which the ratio of 10 to 1 is composed to be sufficiently great, the ratios of all other numbers to unity may be as nearly equal to ratios which are multiples of that small ratio as we please. Let us still suppose, however, for the sake of illustration, that the number of small ratios contained in that of 10 to 1 is 1000,000 then, as it may be proved that the ratio of 2 to 1 will be very nearly the same as a ratio composed of 301030 of these; and that the ratio of 3 to 1 will be nearly equal to a ratio composed of 477121 of them, and that the ratio of 4 to 1 will be nearly equal to a ratio composed of 620660 of them, and so on; these numbers, viz. 1000000, 301030, 477121, and 620660, or any other numbers proportional to them, will be the measures of the ratios of 10 to 1, 2 to 1, 3 to 1, and 4 to 1, respectively; and the same quantities will also be what have been called the logarithms of the ratios; for the word logarithm, if regard be had to its etymology, is \lambda\gamma\sigma\alpha\ \alpha\gamma\delta\epsilon\iota, or the numbers of small and equal

ratios (or rationes as they have been called) contained in the several ratios of quantities one to another. Nature of Logarithms &c.

We have for the sake of illustration, assumed 1000000 as the measure of the ratio of 10 to 1, by which it happens, as already observed, that the measures of the ratios of 2 to 1, 3 to 1, &c. are 301030 and 477121 respectively; as, however, these measures are not absolute, but relative quantities, we may assume any other numbers whatever instead of these, provided they have the same proportions to each other as these numbers have among themselves. Accordingly, we may assume 1 as the measure or logarithm of the ratio of 10 to 1; and then the logarithms of the ratios of 2 to 1, 3 to 1, &c. instead of being 301030, 477121, &c. will be .301030 and .477121, &c. respectively, that is, each will be the one-millionth of what it was before.

In Brigg's system, the logarithm of the ratio of 10 to 1, or, to speak briefly, the logarithm of 10, is unity; but we are at liberty to assume any number whatever, as that whose logarithm shall be unity. Napier, in consequence of his particular views of the subject, chose the number 2.718282; and hence it happens that the logarithms of the ratios are expressed by different numbers in the two systems.

It yet remains for us to shew the identity of the properties of logarithms, as explained in the two different views we have now given of the subject; and this may be done as follows.

Let A and B denote any two numbers. The ratio of their product to unity, that is, the ratio of A \times B to 1, is compounded of the ratio of A \times B to B, and of B to 1; (see GEOMETRY Part III. Def. 10.) but since A \times B, B, A, and 1 are four proportionals, the ratio of A \times B to B is equal to the ratio of A to 1. Therefore the ratio of A \times B to 1 is compounded of the ratio of A to 1 and of B to 1; and consequently the logarithm of the ratio of A \times B to 1 will be equal to the sum of the logarithms of the ratios of A to 1, and of B to 1; or in other words, the logarithm of A \times B will be the sum of the logarithms of A and B.

And because \log. (A \times B) = \log. A + \log. B, therefore, \log. B = \log. (A \times B) - \log. A. In this equation let \frac{C}{D} be substituted for B, and D for A, then, (because A \times B = D \times \frac{C}{D} = C) we have \log. \frac{C}{D} = \log. C - \log. D.

We have now given a short sketch of the theory of logarithms as deducible from the doctrine of ratios. It was in this way that the celebrated Kepler treated the subject according to the strictest rules of geometrical reasoning; and in this he has been followed by Mercator, Halley, Cotes, as well as by other mathematicians of later times, as by Mr Baron Maferes, in his "Elements of Plane Trigonometry," a work in which the whole theory of logarithms is treated with all that perspicuity and accuracy which characterize the ingenious author's various writings. The same mode of treating the subject was likewise adopted by that excellent geometrician Dr Robert Simson, as appears by a short tract in Latin, written by him and published in his posthumous works. As, however, the doctrine of ratios is of a very abstract nature, and the mode of reasoning upon which it has been established is of a peculiar and subtle kind, we presume that the greater number of readers

Nature of readers will think this view of the subject less simple
Logarithms, and natural than the following, in which we mean to
deduce the theory of logarithms, as well as the manner
of computing them, from the properties of the exponents
of powers.

If we attend to the common scale of notation in
arithmetic, we shall find that it is so contrived as to
express all numbers whatever by means of the powers
of the number 10, which is the root of the scale, and
the nine digits which serve as coefficients to these
powers. Thus, if R denote 10, the root of the scale,
so that R^1 will denote 100, and R^2 1000, and so on,
the number 471509 is otherwise expressed by 4R^5 +
7R^4 + 1R^3 + 5R^2 + 0R^1 + 9R^0, which is equivalent to
4R^5 + 7R^4 + R^3 + 5R^2 + 9. Again, the mixt number
371.243 is expressed by 3R^2 + 7R^1 + R^0 + \frac{2}{R} + \frac{4}{R^2} +
\frac{3}{R^3}, or by 3R^2 + 7R^1 + R^0 + 2R^{-1} + 4R^{-2} + 3R^{-3}.

As to vulgar fractions, by transforming them to deci-
mals, they may be expressed in the same manner.
Thus \frac{1}{2} = .5 = 5R^{-1} = 5R^{-1} + 7R^{-2} + 5R^{-3}. Also \frac{1}{3} =
.666, &c. = 6R^{-1} + 6R^{-2} + 6R^{-3} + \dots

Although the number 10 has been fixed upon as the
root of the scale of notation, any other number may
be employed to express all numbers whatever in the
same manner; and some numbers are even preferable
to 10. Thus, making 8 the root of a scale, and deno-
tating it by R, the number 2735, when expressed ac-
cording to this scale, is 5R^3 + 2R^2 + 5R^1 + 7R^0, or
5R^3 + 2R^2 + 5R + 7; and here we may observe, that if
a number greater than 10 were assumed as the root of
the scale of notation, it would be necessary to adopt
some new numeral characters in addition to those in
common use, and if a smaller number were assumed,
we might dispense with some of those we already
have.

But instead of expressing all numbers by the sums of
certain multiples of the successive powers of some par-
ticular numbers, we may also express them, if not accu-
rately, at least as near as we please, by a single power,
whole or fractional, of any positive number whatever,
which may be either whole or fractional, but must not
be unity.

Let us take, for example, 2 as the number, by the
powers of which all others are to be expressed. Then
it may be shewn that the numbers 1, 2, 3, &c. are all
expressible by the powers of 2, as follows.

1 = 2^0 6 = 2^{2.58496} nearly
2 = 2^1 7 = 2^{2.8073} nearly
3 = 2^{1.58496}, nearly 8 = 2^3
4 = 2^2 9 = 2^{3.1699}
5 = 2^{2.3219}, nearly 10 = 2^{3.3219} nearly,

and so on. And if instead of 2 we take the number 10,
then we have

1 = 10^0 6 = 10^{.77815}
2 = 10^{.30103} 7 = 10^{.84510}
3 = 10^{.47712} 8 = 10^{.90309}
4 = 10^{.60206} 9 = 10^{.95424}
5 = 10^{.69897} 10 = 10^1

Hence we may conclude, that if r be put for some

determinate number, and n for any indefinite positive
number, whole or fractional, it is always possible to find
another number N, such that the number r being raised
to the power N shall either be exactly equal to n, or
shall be as near to it as we please; that is, we shall have
r^N = n.

When numbers are expressed in this way by the
powers of some given number r; the exponent of that
power of r which is equal to any assigned number is
called the logarithm of that number. Therefore, if r^N = n,
(n being put for any number) then N will be the loga-
rithm of the number n.

The logarithms which are produced by giving to r
some determinate value constitute a system of logarithms,
and the constant number r, from which the system is
formed, is called the base or radical number of the
system.

The properties of logarithms may be readily deduced
from the above definition as follows. Let a and b be
put for any two numbers, and A and B for their loga-
rithms; then, r being supposed to denote the base, or
radical number of the system, we have a = r^A and
b = r^B: now if we take the product of a and b, we
have a \cdot b = r^A \times r^B = r^{A+B}; but according to the de-
finition, A+B is the logarithm of a \cdot b, (for it is the in-
dex of that power of r which is equal to a \cdot b) therefore,
the sum of the logarithms of any two numbers a and b is
the logarithm of their product a \cdot b. Again, we have

\frac{a}{b} = \frac{r^A}{r^B} = r^{A-B}, but here A-B is the index of that
power of r which is equal to \frac{a}{b}; therefore, A-B is the

logarithm of \frac{a}{b}; hence, if one number a be divided by
another number b, the excess of the logarithm of the divi-
dend above that of the divisor is equal to the logarithm
of the quotient \frac{a}{b}.

Let n express any number whatever, then, raising
both sides of the equation a = r^A to the nth power, we
have a^n = (r^A)^n = r^{nA}; but here nA is manifestly
the logarithm of a^n; therefore, the logarithm of a^n, any
power of a number, is the product of the logarithm of the
number by n, the index of the power. And this must
evidently be true, whether that index be a whole num-
ber, or a fraction, either positive or negative.

From these properties it is easy to see in what man-
ner a table that exhibits the logarithms of all numbers
within certain limits may be applied to simplify calcula-
tions: for since the sum of the logarithms of any two
numbers is equal to the logarithm of their product; it
follows, that as often as we have occasion to find the
product of two or more numbers, we have only to add
their logarithms into one sum, taking them from the
table, and to look in the table for the number whose
logarithm is equal to that sum, and this number will be
the product required. Also, because the excess of the
logarithm of the dividend above that of the divisor is
equal to the logarithm of the quotient; as often as we
have occasion to divide one number by another, we have
only

Nature of Logarithms, &c. only to subtract the logarithm of the divisor from that of the dividend, and opposite to that logarithm in the table, which is the remainder, we shall find the quotient.

As the logarithm of any power of a number is the product of the logarithm of the number, and the index of the power; and on the contrary, the logarithm of any root of a number is the quotient found by dividing the logarithm of the number by the index of the root; it follows, that we may find any power or root of a number, by multiplying the logarithm of the number by the index of the power, or dividing it by the index of the root, and taking that number in the table whose logarithm is the product or quotient for the power or root required.

If in the equation a = r^A (where a is any number, A its logarithm, and r the base of the system) we suppose a = 1, then, in this case r^A = 1; but this equation can only be satisfied by putting A = 0. Hence it appears, that in every system of logarithms, the logarithm of unity must be 0. It on the other hand we assume a = r; then we have the equation r = r^A, which is immediately satisfied by putting A = 1; therefore, the logarithm of the base, or radical number of every system is necessarily unity.

If we suppose r to be a positive number greater than unity, and a a positive number greater than unity, then A will be a positive number; for if it be negative we would have a = r^{-A} = \frac{1}{r^A} a proper fraction, and at the same time a number greater than unity by hypothesis, which is impossible. If on the contrary we suppose a a proper fraction, then A must necessarily be negative, for if it were positive, then r^A would be greater than unity, and a = r^A also greater than unity, while by hypothesis it is a fraction less than unity, which is impossible. Therefore, in every system, the base of which is greater than unity, the logarithm of a whole or mixed number is always positive, but the logarithm of a proper fraction is always negative.

Because the logarithm of r is unity, the logarithm of r^n will be n; therefore, the logarithm of any integer power of the radical number r will always be an integer.

Let r and r' denote bases of two different systems; and let A be the logarithm of a number, a, taken according to the first of these, and A' its logarithm taken according to the last. Then because a = r^A, and

a = r'^{A'}, it follows that r^A = r'^{A'}, and r = r'^{\frac{A'}{A}}. Let us now suppose that r'' is the base of a third system of logarithms, and R and R' the logarithms of r and r' taken according to this third system; then because

r^R = r', \quad r'^{R'} = r''; \\ \text{we have } r^{RR'} = r'', \quad r'^{RR'} = r'';

therefore r^{\frac{R'}{R}} = r'^{\frac{R}{R'}}, and r = r'^{\frac{R'}{R}}; but we have already found r = r'^{\frac{A'}{A}}, therefore r^{\frac{A'}{A}} = r'^{\frac{R}{R'}}, and consequently

\frac{A'}{A} = \frac{R}{R'}, \quad \text{and } A : A' :: R' : R :: \frac{1}{R} : \frac{1}{R'}.

Hence it appears, that the logarithm of a number, taken according to one system, has to its logarithm, taken according to any other system, a constant ratio, which is the same as that of the reciprocals of the logarithms of the radical numbers of those systems, taken according to any system whatever.

Let us next suppose, that a and b are two numbers, and A and B their logarithms, taken according to the same system, and r the base of the system; then because

r^A = a, \quad r^B = b; \\ \text{we have } r^{AB} = a^B, \quad r^{AB} = b^A;

therefore a^B = b^A, and a = b^{\frac{A}{B}}, now as r is not found in this equation, the value of the fraction \frac{A}{B} depends only on the numbers a and b; therefore, the logarithms of any two given numbers have the same ratio in every system whatever.

Having now explained the properties which belong to the logarithms of any system whatever, we proceed to investigate general rules by which the number corresponding to any logarithm, and on the contrary, the logarithm corresponding to any number, may be found the one from the other. And for this end let us denote any number whatever by y, and its logarithm by x, and put r as before for the base, or radical number of the system; then by the nature of logarithms we have this equation

y = r^x.

Put r = 1 + a, and let the expression (1 + a)^x be expanded into a series by the binomial theorem; thus we shall have y =

1 + xa + \frac{x(x-1)}{1 \cdot 2} a^2 + \frac{x(x-1)(x-2)}{1 \cdot 2 \cdot 3} a^3 + \frac{x(x-1)(x-2)(x-3)}{1 \cdot 2 \cdot 3 \cdot 4} a^4 + \dots

Let this series, the terms of which are arranged according to the powers of the quantity a, be transformed into another the terms of which shall be arranged according to the powers of x; and to effect this we must find the actual products of the factors which constitute the powers of a, and arrange the terms anew, as follows,

1 = 1, \\ xa = +ax, \\ \frac{x(x-1)}{1 \cdot 2} a^2 = -\frac{a^2}{2}x + \frac{a^2}{2}x^2, \\ \frac{x(x-1)(x-2)}{1 \cdot 2 \cdot 3} a^3 = +\frac{a^3}{3}x - \frac{a^3}{2}x^2 + \frac{a^3}{6}x^3, \\ \frac{x(x-1)(x-2)(x-3)}{1 \cdot 2 \cdot 3 \cdot 4} a^4 = -\frac{a^4}{4}x + \frac{11a^4}{24}x^2 - \frac{a^4}{4}x^3 + \frac{a^4}{24}x^4, \\ \&c. \quad \&c.

so that adding into one sum the quantities on each side of the sign =, and recollecting that the sum of these on the left-hand side is equal to y, we have

y = r^x = \begin{cases} 1 \\ + \left( a - \frac{a^2}{2} + \frac{a^3}{3} - \frac{a^4}{4} + \&c. \right) x, \\ + \left( \frac{a^2}{2} - \frac{a^3}{2} + \frac{11a^4}{24} - \&c. \right) x^2, \\ + \left( \frac{a^3}{6} - \frac{a^4}{4} + \&c. \right) x^3, \\ + \left( \frac{a^4}{24} - \&c. \right) x^4, \\ + \&c. \end{cases}
which equation, by substituting,
A \text{ for } a - \frac{a^2}{2} + \frac{a^3}{3} - \frac{a^4}{4} + \&c.
A' \text{ for } \frac{a^2}{2} - \frac{a^3}{2} + \frac{11a^4}{24} - \&c.
A'' \text{ for } \frac{a^3}{6} - \frac{a^4}{4} + \&c.
A''' \text{ for } \frac{a^4}{24} - \&c.
may be abbreviated to
r^x = 1 + Ax + A'x^2 + A''x^3 + A'''x^4 + \&c.

Next, to determine the law of connexion of the quantities A, A', A'', A''', \&c. let x + z be substituted in the last equation for x, (here z is put for any indefinite quantity) thus it becomes

r^{x+z} = 1 + A(x+z) + A'(x+z)^2 + A''(x+z)^3 + \&c.

But r^{x+z} = r^x \times r^z, and since it has been shewn that

r^z = 1 + Az + A'z^2 + A''z^3 + A'''z^4 + \&c.

for the very same reason

r^z = 1 + Az + A'z^2 + A''z^3 + A'''z^4 + \&c.

therefore the series

1 + A(x+z) + A'(x+z)^2 + A''(x+z)^3 + A'''(x+z)^4 + \&c.

is equal to the product of the two series

1 + Ax + A'x^2 + A''x^3 + A'''x^4 + \&c.
1 + Az + A'z^2 + A''z^3 + A'''z^4 + \&c.

That is, by actual involution and multiplication

\begin{aligned} & \left\{ 1 + Ax + A'x^2 + A''x^3 + A'''x^4 + \&c. \right. \\ & \left. + Az + 2A'xz + 3A''xz^2 + 4A'''xz^3 + \&c. \right. \\ & \left. + A'z^2 + 3A''xz^3 + 6A'''xz^4 + \&c. \right. \\ & \left. + A''z^3 + 4A'''xz^4 + \&c. \right. \\ & \left. + A'''z^4 + \&c. \right\} = \\ & = \left\{ 1 + Ax + A'x^2 + A''x^3 + A'''x^4 + \&c. \right. \\ & \left. + Az + A'xz + A''xz^2 + A'''xz^3 + \&c. \right. \\ & \left. + A'z^2 + A'xz^2 + A''xz^3 + A'''xz^4 + \&c. \right. \\ & \left. + A''z^3 + A''xz^3 + A'''xz^4 + \&c. \right. \\ & \left. + A'''z^4 + \&c. \right\} \end{aligned}

Now as the quantities A, A', A'', \&c. are quite independent of x and z, the two sides of the equation can

VOL. XII. Part I.

only be identical upon the supposition that the co-efficients of like terms in each are equal; therefore, setting aside the first line of each side of the equation, because their terms are the same, and also the first term of the second line, for the same reason, let the coefficients of the remaining terms be put equal to one another, thus we have

\left. \begin{array}{l} A^2 = 2A' \\ AA' = 3A'' \\ AA'' = 4A''' \\ \&c. \end{array} \right\} \text{ and hence we have } \left\{ \begin{array}{l} A' = \frac{A^2}{1 \cdot 2} \\ A'' = \frac{A^3}{1 \cdot 2 \cdot 3} \\ A''' = \frac{A^4}{1 \cdot 2 \cdot 3 \cdot 4} \\ \&c. \end{array} \right.

Here the law of the coefficients A, A', A'', \&c. is obvious, each being formed from the preceding by multiplying it by A, and dividing by the exponent of the power of A which is thus formed. Let these values of A', A'', \&c. be now substituted in the equation

y = r^x = 1 + Ax + A'x^2 + A''x^3 + \&c.

and it becomes,

y = 1 + Ax + \frac{A^2}{1 \cdot 2} x^2 + \frac{A^3}{1 \cdot 2 \cdot 3} x^3 + \frac{A^4}{1 \cdot 2 \cdot 3 \cdot 4} x^4 + \&c.

thus we have obtained a general formula expressing a number in terms of its logarithm and the base of the system, for we must recollect that the quantity A which is equal to

a - \frac{a^2}{2} + \frac{a^3}{3} - \frac{a^4}{4} + \frac{a^5}{5} - \&c.

is otherwise expressed by

r = 1 - \frac{(r-1)^2}{2} + \frac{(r-1)^3}{3} - \frac{(r-1)^4}{4} + \frac{(r-1)^5}{5} - \&c.

where r denotes the base of the system (A).

If in the formula

r^x = 1 + Ax + \frac{A^2}{1 \cdot 2} x^2 + \frac{A^3}{1 \cdot 2 \cdot 3} x^3 + \frac{A^4}{1 \cdot 2 \cdot 3 \cdot 4} x^4 + \&c.

we suppose x = 1, it becomes

r = 1 + A + \frac{A^2}{1 \cdot 2} + \frac{A^3}{1 \cdot 2 \cdot 3} + \frac{A^4}{1 \cdot 2 \cdot 3 \cdot 4} + \&c.

an equation which contains r only; but as r has been all along supposed an indeterminate quantity, this equation must be identical, that is, if instead of A, its value, as expressed above in terms of r, were substituted, the whole would vanish.

Again, let us suppose that \frac{1}{A} is substituted instead of x in the general formula, thus it becomes

r^{\frac{1}{A}} = 1 + \frac{1}{A} + \frac{1}{1 \cdot 2} + \frac{1}{1 \cdot 2 \cdot 3} + \frac{1}{1 \cdot 2 \cdot 3 \cdot 4} + \&c.
K
Thus

(A) For other analytic methods of investigating the same formula, see ALGEBRA § 293, and FLUXION § 54, and § 70. Ex. 1. also § 200. Prob. 1.

Nature of
Logarithms,
&c.

Thus the quantity r^{\frac{1}{A}}, whatever be the value of r, is evidently equal to a constant number, which, as appears from the last equation, is equal to the value of r when A=1. By adding together a sufficient number of the terms of the series expressing the value of r^{\frac{1}{A}}, we find that quantity equal to

2.718281828459045\dots

Let this number be denoted by e, and we have r^{\frac{1}{A}} = e, and r = e^A; hence it appears, that if the number e be considered as the base of a logarithmic system, the quantity A, that is

r = 1 - \frac{(r-1)^2}{2} + \frac{(r-1)^3}{3} - \frac{(r-1)^4}{4} + \frac{(r-1)^5}{5} \dots \&c.

is the logarithm of r to the base e. But as r is not restricted here to any particular value, we may substitute y instead of it, keeping in mind that y denotes any number whatever, and x its logarithm; thus we have x the logarithm of y, expressed by the series

y = 1 - \frac{(y-1)^2}{2} + \frac{(y-1)^3}{3} - \frac{(y-1)^4}{4} + \frac{(y-1)^5}{5} \dots \&c.

supposing that the base of the system is the number we have expressed above by e.

We have now found a general formula for the logarithm of any number, y, taken according to a particular system, namely, that which has the number e for its base. But it is easy from hence to find a formula, which shall apply to any system whatever. For it has been shown that the logarithms of the same number, taken according to two different systems, are to each other as the reciprocals of the logarithms of the bases of the systems, these last logarithms being taken according to any system whatever, that is,

\log. y \text{ to base } e : \log. y \text{ to base } r :: \frac{1}{\log. e} : \frac{1}{\log. r};

hence we find

\log. y \text{ to base } r = \frac{\log. e}{\log. r} \times \log. y \text{ to base } e.

Let the value we have already found for the logarithm of y to base e be substituted in this equation, and it becomes

\log. y = \frac{\log. e}{\log. r} \left\{ 1 - \frac{(y-1)^2}{2} + \frac{(y-1)^3}{3} - \frac{(y-1)^4}{4} + \dots \right\}

which is a general formula for the logarithm of any number whatever, to the base r. And it is to be recollected that in the fraction \frac{\log. e}{\log. r}, which is a common multiplier to the series, the logarithms are to be taken according to the same base, which however may be any number whatever (B).

If in the above formula we suppose r=e, the multiplier

\frac{\log. e}{\log. r} will be unity, and the formula will become simply \log. y = y - 1 - \frac{(y-1)^2}{2} + \frac{(y-1)^3}{3} - \frac{(y-1)^4}{4} + \dots

Nature of Logarithms, &c.

as we have already remarked. Now this is the system which was adopted by Lord Napier; and although the logarithms which were computed according to this system, or upon the supposition that the radical number is 2.7182818 &c. have been called hyperbolic logarithms because they happen to be proportional to certain hyperbolic spaces, yet, as the logarithms of every system have the same property, it is more proper to call them Napierian logarithms.

As the constant multiplier \frac{\log. e}{\log. r}, which occurs in the general formula for the logarithm of any number, is the only part of the formula which depends for its value upon the base of the system, it has been called by writers on logarithms, the modulus of the system. If we suppose the logarithms taken to the base e, then the numerator, viz. \log. e, will be unity, and the denominator will be the Napierian logarithm of r. If however we suppose the logarithms taken to the base r, then the numerator will be \log. e to base r, and the denominator will be unity, so that the modulus of any system whose base is r, is the reciprocal of the Napierian logarithm of that base; or it is the logarithm of the number e (the base of the Napierian system) to the base r.

In the Napierian system the modulus is unity, and hence the logarithms of this system, as far as depends upon facility of computation, are the most simple of any. It was however soon found that a system whose base should be the same as the root of the scale of the arithmetical notation, viz. the number 10, would be the most convenient of any in practice; and accordingly such a system was actually constructed by Mr Briggs. This is the only one now in common use, and is called Briggs's system, also the common system of logarithms. The modulus of this system therefore is the reciprocal of the Napierian logarithm of 10; or it is the common logarithm of e = 2.7182818 \dots the base of the Napierian system. We shall in future denote this modulus by M; so that the formula expressing the common logarithm of any number y will be

\log. y = M \left\{ 1 - \frac{(1-y)^2}{2} + \frac{(1-y)^3}{3} - \frac{(1-y)^4}{4} + \dots \right\}

If the number y, whose logarithm is required be very near to unity, so that 1-y is a small quantity, then the logarithm may be found from this formula with great ease, because the series will converge very rapidly. If, however, 1-y be greater than unity, the series, instead of converging, will diverge, so as to be in its present form of no use.

It may however be transformed into another, which shall converge in every case, by substituting in it \sqrt[n]{y} instead of y, and observing that \log. (\sqrt[n]{y}) = \frac{\log. y}{n};

(B) For other methods of investigating the same formula see ALGEBRA 284, and FLUXIONS § 70. Ex. 2. also § 136.

Nature of it thus becomes

\log. y = nM \left\{ \sqrt[n]{y} - 1 - \frac{1}{2}(\sqrt[n]{y} - 1)^2 + \frac{1}{3}(\sqrt[n]{y} - 1)^3 - \dots \right\}

where n may denote any number whatever, positive or negative. But whatever be the number y, we can always take n, such that \sqrt[n]{y} shall be as nearly equal to 1, as we please, therefore by this last formula, we can always find the logarithm of y to any degree of accuracy whatever.

If we suppose n to be taken negative, then \sqrt[n]{y} = \frac{1}{\sqrt[n]{y}}, and the series which expresses \log. y becomes, by changing the signs,

\log. y = nM \left\{ 1 - \frac{1}{\sqrt[n]{y}} + \frac{1}{2} \left( 1 - \frac{1}{\sqrt[n]{y}} \right)^2 - \frac{1}{3} \left( 1 - \frac{1}{\sqrt[n]{y}} \right)^3 + \dots \right\}

where all the terms are positive. Thus we have it in our power to express the value of y, either by a series which shall have its terms all positive, or by one which shall have its terms alternately positive and negative: for it is evident that y being greater than unity, \sqrt[n]{y} will also be greater than unity, and y being less than unity, \sqrt[n]{y} will also be less than unity, but the differences will be so much the smaller as n the exponent of the root is greater; therefore \sqrt[n]{y} - 1 will be positive in the first case, and negative in the second.

Because M = \frac{1}{\text{Nap. log. } 10}, therefore \text{Nap. log. } 10 = \frac{1}{M}; hence by the two last formulas we have

\frac{1}{M} = n \left\{ \sqrt[n]{10} - 1 - \frac{1}{2}(\sqrt[n]{10} - 1)^2 + \frac{1}{3}(\sqrt[n]{10} - 1)^3 - \dots \right\}
\frac{1}{M} = n \left\{ 1 - \frac{1}{\sqrt[n]{10}} + \frac{1}{2} \left( 1 - \frac{1}{\sqrt[n]{10}} \right)^2 - \frac{1}{3} \left( 1 - \frac{1}{\sqrt[n]{10}} \right)^3 + \dots \right\}

It is evident that by giving to \sqrt[n]{y} such a value that \sqrt[n]{y} - 1 is a fraction less than unity, we render both the series for the value of \log. y converging; for as \sqrt[n]{y} - 1 is a fraction less than unity, the expression 1 - \frac{1}{\sqrt[n]{y}} will also be less than unity, seeing that it is

equal to \frac{\sqrt[n]{y} - 1}{\sqrt[n]{y}}. Therefore, in the first series, the second and third terms (taken together as one term) constitute a negative quantity, and as the same is also true of the fourth and fifth, and so on; the amount of all the terms after the first is a negative quantity, that is a quantity which is to be subtracted from the first, that we may have the value of \log. y. Hence we may infer that

\log. y < nM(\sqrt[n]{y} - 1).

And since, on the contrary, the terms of the second series are all positive, the amount of all the terms after the first is a positive quantity, that is, a quantity which must be added to the first to give the value of \log. y; so that we have

\log. y > nM \left( 1 - \frac{1}{\sqrt[n]{y}} \right).

Thus we have two limits to the value of the logarithm of y, which, by taking the number n sufficient-
ly great may come as near to each other as we
please.

In like manner we find two limits to the value of the reciprocal to the modulus, viz.

\frac{1}{M} < n(\sqrt[n]{10} - 1), \quad \frac{1}{M} > n \left( 1 - \frac{1}{\sqrt[n]{10}} \right).

It is evident that the difference between the two limits of \log. y, is

nM \left\{ (\sqrt[n]{y} - 1) - \left( 1 - \frac{1}{\sqrt[n]{y}} \right) \right\},

therefore if we take either the one or the other of the two preceding expressions for \log. y, the error in excess or defect is necessarily less than this quantity.

By these formulas we may depend upon having the logarithm of any number true to m figures, if we give to n such a value that the root \sqrt[n]{y} shall have m cyphers between the decimal point and the first significant figure on the right. So that in general, as the error is the smaller according as n the exponent of the root is greater, we may conclude that it becomes nothing, or may be reckoned as nothing, when n is taken indefinitely great; and this being the case, we may conclude that either of these expressions

nM(\sqrt[n]{y} - 1), \quad nM \left( 1 - \frac{1}{\sqrt[n]{y}} \right)

is the accurate value of \log. y.

The best manner of applying the preceding formula is to take some power of the number 2 for n; for by doing so, the root \sqrt[n]{y} may be found by a repetition of extractions of the square root only. It was in this way that Briggs calculated the first logarithms; and he remarked, that if in performing the successive extractions of the square root, he at last obtained twice as many decimal places as there were cyphers after the decimal point, the integer before it being unity, then the decimal part of this root was exactly the half of that which went before; so that the decimal parts of the two roots were to each in the same proportion as their logarithms: now this is an evident consequence of the preceding formula.

To give an example of the application of the formula, let it be required to find the numerical value of M, the modulus of the common system of logarithms, which, as it is the reciprocal of the Napierian logarithm of 10 is equal to

\frac{1}{n} \times \frac{1}{\sqrt[n]{10} - 1} \text{ nearly,}

when n is some very great number. Let us suppose n = 2^{40} = 8^{20}; then, dividing unity by 8, and this result again by 8, and so on, we shall after 20 divisions have \frac{1}{n}, or \frac{1}{8^{20}} equal to

0.00000 00000 00000 00086 73617 37988 40354.

Also, by extracting the square root of 10, and the square root of this result, and so on, after performing 64 extractions we shall find \sqrt[n]{10} equal to

1.00000 00000 00000 00199 71742 08125 50527 03257.

Nature of Logarithms, &c.

Therefore, \frac{1}{n} \times \frac{1}{n\sqrt{10}-1}, or M, is equal to

\frac{86736173798840354}{199717420812550527} = 0.4342944819.

As a second example, let it be required to find by the same formula the logarithm of the number 3, which is nearly equal to

n M (\pi\sqrt{3}-1) = \frac{n(\pi\sqrt{3}-1)}{n(\pi\sqrt{10}-1)} = \frac{\pi\sqrt{3}-1}{\pi\sqrt{10}-1},

n being as before a very great number. Let us suppose also in this case that n=2^{60}; then after 60 extractions of the square root we have \pi\sqrt{3} equal to

1.00000 00000 00000 0095 28942 64074 58932.

Therefore, taking the value of \pi\sqrt{10} as found in last example, we have

\log. 3 = \frac{\pi\sqrt{3}-1}{\pi\sqrt{10}-1} = \frac{95289426407458932}{199717420812550527} = .47712 11547 19662.

This method of computing logarithms is evidently attended with great labour, on account of the number of extractions of roots which it requires, to obtain a result true to a moderate number of places of figures. But the two series, which we have given, serve to simplify and complete it. For, whatever be the number y, it is only necessary to proceed with the extractions of the square root, till we have obtained for \pi\sqrt{y} a value which is unity followed by a decimal fraction; and then \pi\sqrt{y}-1, being a fraction, its powers will also be fractions, which will be so much the smaller as their exponents are greater; thus a certain number of terms of the series will serve to express the logarithm to as many decimal places as may be required.

There are yet other analytical artifices by which the series

\log. y = M \left\{ y-1-\frac{1}{2}(y-1)^2+\frac{1}{3}(y-1)^3-\frac{1}{4}(y-1)^4+\dots \right\}

may be transformed into others which shall always converge, and in particular the following. Let 1+u be substituted in the series for y; then it becomes

\log. (1+u) = M \left( u-\frac{u^2}{2}+\frac{u^3}{3}-\frac{u^4}{4}+\frac{u^5}{5}-\dots \right).

In like manner let 1-u be substituted for y, and we have

\log. (1-u) = M \left( -u-\frac{u^2}{2}-\frac{u^3}{3}-\frac{u^4}{4}-\frac{u^5}{5}-\dots \right).

Let each side of the latter equation be subtracted from the corresponding side of the former; the result on the left-hand side will be \log. (1+u) - \log. (1-u), which, by the nature of logarithms, is equal to \log. \frac{1+u}{1-u}; and on the right-hand side the alternate terms of the two series, having the same sign, these will by subtraction destroy each other, so that we shall have

\log. \frac{1+u}{1-u} = 2 M \left\{ u + \frac{u^3}{3} + \frac{u^5}{5} + \frac{u^7}{7} + \dots \right\}

which series, by substituting x for \frac{1+u}{1-u}, and conse-

quently \frac{x-1}{x+1} for u, will be otherwise expressed thus,

\log. x = 2 M \left\{ \frac{x-1}{x+1} + \frac{1}{3} \left( \frac{x-1}{x+1} \right)^3 + \frac{1}{5} \left( \frac{x-1}{x+1} \right)^5 + \dots \right\}

and this formula for the logarithm of a number is not only simple, but has also the property of converging in every possible case.

That we may give an example of the utility of this formula we shall employ it in the calculation of the Napierian logarithm of 2, which by the above formula will be

2 \left( \frac{1}{3} + \frac{1}{3 \cdot 3^3} + \frac{1}{5 \cdot 3^5} + \frac{1}{7 \cdot 3^7} + \frac{1}{9 \cdot 3^9} + \dots \right) = A + \frac{1}{3} B + \frac{1}{5} C + \frac{1}{7} D + \frac{1}{9} E + \dots

where A is put for \frac{2}{3}, B for \frac{2}{3^3} = \frac{A}{9}, C for \frac{2}{3^5} = \frac{B}{9}, D for \frac{2}{3^7} = \frac{C}{9}, &c. The calculation will be as follows.

A=.66666666666
B\frac{1}{3} A = .22222222222
C\frac{1}{5} B = .08888888889
D\frac{1}{7} C = .03202888889
E\frac{1}{9} D = .01304040404
F\frac{1}{11} E = .00572727273
G\frac{1}{13} F = .00222077020
H\frac{1}{15} G = .00096764706
I\frac{1}{17} H = .00043160360
K\frac{1}{19} I = .00017978648
L\frac{1}{21} K = .00007847118
M\frac{1}{23} L = .00003237921

A.66666666666
\frac{1}{3} B.22222222222
\frac{1}{5} C.08888888889
\frac{1}{7} D.03202888889
\frac{1}{9} E.01304040404
\frac{1}{11} F.00572727273
\frac{1}{13} G.00222077020
\frac{1}{15} H.00096764706
\frac{1}{17} I.00043160360
\frac{1}{19} K.00017978648
\frac{1}{21} L.00007847118
\frac{1}{23} M.00003237921

Nap. log. 2 = .69314718055

Thus, by a very easy calculation, we have obtained the Napierian logarithm of 2 true to the first ten places of figures; the accurate value, as far as the 12th place, being 0.693147180550.

If this very simple process by which we have found the logarithm of 2 (the whole of which is here actually put down), be compared with the laborious calculations which must have been performed to have found the same logarithm by the method explained in the beginning of this section, the great superiority of this method to the other, and even to the second method, by which we have found the numerical value of M, and the common logarithm of 3, must be very apparent.

In the same manner as we have found the logarithm of 2 we may find those of 3, 5, &c. In computing the logarithm

Nature of logarithm of 3 the series would converge by the powers of the fraction \frac{3-1}{3+1} = \frac{1}{2}, and in computing the logarithm of 5 it would converge by the powers of \frac{5-1}{5+1} = \frac{2}{3};

but in each of these cases the series would converge slower, and of course the labour would be greater than in computing the logarithm of 2. And if the number whose logarithm was required was still more considerable; as for example 199, the series would converge so slow as to be useless.

We may however avoid this inconvenience by again transforming this last formula into another which shall express the logarithm of any number by means of a series, and a logarithm supposed to be previously known.

To effect this new transformation, let \frac{1+u}{1-u} = 1 + \frac{u}{n}, then, by resolving this equation in respect of u, we have u = \frac{\infty}{2n+\infty}. Let these values of \frac{1+u}{1-u} and u be substituted in the formula,

\log. \frac{1+u}{1-u} = 2M \left( u + \frac{u^3}{3} + \frac{u^5}{5} + \frac{u^7}{7} + \dots \right)

and we have \log. \left( 1 + \frac{\infty}{n} \right) equal to

2M \left\{ \frac{\infty}{2n+\infty} + \frac{1}{3} \left( \frac{\infty}{2n+\infty} \right)^3 + \frac{1}{5} \left( \frac{\infty}{2n+\infty} \right)^5 + \dots \right\}
\text{but } \log. \left( 1 + \frac{\infty}{n} \right) = \log. \frac{n+\infty}{n} = \log. (n+\infty) - \log. n

therefore, by substituting this value of \log. \frac{n+\infty}{n}, and transposing \log. n to the other side of the equation, we have

\log. (n+\infty) = \log. n + 2M \left\{ \frac{\infty}{2n+\infty} + \frac{1}{3} \left( \frac{\infty}{2n+\infty} \right)^3 + \frac{1}{5} \left( \frac{\infty}{2n+\infty} \right)^5 + \dots \right\}

By the assistance of this formula, and the known properties of logarithms, we may proceed calculating the logarithm of one number from that of another as follows.

To find the Napierian logarithm of 3 from that of 2, which has been already found. We have here n=2, \infty=1, and \frac{\infty}{2n+\infty} = \frac{1}{3}. Therefore the logarithm required is equal to

\log. 2 + 2 \left( \frac{1}{3} + \frac{1}{3 \cdot 5^3} + \frac{1}{5 \cdot 5^5} + \frac{1}{7 \cdot 5^7} + \dots \right) \\ = \log. 2 + A + \frac{1}{3}B + \frac{1}{3 \cdot 5}C + \frac{1}{5 \cdot 5^3}D + \frac{1}{7 \cdot 5^5}E + \dots

where A is put for \frac{1}{3}, B for \frac{1}{25}, C for \frac{1}{125}, and so on.

The calculation may stand thus:

A = .400000000000 \\ B = \frac{1}{3}A = .133333333333 \\ C = \frac{1}{3 \cdot 5}B = .006666666666 \\ D = \frac{1}{5 \cdot 5^3}C = .000266666666
E = \frac{1}{7 \cdot 5^5}D = .000010240000 \\ F = \frac{1}{7 \cdot 5^7}E = .000000449600 \\ G = \frac{1}{7 \cdot 5^9}F = .000000016380 \\ H = \frac{1}{7 \cdot 5^{11}}G = .000000000660
A = .400000000000 \\ \frac{1}{3}B = .005333333333 \\ \frac{1}{3 \cdot 5}C = .000128000000 \\ \frac{1}{5 \cdot 5^3}D = .000003657143 \\ \frac{1}{7 \cdot 5^5}E = .000000113778 \\ \frac{1}{7 \cdot 5^7}F = .000000003724 \\ \frac{1}{7 \cdot 5^9}G = .000000000125 \\ \frac{1}{7 \cdot 5^{11}}H = .000000000004
.405465108108 \\ \text{Nap. log. 2} = .693147180551
\text{Nap. log. 3} = 1.098612288659

This logarithm is true to 10 decimal places, the accurate value to 12 figures being 1.098612288668.

To find the Napierian logarithm of 4. This is immediately had from that of 2 by considering that as 4=2^2, therefore \log. 4 = \log. 2 + \log. 2.

\text{Nap. log. 2} = .693147180551
\text{Nap. log. 4} = 1.386294361102

This logarithm is also true to 10 places besides the integer.

To find the Napierian logarithm of 5, from that of 4; we have n=4, \infty=1 & \frac{\infty}{2n+\infty} = \frac{1}{9}, therefore the logarithm of 5 is expressed by

\log. 4 + 2 \left( \frac{1}{9} + \frac{1}{3 \cdot 9^3} + \frac{1}{5 \cdot 9^5} + \frac{1}{7 \cdot 9^7} + \dots \right)
\log. 4 + A + \frac{1}{3}B + \frac{1}{3 \cdot 5}C + \frac{1}{5 \cdot 5^3}D + \dots

where A = \frac{1}{9}, B = \frac{1}{27}A, C = \frac{1}{15}B, &c.

The calculation:

A = .222222222222 \\ B = \frac{1}{3}A = .007407407407 \\ C = \frac{1}{3 \cdot 5}B = .000038709677 \\ D = \frac{1}{5 \cdot 5^3}C = .000000418150 \\ E = \frac{1}{7 \cdot 5^5}D = .000000005162 \\ F = \frac{1}{7 \cdot 5^7}E = .0000000000064
A = .222222222222 \\ \frac{1}{3}B = .000914494742 \\ \frac{1}{3 \cdot 5}C = .000006774035 \\ \frac{1}{5 \cdot 5^3}D = .000000059736 \\ \frac{1}{7 \cdot 5^5}E = .000000000574 \\ \frac{1}{7 \cdot 5^7}F = .0000000000006
.223143551315 \\ \text{Nap. log. 4} = 1.386294361102
\text{Nap. log. 5} = 1.609437912417

This result is also correct to the first ten places of decimals.

Nature of Logarithms, &c. The logarithm of 6 is found from those of 2 and 3 by considering, that because 6 = 2 \times 3, therefore \log. 6 = \log. 2 + \log. 3.

\text{Nap. log. } 2 = 0.693147180551
\text{Nap. log. } 3 = 1.098612288659
\text{Nap. log. } 6 = 1.791759469210

This result is correct as far as the tenth decimal place.

We might find the logarithm of 7 from the logarithm of 6, that is, from the logarithms of 3 and 2, in the same manner as we have found the logarithms of 5 and 3; but it may be more readily found from the logarithms of 2 and 5 by reasoning thus. Because

\frac{2 \times 5^2}{7^2} = \frac{50}{49}, \text{ therefore } \log. 2 + 2 \log. 5 = 2 \log. 7
= \log. \frac{50}{49}, \text{ and consequently}
\log. 7 = \frac{1}{2} \log. 2 + \frac{1}{2} \log. 5 - \frac{1}{2} \log. \frac{50}{49}

Now the logarithm of \frac{50}{49} may be readily obtained from the formula

\log. x = 2M \left\{ \frac{x-1}{x+1} + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^3 + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^5 + \dots \right\}

For substituting \frac{50}{49} for x, the formula gives

\begin{aligned} \text{Nap. log. } \frac{50}{49} &= 2 \left( \frac{1}{99} + \frac{1}{3.99} + \frac{1}{5.99} + \dots \right) \\ &= A + \frac{1}{2}B + \frac{1}{2}C + \dots \end{aligned}

where A = \frac{2}{9.11^2}, B = \frac{A}{9^2.11^2}, C = \frac{B}{9^2.11^2}, &c. This series converges with great rapidity, and a few of its terms will be sufficient to give the logarithm of 7, as appears from the following operation.

A = 0.20202020202
B = \frac{1}{9^2.11^2} A = 0.00002061220
C = \frac{1}{9^2.11^2} B = 0.00000000210
A = 0.20202020202
\frac{1}{2}B = 0.00000687073
\frac{1}{2}C = 0.00000000102
\text{Nap. log. } \frac{50}{49} = 0.20202707317
\frac{1}{2} \log. 2 = 0.34657359275
\log. 5 = 1.609437912417
1.956011502692
+ \log. \frac{50}{49} = 0.01010135368
\text{Nap. log. } 7 = 1.945910149034

This logarithm, like those we found before, is correct in the first ten decimal places. Nature of Logarithms, &c.

The logarithms of 8, 9, and 10 are immediately obtained from those of 2, 3, and 5, as follows:

\text{Nap. log. } 2 = 0.693147180551
\text{Nap. log. } 8 = 2.079441541653
\text{Nap. log. } 3 = 1.098612288659
\text{Nap. log. } 9 = 2.197224577318
\text{Nap. log. } 2 = 0.693147180551
\text{Nap. log. } 5 = 1.609437912417
\text{Nap. log. } 10 = 2.302585092968

Thus by a few calculations we have found the Napierian logarithms of the first ten numbers, each true to ten decimal places; and since the Napierian logarithm of 10 is now known, the modulus of the common system, which is the reciprocal of that logarithm will also be known, and will be

\frac{1}{2.302585092968} = 0.4342944819

The common logarithms of the first ten numbers may now be found from the Napierian logarithms by multiplying each of the latter by the modulus, or dividing by its reciprocal, that is, by the Napierian logarithm of 10. And as the modulus of the common system is so important an element in the theory of logarithms, we shall give its value, together with that of its reciprocal, as far as the 30th decimal place.

M = 0.43429448190325187651128918917
\frac{1}{M} = 2.302585092994045684017991454684

The formulas we have already given are sufficient for finding the logarithms of all numbers whatever throughout the table, but there are yet others which may often be applied with great advantage, and we shall now investigate some of these.

Because

\log. 2 = 2M \left\{ \frac{x-1}{x+1} + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^3 + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^5 + \dots \right\}

If we now suppose

x = \frac{n^2}{n^2-1} = \frac{n^2}{(n-1)(n+1)}

so that \frac{x-1}{x+1} = \frac{1}{2n^2-1}, then the formula becomes

\begin{aligned} \log. \frac{n^2}{(n-1)(n+1)} &= 2M \left\{ \frac{1}{2n^2-1} + \right. \\ &\quad \left. \frac{1}{2} \left( \frac{1}{2n^2-1} \right)^3 + \frac{1}{2} \left( \frac{1}{2n^2-1} \right)^5 + \dots \right\} \end{aligned}

Nature of Logarithms, &c. But \log. \frac{n^3}{(n-1)(n+1)} = 2 \log. n - \log. (n-1) - \log. (n+1), therefore, putting N for the series

2M \left\{ \frac{1}{2n^2-1} + \frac{1}{2} \left( \frac{1}{2n^2-1} \right)^2 + \frac{1}{3} \left( \frac{1}{2n^2-1} \right)^3 + \dots \right\}

we have this formula,

2 \log. n - \log. (n-1) - \log. (n+1) = N

and hence, as often as we have the logarithms of any two of three numbers whose common difference is unity, the logarithm of the remaining number may be found. Example. Having given

\begin{aligned} \text{the common log. of } 9 &= 0.95424250943 \\ \text{the common log. of } 10 &= 1; \end{aligned}

it is required to find the common logarithm of 11.

Here we have n=10, so that the formula gives in this case 2 \log. 10 - \log. 9 - \log. 11 = N, and hence we have

\log. 11 = 2 \log. 10 - \log. 9 - N,
\text{where } N = \frac{2M}{199} + \frac{2M}{3.199^2} + \dots
M \text{ being } .43429448190.

Calculation of N.

A = \frac{2M}{199} = .00436476366
B = \frac{A}{3.199^2} = .0000003674
.00436480540
2 \log. 10 = 2.0000000000
\log. 9 = 0.95424250943
N = 0.00436480540
\log. 9 + N = 0.95860731483
\log. 11 = 1.04139268517

Here the series expressed by N converges very fast, so that two of its terms are sufficient to give the logarithm true to 10 places of decimals. But the logarithm of 11 may be expressed by the logarithms of smaller numbers and a series which converges still more rapidly, by the following artifice, which will apply also to some other numbers. Because the numbers 98, 99, and 100 are the products of numbers, the greatest of which is 11, for 98 = 2 \times 7^2, 99 = 9 \times 11, and 100 = 10 \times 10, it follows that if we have an equation composed of terms which are the logarithms of these three numbers, it may be resolved into another, the terms of which shall be the logarithms of the number 11 and other smaller numbers. Now by the preceding formula, if we put 99 for n, we have

2 \log. 99 - \log. 98 - \log. 100 = N,

that is, substituting \log. 9 + \log. 11 for \log. 99, \log. 2 +

2 \log. 7 \text{ for } \log. 98, \text{ and } 2 \log. 10 \text{ for } \log. 100,
2 \log. 9 + 2 \log. 11 - \log. 2 - 2 \log. 7 - 2 \log. 10 = N,

and hence by transposition, &c.

\log. 11 = \frac{1}{2} N + \frac{1}{2} \log. 2 + \log. 7 - \log. 9 + \log. 10;

and in this equation.

N = \frac{2M}{19601} + \frac{2M}{19601^2} + \dots

The first term alone of this series is sufficient to give the logarithm of 11 true to 14 places.

Another formula, by which the logarithm of a number is expressed by the logarithms of other numbers and a series, may be found as follows.

Refusing the formula

\log. x = 2M \left\{ \frac{x-1}{x+1} + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^2 + \frac{1}{3} \left( \frac{x-1}{x+1} \right)^3 + \dots \right\}

Let us assume

x = \frac{(n-1)(n+2)}{(n-2)(n+1)} = \frac{n^3 - 3n + 2}{n^3 - 3n - 2}
\text{then } \frac{x-1}{x+1} = \frac{2}{n^3 - 3n}

Let these values of x, & \frac{x-1}{x+1} be substituted in the formula, and it becomes

\log. \frac{(n-1)(n+2)}{(n-2)(n+1)} = 2M \left\{ \frac{2}{n^3 - 3n} + \frac{1}{2} \left( \frac{2}{n^3 - 3n} \right)^2 + \dots \right\}

But the quantity on the left-hand side of this equation is manifestly equal to 2 \log. (n-1) + \log. (n+2) - \log. (n-2) - 2 \log. (n+1), therefore, putting P for the series.

2M \left\{ \frac{2}{n^3 - 3n} + \frac{1}{2} \left( \frac{2}{n^3 - 3n} \right)^2 + \frac{1}{3} \left( \frac{2}{n^3 - 3n} \right)^3 + \dots \right\}

we have this formula.

\log. (n+2) + 2 \log. (n-1) - \log. (n-2) - 2 \log. (n+1) = P

By this formula we may find, with great facility, the logarithm of any one of the four numbers n-2, n-1, n+1, n+2, having the logarithms of the other three. We may also employ it in the calculation of logarithms, as in the following example. Let the numbers 5, 6, 7, 8, be substituted successively in the formula; then, observing that \log. 6 = \log. 2 + \log. 3, and \log. 8 = 3 \log. 2, we have these four equations.

\log. 7 + 2 \log. 2 - 3 \log. 3 = \frac{2M}{55} + \frac{2M}{3.55^2} + \dots
-2 \log. 7 + \log. 2 + 2 \log. 5 = \frac{2M}{99} + \frac{2M}{3.99^2} + \dots
4 \log. 3 - 4 \log. 2 - \log. 5 = \frac{2M}{161} + \frac{2M}{3.161^2} + \dots
\log. 5 - 5 \log. 3 + 2 \log. 7 = \frac{2M}{244} + \frac{2M}{3.244^2} + \dots

Let \log. 2, \log. 3, \log. 5 and \log. 7 be now considered as four unknown quantities, and by resolving these equations in the usual manner, (see ALGEBRA, Sect. VIII.) the logarithms may be determined.

Refusing once more the formula

\log. x = 2M \left\{ \frac{x-1}{x+1} + \frac{1}{2} \left( \frac{x-1}{x+1} \right)^2 + \dots \right\},

etc.

Nature of Logarithms, let \frac{n^2(n+5)(n-5)}{(n+3)(n-3)(n+4)(n-4)} be substituted in it &c.

instead of x, then, by this substitution \frac{x-1}{x+1} will become

\frac{-72}{n^4-25n^2+72} the formula will be transformed to

\log. \frac{n^2(n+5)(n-5)}{(n+3)(n-3)(n+4)(n-4)} = -2M \left\{ \frac{72}{n^4-25n^2+72} + \frac{1}{2} \left( \frac{72}{n^4-25n^2+72} \right)^{\frac{1}{2}} + \dots \right\}

Hence, putting the latter side of this equation equal to Q, we have this formula,

2 \log. n + \log. (n+5) + \log. (n-5) - \log. (n+3) - \log. (n-3) - \log. (n+4) - \log. (n-4) + Q = 0

which may be applied to the calculation of logarithms in the same manner as the former.

When it is required to find the logarithm of a high number, as for example 1231, we may proceed as follows:

\log. 1231 = \log. (1230 + 1) = \log. \left\{ 1230 \left( 1 + \frac{1}{1230} \right) \right\}
= \log. 1230 + \log. \left( 1 + \frac{1}{1230} \right)

Again, \log. 1230 = \log. 2 + \log. 5 + \log. 123 and \log.

123 = \log. \left\{ 120 \left( 1 + \frac{1}{40} \right) \right\}
= \log. 120 + \log. \left( 1 + \frac{1}{40} \right)

\log. 120 = \log. (2^1 \times 3 \times 5) = 3 \log. 2 + \log. 3 + \log. 5

Therefore

\log. 1231 = 4 \log. 2 + \log. 3 + 2 \log. 5 + \log. \left( 1 + \frac{1}{40} \right) + \log. \left( 1 + \frac{1}{1230} \right)

Thus the logarithm of the proposed number is expressed by the logarithms of 2, 3, 5, and the logarithms of 1 + \frac{1}{40}, 1 + \frac{1}{1230}, all of which may be easily found by the formulas already delivered.

Having now explained, at considerable length, the theory of logarithms upon principles purely analytical, such being, as we conceive, the most natural way of reasoning concerning the properties of number, we shall conclude this section by stating briefly the ground upon which it was referred to the principles of geometry by the mathematicians of the 17th century. Let C be the centre, and CH, CK the asymptotes of an hyperbola. In either of these let there be taken any number of continual proportionals CA, CB, CD, CE, &c. then if Bb, Dd, Ee, &c. be drawn parallel to the other asymptote, meeting the curve in a, b, d, e, &c. the hyperbolic spaces AabB, BbdD, DdeE, &c. are equal to one another; also if straight lines be drawn from C to the points a, b, d, e, &c. the hyperbolic sectors aCb, bCd, dCe, &c. shall also be equal (CONIC SECTIONS Part III. prop. 30.) Now, since it

appears by this proposition that the segments CA, CB, CD, CE, &c. of the asymptote being taken in continued geometrical progression, the corresponding hyperbolic areas AabB, BbdD, DdeE, &c. constitute a series of quantities in continued arithmetical progression, it is evident that the two series will have, in respect to each other, the same properties as numbers and their logarithms; so that, if we assume CA any segment of the asymptote as the representative of unity, and suppose CB, CD, CE, &c. to be the representatives of other numbers, the hyperbolic areas AabB, BbdD, DdeE will be the geometrical representatives of the logarithms of these numbers; and so also will the hyperbolic sectors aCb, bCd, dCe, &c.

Let CA (the line denoting unity) be the side of a rhombus CAaL inscribed at the vertex of the hyperbola, and let CP = n \times CA (n being put for any number); draw Pp parallel to CL meeting the hyperbola in p, then it may be shewn, by the methods usually employed in reasoning about curvilinear areas, that the area of the rhombus CAaL is to the hyperbolic area AapP as 1 to the Napierian logarithm of the number n. Therefore if the hyperbola be equilateral, so that AaLc is a square, &c. consequently its area = 1 \times 1 = 1, the Napierian logarithm of n, and the area AapP may be taken as the mutual representatives of each other. It is this circumstance which induced mathematicians to call these logarithms hyperbolic. But with equal propriety might the logarithms of any other system be called hyperbolic, as they may be equally expressed by the area of the equilateral hyperbola, or indeed by the area of any hyperbola whatever, (see FLUXIONS § 152. Ex. 5.)

SECT. II.

DESCRIPTION AND USE OF THE TABLE.

THE common system of logarithms is so constructed, that, 0 being the logarithm of unity, or 1, the logarithm of 10 is 1; by which it happens that the logarithm of 100 is 2, that of 1000 is 3, and so on. Also, the logarithm of \frac{1}{10}, or .1, is -1, that is, 1 considered as subtractive; or, in the language of algebra, minus one; and the logarithm of \frac{1}{100}, or .01, is -2; and the logarithm of .001 is -3, and so on, as in the following short table.

Numbers. Logarithms.
..... ..
.001 -3
.00 -2
.1 -1
1 0
10 1
100 2
1000 3
&c. &c.

As the terms of the geometrical progression 1, 10, 100, &c. continued backwards as well as forward, are the only numbers whose logarithms are integers; the logarithms of all other numbers whatever must be either fractions, or mixt numbers. Accordingly, the logarithms of all numbers, whether integer or mixt, between 1 and 10 are expressed by decimal fractions less than

Description than unity. The logarithms of numbers between 10 and 100 are expressed by mixt numbers composed of the Table.

unity and a decimal fraction. The logarithms of numbers between 100 and 1000 are expressed by mixt numbers composed of the number 2 and a decimal fraction, and so on. On the other hand, the logarithm of any vulgar or decimal fraction less than 1, but greater than \frac{1}{10} or .1, will be some negative decimal fraction between 0 and -1; and the logarithm of any fraction between .1 and .01, will be a negative mixed quantity between -1 and -2, and so on.

But it must be remarked, that any fraction, or mixt number, considered as entirely negative, may always be transformed into another mixt number of equal value, that shall have its integer part negative, but its fractional part positive, by diminishing the integer by unity, and increasing the fractional part by the same quantity. Thus let the mixt quantity be -2\frac{1}{10}, which may be also written thus -2-\frac{1}{10}. Let the integer -2 be diminished by 1, and the result is -2-1=-3. Also, let the fraction -\frac{1}{10} be increased by 1, and it becomes -\frac{1}{10}+1=+\frac{9}{10}; therefore the fraction -2\frac{1}{10} or -2.3, when transformed, is -3+\frac{9}{10}, or -3+.7, which may be written thus, \overline{3}.7; where the negative sign is placed over the integer to indicate that it is the only part of the expression that is considered as negative, the other part, viz. .7, being reckoned positive.

Since therefore any fractional or mixt quantity, considered as entirely negative, is equivalent to another mixt quantity, the integer part of which only is negative, but the fractional part positive, it is evident that instead of expressing the logarithms of fractions by numbers considered as entirely negative, we may express them by numbers having their integer parts negative, and their decimal parts positive; and it is usual so to express them. Thus the logarithm of .03, instead of being expressed by -1.52288, that is, by -1-\overline{52288}, is usually expressed by \overline{2}.47712, by which is to be understood -2+\overline{47712}. Again, the logarithm of .7, which, if considered as entirely negative, would be -1.5490, is otherwise \overline{1}.84510.

As the logarithms of any series of numbers forming a geometrical progression, the common ratio of which is 10, will exceed each other by the logarithm of 10, that is, by 1, it follows that the logarithms of all numbers denoted by the same figures, and differing only in the position of the decimal point, will have the decimal part of their logarithms the same; but the integers standing before the decimals will be different, and will be positive or negative, according as the numbers are whole or fractional, as in these examples.

Numbers. Logarithms.
69150 4.83980
6915 3.83980
691.5 2.83980
69.15 1.83980
6.915 0.83980
.6915 \overline{1}.83980
.06915 2.83980

The integer figure of a logarithm, is called its index or characteristic; and it is always less by one than the

VOL. XII. Part I.

number of integer figures which the natural number consists of; or it is equal to the distance of the first figure from the place of units or first place of integers, whether on the left or on the right of it.

The table of logarithms given at the end of this article, contains the decimal parts of the logarithms of all numbers from 1 to 10,000; and indeed of all numbers which can be expressed by four figures, preceded or followed by any numbers of ciphers, such as the numbers 367500, .002795, &c. The index, however, is not put down; but it is easily supplied by the rule which has just now been given. The table also contains the differences of the logarithms of all numbers from 1000 to 10,000, by means of which the logarithm of any number consisting of five figures may be easily obtained.

1. To find the logarithm of any number consisting of four or any smaller number of figures. Look for the number in the columns titled at the top Numbers; and in the same line with it, on the right, in the column of logarithms, will be found the decimal part of its logarithm, to which supply the decimal point, and its index according to rule delivered above. Thus,

The log. of 9 is found to be 0.95424
of 17 1.23045
of 2.63 0.41996
of 13.42 1.12775
of 6280 3.79796
of 3749 3.57392
of .6027 \overline{1}.78010
of .00234 3.36922
of 852600 5.93075

2. To find the logarithm of a number consisting of five figures.

Find the decimal part of the logarithm of the first four figures of the number, (that is, find the logarithm of the proposed number as if the last figure were a cipher), by the preceding rule, and find the difference between that logarithm and the next greater, as given in the column of differences (to the right of the column of logarithms). Then state this proportion:

As 10,
To the tabular difference,
So is the last, or fifth figure of the number,
To a fourth proportional;

which being added to the former logarithm, and the decimal point and index supplied, will be the logarithm sought.

Example. Required the logarithm of 186.47. The decimal part of the logarithm of the first four figures, viz. 1864, is .27045, and the difference opposite to it in the column marked D on the top is 23. Therefore we have this proportion:

10 : 23 :: 7 : \frac{7 \times 23}{10} = 16.1

The fourth proportional is 16.1, or, rejecting the decimal part, 16 nearly; therefore,

\begin{array}{r} \text{to log. of } 1684 \\ \text{add} \end{array} \quad \begin{array}{r} .27045 \\ 16 \end{array}
\begin{array}{r} \text{the log. of } 168.47 \text{ is} \\ \text{L} \end{array} \quad \begin{array}{r} 2.27061 \end{array}

3. To

Description
and Use of
the Table.
3. To find the logarithm of a vulgar fraction or mixed number.

Either reduce the vulgar fraction to a decimal, and find its logarithm as above, or else (having reduced the mixed number to an improper fraction) subtract the logarithm of the denominator from the logarithm of the numerator, and the remainder will be the logarithm of the fraction sought.

Ex. 1. To find the logarithm of \frac{1}{2}.
From the log. of 3 0.47712
Subtract the log. of 16 1.20412
Rem. log. of \frac{1}{2} or of .1875 1.27300

Here, as the lower number is greater than the upper, the remainder must be negative; the subtraction, however, is so performed, that the decimal part of the remainder is positive, and the integer negative.

Ex. 2. To find the logarithm of 13\frac{1}{2} or 13.5.
From log. of 55 1.74036
Subtract log. of 4 0.60206
Rem. log. of 13\frac{1}{2} or of 13.75 1.13830
4. To find the number corresponding to any given logarithm.

Seek the decimal part of the proposed logarithm in the column of logarithms, and if it be found exactly, the figures of the number corresponding to it will be found in the same line with it in the column of numbers. If the index of the given logarithm is 3, the four figures of the numbers thus found are integers; but if it be 2, the three first figures are integers, and the fourth is a decimal, and so on; the number of integer figures before the decimal point being always one greater than the index, if it be positive; but if it be negative, the number sought will be a decimal, and the number of cyphers between the decimal point and first significant figure will be one less than the index.—Examples. The number corresponding to the logarithm 3.57392 is 3749. The number corresponding to 1.12775 is 13.42. The number corresponding to 3.36922 is .00234, and so on.

But if the given logarithm is not exactly found in the table, subtract the next less tabular logarithm from it, and take the difference between that logarithm, and the next greater (as given in the column of differences). Then state this proportion:

As the difference, taken from the table,
Is to 10,
So is the difference between the given logarithm and
the next less,
To a fourth proportional,

which being annexed to the four figures corresponding to the logarithm next less than the given one, will be the logarithm required.

Example. Find the number answering to the logarithm 4.13278.

The dec. part of given log. is .13278
That of next less, viz. log. of 1357, is .13258

Difference 20

The tabular difference is 32, therefore we have this proportion,

32 : 10 :: 20 : \frac{20 \times 10}{32} = 6 \text{ nearly.}

Therefore the number corresponding to the proposed logarithm is .13576.

In like manner may the numbers to the following logarithms be found.

Logarithms. Numbers.
1.23457 17.162
3.73430 5423.8
1.09214 .12363
4.61230 40954

The table of logarithms of numbers is followed by a Table of logarithmic Sines and Tangents, for every minute of the quadrant, with their differences. For the explanation of this table we refer to TRIGONOMETRY, to which branch of mathematics it is intended to be applied.

We shall now give practical rules, illustrated by examples, for performing the different operations of arithmetic by logarithms.

MULTIPLICATION BY LOGARITHMS.
RULE.

TAKE out the logarithms of the factors from the table; then add them together, and their sum will be the logarithm of the product required. Then find, by inspection of the table, the natural number answering to their sum, and it will be the product required.

Observing to add what is to be carried from the decimal part of the logarithm to the positive index or indices, or else subtract it from the negative.

Also adding the indices together when they are of the same kind, that is, both positive or both negative; but subtracting the less from the greater when the one is positive and the other negative, and prefixing the sign of the greater to the remainder.

EXAMPLES.
Ex. 1. To multiply 2.314 by 50.62.
Numbers. Logarithms.
2.314 0.36436
50.62 1.70432
Product 117.13 2.06868
Ex. 2. To multiply 2.5819 by 3.4573.
Numbers. Logarithms.
2.5819 0.41194
3.4573 0.53874
Prod. 8.9265 0.95068

LOGARITHMS.

Ex. 3. To multiply 39.02, and 597.16, and .03147 together.

Numbers. Logarithms.
39.02 1.59129
597.16 2.77609
.03147 2.49790

Prod. 733.3      2.86528

Here the sum of the positive indices, together with 1 which we carry, is 4, and from this we subtract 2, because of the negative index —2.

Ex. 4. To multiply 3.586 and 2.1046, and 0.8372 and 0.0294 all together.

Numbers. Logarithms.
3.586 0.55461
2.1046 0.32317
0.8372 1.92283
0.0294 2.46835
1.26896

Here the 2 to carry cancels the —2, and there remains the —1 to set down.

DIVISION BY LOGARITHMS.

RULE.

SUBTRACT the logarithm of the divisor from the logarithm of the dividend, and the number answering to the remainder will be the logarithm of the quotient required.

Observing to change the sign of the index of the divisor from positive to negative, or from negative to positive; then take the sum of the indices if they be of the same name, or their difference when they have different signs, with the sign of the greater for the index to the logarithm of the quotient.

Also, when 1 is borrowed in the left-hand place of the decimal part of the logarithm, add it to the index of the divisor when that index is positive, but subtract it when negative; then let the index arising from thence be changed, and work with it as before.

EXAMPLES.

Ex. 1. To divide 24163 by 4567.

Numbers. Logarithms.
Divid. 24163 4.38315
Divis. 4567 3.65963
Quot. 5.2908 0.72352

Ex. 2. To divide 37.15 by 523.76.

Numbers. Logarithms.
Divid. 37.15 1.56996
Div. 523.76 2.71913
Quot. .07093 2.85083

Ex. 3. Divide .06314 by .007247.

Numbers. Logarithms.
Divid. .06314 2.80030
Divis. .007247 3.85980
Quot. 8.720 0.94050

Here 1 carried from the decimals to the —3 makes it —2, which taken from the other —2, leaves 0 remaining.

Ex. 4. Divide .7438 by 12.947.

Numbers. Logarithms.
Divid. .7438 1.87146
Divis. 12.947 1.11218
Quot. .057449 2.75928

Here the 1 taken from the —1 makes it become —2 to set down.

PROPORTION BY LOGARITHMS.

RULE.

ADD the logarithms of the second and third terms, and from the sum subtract the logarithm of the first term by the foregoing rules, the remainder will be the logarithm of the fourth term required.

Or in any compound proportion whatever, add together the logarithms of all the terms that are to be multiplied; and from that sum take the sum of the others, the remainder will be the logarithm of the answer.

But, instead of subtracting any logarithm, we may add its arithmetical complement, and the result will be the same. By the arithmetical complement is meant the logarithm of the reciprocal of the given number, or the remainder by taking the given logarithm from 0, or from 10, changing the beginning of the scale from 0 to 10; the easiest way of doing which is to begin at the left hand, and subtract each figure from 9, except the last significant figure on the right hand, which must be subtracted from 10. But when the index is negative, it must be added to 9, and the rest subtracted as before; and for every complement that is added subtract 10 from the last sum of the indices.

EXAMPLES.

Ex. 1. Find a fourth proportional to 72.34, 2.519, and 357.48.

Numbers. Logarithms.
As 72.34 1.85938
To 2.519 0.40123
So is 357.48 2.55325
2.95448
To 12.448 1.09510

Here the logarithms of the second and third terms are added together, and the logarithm of the first term is subtracted from the sum; but by taking the arithmetical

Description and Use of the Table. Description and Use of the Table.

As 72.34 Comp. log. 8.14062
To 2.519 0.40123
So is 357.48 2.55325
To 12.448 1.09510

Ex. 2. If the interest of 1001. for a year, or 365 days, be 4.5, What will be the interest of 279.251. for 274 days.

As { 100 Comp. log. { 8.00000
{ 365 { 7.43771
To { 279.25 2.44599
{ 274 2.43775
So is 4.5 0.65321
To 9.4333 0.97466

Here, instead of subtracting the sum of the logarithms of 100 and 365, we add the arithmetical complement of the logarithms of these numbers, and subtract 20 from the sum of the indices.

INVOLUTION BY LOGARITHMS.
RULE.

MULTIPLY the logarithm of the given number by the index of the power, and the number answering to the product will be the power required.

Note.—In multiplying a logarithm with a negative index by a positive number, the product will be negative. But what is to be carried from the decimal part of the logarithm will always be positive. And therefore the difference will be the index of the product, and is always to be made of the same kind with the greater.

EXAMPLES.

Ex. 1. To square the number 2.579.

Number. Logarithm.
Root 2.569 0.41145
The index 2
Power 6.6513 0.82290

Ex. 2. To find the cube of 3.0715.

Number. Logarithm.
Root 3.0715 0.48735
The index 3
Power 28.976 1.46205

Ex. 3. To raise .09163 to the fourth power.

Number. Logarithm.
Root .09163 2.96204
4
Power .000070495 5.84816

Here 4 times the negative index being -8, and

3 to carry, the difference -5, is the index of the product.

Ex. 4. To raise 1.0045 to the 365th power.

Number. Logarithm.
Root 1.0045 0.00195
The index 365
975
1170
585
Power. 5.1493 .71175
EVOLUTION BY LOGARITHMS.
RULE.

DIVIDE the logarithm of the number by the index of the root, and the number answering to the quotient is the root sought.

When the index of the logarithm to be divided is negative, and does not exactly contain the divisor without some remainder, increase the index by such a number as will make it exactly divisible by the index of the root, carrying the units borrowed as so many tens to the left-hand place of the decimal, and then divide as in whole numbers.

EXAMPLES.

Ex. 1. Find the square root of 2.

Number. Logarithm.
Power 2 2)0.30103
Root 1.4142 0.15051

Ex. 2. Find the 10th root of 365.

Number. Logarithm.
Power 365 10)2.56229
Root 1.804 0.25623

Ex. 3. To find \sqrt[3]{.093}.

Number. Logarithm.
Power .093 2)2.96848
Root .30496 1.48424

Here the divisor 2 is contained exactly in the negative index -2, and therefore the index of the quotient is -1.

Ex. 4. To find \sqrt[3]{.00048}.

Number. Logarithm.
Power .00048 3)4.68124
Root .078298 2.89375

Here the divisor 3, not being exactly contained in -4, it is augmented by 2 to make up 6, in which the divisor is contained just 2 times, then the 2 thus borrowed being carried to the decimal figure 6, makes 26, which divided by 3 gives 8, &c.

LOGARITHMS OF NUMBERS.

N.Log.N.Log.N.Log.N.Log.N.Log.N.Log.N.Log.
1000006077815120079181802552724038021300477123605563042062325
2001036178533121082791812576824138202301478573615575142162428
301126279239122086301822600724238382302480013625587142262531
402066379934123089911832624524338561303481443635599142362634
503096480618124093421842648224438739304482873645611042462737
604116581291125096911852671724538917305484303655622942562839
705136681954126100371862695124639094306485723665634842662941
806156782607127103801872718424739270307487143675646742763043
907186883251128107211882741624839445308488553685658542863144
1008206983885129110591892764624939620309489963695670342963246
1114227084510130113941902787525039794310491363705682043063347
1220247185126131117271912810325139967311492763715693743163448
1326267285733132120571922833025240140312494153725705443263548
1432287386332133123831932855625340312313495543735717143363649
1538297486923134127101942878025440483314496933745728743463749
1644317587506135130331952900325540654315498313755740343563849
1750327688081136133541962922625640824316499693765751943663949
1856347788649137136721972944725740993317501063775763443764048
1962357889209138139881982966725841162318502433785774943864147
2068377989763139143011992988525941330319503793795786443964246
2174388090309140146132003010326041497320505153805797844064345
2280408190849141149222013032026141663321506513815809244164444
2386418291381142152202023053526241830322507863825820644264542
2492438391908143155342033075026341996323509203835832044364640
2598448492428144158362043096326442160324510533845843344464738
2704468592942145161372053117526542325325511883855854644564836
2810478693450146164352063138726642488326513223865865944664933
2916498793952147167322073159726742651327514533875877144765031
3022508894448148170262083180626842813328515873885888344865128
3128528994939149173192093201526942975329517203895899544965225
3234539095424150176092103222227043136330518513905910045065321
3340559195904151178982113242827143297331519833915921845165418
3446569296379152181842123263427243457332521143925932945265514
3552579396848153184692133283827343616333522443935943945365610
3658599497313154187522143304127443773334523753945955045465706
3764609597772155190332153324427543933335525043955966245565801
3870629698227156193122163344527644091336526343965977045665896
3976639798677157195902173364627744248337527633975987945765992
4082649899123158198662183384627844404338528923985998845866087
4188659999564159201402193404427944560339530203996009745966181
429467100100000160204122203424228044716340531484006020646066276
439668101100432161206832213443928144871341532754016031446166370
449869102100860162209522223463528245025342534034026042346266464
460071103101283163212192233483028345179343535294036053146366558
470272104101703164214842243502528445332344536564046063846466652
480474105102119165217482253521828545484345537824056074646566745
490675106102531166220112263541128645637346539084066085346666839
500877107102938167222722273560328745788347540334076095946766932
511078108103342168225312283579328845939348541584086106646867025
521280109103743169227892293598428946090349542834096117246967117
531481110104139170230432303617329046240350544074106127847067210
541682111104532171233002313636129146389351545314116138447167302
551884112104922172235532323654929246538352546544126149047267394
562085113105308173238052333673629346687353547774136159547367486
572287114105690174240532343692229446835354549004146170047467578
582489115106070175243042353710729546982355550234156180547567669
592690116106446176245512363729129647129356551454166190947667761
602892117106810177247972373747329747276357552674176201447767852
613093118107188178250422383765829847422358553884186211847867943
623295119107555179252852393784029947567359555094196222147968034
633496120107918180255272403802130047712360556304206232548068124
N. Log. N. Log. N. Log. N. Log. N. Log. N. Log.
480681245407323960077815660819547208573378089206
481681355417324060177887661820207218579478189263
482682035427340060277960662820867228585478289321
483683055437348060378032663821517238591478389376
484684855447360060478104664822177248597478489432
485685745457364060578176665822827258603478589487
486686645467371960678247666823477268609478689542
487687535477379060778319667824137278615378789597
488688425487387860878390668824787288621378889653
489689315497395760978462669825437298627378989708
490690205507403661078533670826077308633279089763
491691085517411561178604671826727318639279189818
492691975527419461278675672827377328645179289873
493692855537427361378746673828027338651079389927
494693735547435161478817674828667348657079489982
495694615557442961578888675829307358662979590037
496695485567450761678958676829957368668879690091
497696365577458661779029677830597378674779790146
498697235587466361879099678831237388680679890200
499698105597474161979169679831877398686479990255
500698975607481962079239680832517408692380090309
501699845617489662179309681833157418698280190363
502700705627497462279375682833787428704080290417
503701575637505162379449683834427438709980390472
504702435647512862479518684835067448715780490526
505703295657520562579588685835697458721680590580
506704155667528262679657686836327468727480690634
507705015677535862779727687836967478733280790687
508705865687543562879796688837597488739080890741
509706725697551162979865689838227498744880990795
510707575707558763079934690838857508750681090849
511708425717566463180003691839487518756481190902
512709275727574063280072692840117528762281290956
513710125737581563380140693840737538767981391009
514710965747589163480209694841367548773781491062
515711815757596763580277695841987558779581591116
516712655767604263680346696842617568785281691169
517713495777611863780414697843237578791081791222
518714335787619363880482698843867588796781891275
519715175797626863980550699844487598802481991328
520716005807634364080618700845107608808182091381
521716845817641864180686701845727618813882191434
522717675827649264280754702846347628819582291487
523718505837656764380821703846967638825282391540
524719335847664164480889704847577648830982491593
525720165857671664580956705848197658836682591645
526720995867679064681023706848827668842382691698
527721815877686464781090707849427678848082791751
528722635887693864881158708850037688853682891803
529723465897701264981224709850657698859382991855
530724285907708565081291710851267708864983091908
531725095917715965181358711851877718870583191960
532725915927723265281425712852487728876283292012
533726735937730565381491713853097738881883392065
534727545947737965481558714853707748887483492117
535728355957745265581622715854317758893083592169
536729165967752565681690716854917768898683692221
537729975977759765781757717855527778904283792273
538730785987767065881823718856127788909883892324
539731595997774365981889719856737798915483992376
540732396007781566081954720857337808920984092428

LOGARITHMS OF NUMBERS.

N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
96 98277 1020 0360 1080 03342 1140 05692 1200 07918 1260 10037 1320 12057
961 98273 1021 00403 43 1081 03383 41 1141 05729 39 1201 07954 36 1261 10072 35 1321 12090 33
962 98318 1022 00943 42 1082 03423 40 1142 05767 38 1202 07992 37 1262 10106 34 1322 12123 32
963 98363 1023 00988 43 1083 03463 40 1143 05805 38 1203 08027 36 1263 10149 34 1323 12156 31
964 98408 1024 01030 42 1084 03503 40 1144 05843 38 1204 08065 36 1264 10175 35 1324 12189 31
965 98453 1025 01072 42 1085 03543 40 1145 05881 38 1205 08099 36 1265 10209 34 1325 12222 31
966 98498 1026 01113 43 1086 03583 40 1146 05918 37 1206 08133 36 1266 10243 35 1326 12254 31
967 98543 1027 01157 42 1087 03623 40 1147 05956 38 1207 08171 36 1267 10278 35 1327 12287 31
968 98588 1028 01199 43 1088 03663 40 1148 05994 38 1208 08207 36 1268 10312 34 1328 12320 31
969 98632 1029 01242 42 1089 03703 40 1149 06032 38 1209 08243 36 1269 10346 34 1329 12352 31
970 98677 1030 01284 42 1090 03743 39 1150 06070 38 1210 08279 35 1270 10380 34 1330 12385 31
971 98722 1031 01326 42 1091 03782 40 1151 06108 38 1211 08314 36 1271 10415 34 1331 12418 31
972 98767 1032 01368 42 1092 03822 40 1152 06145 38 1212 08350 36 1272 10449 34 1332 12450 31
973 98811 1033 01410 42 1093 03862 40 1153 06183 38 1213 08386 36 1273 10483 34 1333 12483 31
974 98856 1034 01452 42 1094 03902 39 1154 06221 38 1214 08422 36 1274 10517 34 1334 12516 31
975 98900 1035 01494 42 1095 03941 40 1155 06258 38 1215 08458 36 1275 10551 34 1335 12548 31
976 98945 1036 01536 1096 03981 1156 06296 37 1216 08493 36 1276 10585 34 1336 12581 31
977 98989 1037 01578 42 1097 04021 39 1157 06333 37 1217 08529 36 1277 10619 34 1337 12613 31
978 99034 1038 01620 42 1098 04060 40 1158 06371 38 1218 08565 35 1278 10653 34 1338 12646 31
979 99078 1039 01662 42 1099 04100 39 1159 06408 38 1219 08600 35 1279 10687 34 1339 12678 31
980 99123 1040 01703 42 1100 04139 40 1160 06446 38 1220 08636 36 1280 10721 34 1340 12710 31
981 99167 1041 01745 42 1101 04179 39 1161 06483 37 1221 08672 36 1281 10755 34 1341 12743 31
982 99211 1042 01787 42 1102 04218 39 1162 06521 38 1222 08707 36 1282 10789 34 1342 12775 31
983 99255 1043 01828 42 1103 04258 39 1163 06558 37 1223 08743 35 1283 10823 34 1343 12808 31
984 99300 1044 01870 42 1104 04297 39 1164 06595 37 1224 08778 36 1284 10857 34 1344 12840 31
985 99344 1045 01912 42 1105 04336 40 1165 06633 38 1225 08814 36 1285 10890 33 1345 12872 31
986 99388 1046 01953 42 1106 04376 39 1166 06670 37 1226 08849 35 1286 10924 34 1346 12905 31
987 99432 1047 01995 41 1107 04415 39 1167 06707 37 1227 08884 36 1287 10958 34 1347 12937 31
988 99476 1048 02036 41 1108 04454 39 1168 06744 37 1228 08920 35 1288 10992 34 1348 12969 31
989 99520 1049 02078 41 1109 04493 39 1169 06781 37 1229 08955 35 1289 11025 33 1349 13001 31
990 99564 1050 02119 41 1110 04532 39 1170 06819 38 1230 08991 36 1290 11059 34 1350 13033 31
991 99607 1051 02160 42 1111 04571 39 1171 06856 37 1231 09026 35 1291 11093 34 1351 13066 31
992 99651 1052 02202 41 1112 04610 39 1172 06893 37 1232 09061 35 1292 11126 33 1352 13098 31
993 99695 1053 02243 41 1113 04649 39 1173 06930 37 1233 09096 35 1293 11160 33 1353 13130 31
994 99739 1054 02284 41 1114 04688 38 1174 06967 37 1234 09132 35 1294 11193 33 1354 13162 31
995 99782 1055 02325 41 1115 04727 39 1175 07004 37 1235 09167 35 1295 11227 34 1355 13194 31
996 99826 1056 02366 41 1116 04766 39 1176 07041 37 1236 09202 35 1296 11261 34 1356 13226 31
997 99870 1057 02407 41 1117 04805 39 1177 07078 37 1237 09237 35 1297 11294 33 1357 13258 31
998 99913 1058 02449 41 1118 04844 39 1178 07115 36 1238 09272 35 1298 11327 33 1358 13290 31
999 99957 1059 02490 41 1119 04883 39 1179 07151 37 1239 09307 35 1299 11361 33 1359 13322 31
1000 00000 43 1060 02531 41 1120 04922 39 1180 07188 37 1240 09342 35 1300 11394 34 1360 13354 31
1001 00043 44 1061 02572 40 1121 04961 38 1181 07225 37 1241 09377 35 1301 11428 34 1361 13386 31
1002 00087 43 1062 02612 41 1122 04999 39 1182 07262 37 1242 09412 35 1302 11461 33 1362 13418 31
1003 00130 43 1063 02653 41 1123 05038 39 1183 07298 36 1243 09447 35 1303 11494 33 1363 13450 31
1004 00173 44 1064 02694 41 1124 05077 38 1184 07335 37 1244 09482 35 1304 11528 33 1364 13481 31
1005 00217 43 1065 02735 41 1125 05115 39 1185 07372 36 1245 09517 35 1305 11561 33 1365 13513 31
1006 00260 43 1066 02776 40 1126 05154 38 1186 07408 37 1246 09552 35 1306 11594 34 1366 13545 31
1007 00303 43 1067 02816 41 1127 05192 39 1187 07445 37 1247 09587 35 1307 11628 34 1367 13577 31
1008 00346 43 1068 02857 41 1128 05231 39 1188 07482 36 1248 09621 34 1308 11661 33 1368 13609 31
1009 00389 43 1069 02898 40 1129 05266 39 1189 07518 37 1249 09656 35 1309 11694 33 1369 13640 31
1010 00432 43 1070 02938 41 1130 05308 38 1190 07555 36 1250 09691 35 1310 11727 33 1370 13672 31
1011 00475 43 1071 02979 40 1131 05346 39 1191 07591 37 1251 09726 35 1311 11760 33 1371 13704 31
1012 00518 43 1072 03019 41 1132 05385 38 1192 07628 37 1252 09760 34 1312 11793 33 1372 13735 31
1013 00561 43 1073 03060 41 1133 05423 38 1193 07664 36 1253 09795 35 1313 11826 33 1373 13767 31
1014 00604 43 1074 03100 41 1134 05461 39 1194 07700 37 1254 09830 35 1314 11860 34 1374 13799 31
1015 00647 42 1075 03141 40 1135 05500 38 1195 07737 36 1255 09864 35 1315 11893 33 1375 13830 31
1016 00689 43 1076 03181 41 1136 05538 38 1196 07773 36 1256 09899 35 1316 11926 33 1376 13862 31
1017 00732 43 1077 03222 40 1137 05576 38 1197 07809 37 1257 09934 35 1317 11959 33 1377 13893 31
1018 00775 43 1078 03262 40 1138 05614 38 1198 07846

LOGARITHMS OF NUMBERS.

N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
1440 15836 30 1500 17609 29 1560 19312 28 1620 20952 26 1680 22531 26 1740 24055 25 1800 25527 24 1860 26951 24
1441 15866 31 1501 17638 29 1561 19340 28 1621 20978 27 1681 22557 26 1741 24080 25 1801 25551 24 1861 26975 24
1442 15897 30 1502 17667 29 1562 19368 28 1622 21005 27 1682 22583 25 1742 24105 25 1802 25575 24 1862 26990 23
1443 15927 30 1503 17696 29 1563 19396 28 1623 21032 27 1683 22608 25 1743 24130 25 1803 25600 24 1863 27021 23
1444 15957 30 1504 17725 29 1564 19424 28 1624 21059 26 1684 22634 26 1744 24155 25 1804 25624 24 1864 27045 24
1445 15987 30 1505 17754 28 1565 19451 28 1625 21085 27 1685 22660 26 1745 24180 24 1805 25648 24 1865 27068 23
1446 16017 30 1506 17782 29 1566 19479 28 1626 21112 27 1686 22686 26 1746 24204 25 1806 25672 24 1866 27091 23
1447 16047 30 1507 17811 29 1567 19507 28 1627 21139 27 1687 22712 25 1747 24229 25 1807 25696 24 1867 27114 24
1448 16077 30 1508 17840 29 1568 19535 28 1628 21165 26 1688 22737 26 1748 24254 25 1808 25720 24 1868 27138 24
1449 16107 30 1509 17869 29 1569 19562 27 1629 21192 27 1689 22763 26 1749 24279 25 1809 25744 24 1869 27161 23
1450 16137 30 1510 17898 28 1570 19590 28 1630 21219 26 1690 22789 25 1750 24304 25 1810 25768 24 1870 27184 23
1451 16167 30 1511 17926 29 1571 19618 27 1631 21243 27 1691 22814 26 1751 24329 24 1811 25792 24 1871 27207 24
1452 16197 30 1512 17955 29 1572 19645 28 1632 21272 27 1692 22840 26 1752 24353 25 1812 25816 24 1872 27231 24
1453 16227 29 1513 17984 29 1573 19673 28 1633 21299 27 1693 22866 26 1753 24378 25 1813 25840 24 1873 27254 23
1454 16256 30 1514 18013 28 1574 19700 28 1634 21325 27 1694 22891 26 1754 24403 25 1814 25864 24 1874 27277 23
1455 16286 30 1515 18041 29 1575 19728 28 1635 21352 27 1695 22917 26 1755 24428 24 1815 25888 24 1875 27300 23
1456 16316 30 1516 18070 29 1576 19756 27 1636 21378 27 1696 22943 25 1756 24452 25 1816 25912 24 1876 27323 23
1457 16346 30 1517 18099 28 1577 19783 28 1637 21405 26 1697 22968 25 1757 24477 25 1817 25935 24 1877 27346 23
1458 16376 30 1518 18127 29 1578 19811 28 1638 21431 26 1698 22994 25 1758 24502 24 1818 25959 24 1878 27370 24
1459 16406 30 1519 18156 29 1579 19838 27 1639 21458 27 1699 23019 25 1759 24527 24 1819 25983 24 1879 27393 23
1460 16435 30 1520 18184 28 1580 19866 27 1640 21484 26 1700 23045 25 1760 24551 25 1820 26007 24 1880 27416 23
1461 16465 30 1521 18213 28 1581 19893 28 1641 21511 26 1701 23070 25 1761 24576 25 1821 26031 24 1881 27439 23
1462 16495 30 1522 18241 29 1582 19921 27 1642 21537 27 1702 23096 25 1762 24601 24 1822 26055 24 1882 27462 23
1463 16524 30 1523 18270 28 1583 19948 27 1643 21564 26 1703 23121 25 1763 24625 25 1823 26079 24 1883 27485 23
1464 16554 30 1524 18298 29 1584 19976 27 1644 21590 26 1704 23147 25 1764 24650 24 1824 26102 24 1884 27508 23
1465 16584 30 1525 18327 28 1585 20003 27 1645 21617 27 1705 23172 25 1765 24674 25 1825 26126 24 1885 27531 23
1466 16613 30 1526 18355 29 1586 20030 28 1646 21643 26 1706 23198 25 1766 24699 25 1826 26150 24 1886 27554 23
1467 16643 30 1527 18384 28 1587 20058 27 1647 21669 27 1707 23223 25 1767 24724 24 1827 26174 24 1887 27577 23
1468 16673 30 1528 18412 29 1588 20085 27 1648 21696 27 1708 23249 26 1768 24748 24 1828 26198 24 1888 27600 23
1469 16702 30 1529 18441 29 1589 20112 26 1649 21722 26 1709 23274 25 1769 24773 25 1829 26221 24 1889 27623 23
1470 16732 30 1530 18469 28 1590 20140 27 1650 21748 27 1710 23300 25 1770 24797 24 1830 26245 24 1890 27646 23
1471 16761 30 1531 18498 28 1591 20167 27 1651 21775 26 1711 23325 25 1771 24822 24 1831 26269 24 1891 27669 23
1472 16791 30 1532 18526 28 1592 20194 28 1652 21801 26 1712 23350 25 1772 24846 24 1832 26293 24 1892 27692 23
1473 16820 30 1533 18554 29 1593 20222 27 1653 21827 26 1713 23376 25 1773 24871 24 1833 26316 23 1893 27715 23
1474 16850 30 1534 18583 29 1594 20249 27 1654 21854 27 1714 23401 25 1774 24895 24 1834 26340 24 1894 27738 23
1475 16879 30 1535 18611 28 1595 20276 27 1655 21880 26 1715 23426 25 1775 24920 24 1835 26364 24 1895 27761 23
1476 16909 30 1536 18639 28 1596 20303 27 1656 21906 26 1716 23452 25 1776 24944 25 1836 26387 24 1896 27784 23
1477 16938 30 1537 18667 29 1597 20330 28 1657 21932 26 1717 23477 25 1777 24969 24 1837 26411 24 1897 27807 23
1478 16967 30 1538 18696 28 1598 20358 28 1658 21958 27 1718 23502 25 1778 24993 25 1838 26435 24 1898 27830 23
1479 16997 30 1539 18724 28 1599 20385 27 1659 21985 27 1719 23528 26 1779 25018 25 1839 26458 23 1899 27852 22
1480 17026 30 1540 18752 28 1600 20412 26 1660 22011 26 1720 23553 25 1780 25042 24 1840 26482 24 1900 27875 23
1481 17056 30 1541 18780 28 1601 20439 27 1661 22037 26 1721 23578 25 1781 25066 25 1841 26505 24 1901 27898 23
1482 17085 30 1542 18808 29 1602 20466 27 1662 22063 26 1722 23603 25 1782 25091 24 1842 26529 24 1902 27921 23
1483 17114 30 1543 18837 28 1603 20493 27 1663 22089 26 1723 23629 25 1783 25115 24 1843 26553 23 1903 27944 23
1484 17143 30 1544 18865 28 1604 20520 27 1664 22115 26 1724 23654 25 1784 25139 24 1844 26576 23 1904 27967 23
1485 17173 30 1545 18893 28 1605 20548 28 1665 22141 26 1725 23679 25 1785 25164 25 1845 26600 24 1905 27989 22
1486 17202 30 1546 18921 28 1606 20575 27 1666 22167 27 1726 23704 25 1786 25188 24 1846 26623 24 1906 28012 23
1487 17231 30 1547 18949 28 1607 20602 27 1667 22194 26 1727 23729 25 1787 25212 25 1847 26647 23 1907 28035 23
1488 17260 30 1548 18977 28 1608 20629 27 1668 22220 26 1728 23754 25 1788 25237 24 1848 26670 24 1908 28058 23
1489 17289 30 1549 19005 28 1609 20656 27 1669 22246 26 1729 23779 25 1789 25261 24 1849 26694 24 1909 28081 23
1490 17319 30 1550 19033 28 1610 20683 27 1670 22272 26 1730 23805 25 1
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
1920283302319802966721204030963212100322222121603344520222034635202280357932023403692218
1921283532219812968822204130984222101322432021613346521222134655192281358131923413694019
1922283752319822971022204231006212102322632121623348620222234674202282358321923423695918
1923283982319832973222204331027212103322842121633350620222334694192283358511923433697719
1924284212219842975422204431048212104323052021643352620222434713202284358701923443699618
1925284432319852977622204531069222105323252121653354620222534733202285358891923453701419
1926284662219862979822204631091212106323462021663356620222634753192286359081923463703318
1927284882319872982022204731112212107323662121673358620222734772202287359271923473705119
1928285112219882984221204831133212108323872121683360620222834792192288359461923483707018
1929285332319892986321204931154212109324082021693362620222934811192289359651923493708818
1930285562319902988522205031175222110324282121703364620223034830202290359841923503710718
1931285782319912990722205131197212111324492021713366620223134850192291360031823513712519
1932286012219922992922205231218212112324692121723368620223234869202292360211923523714418
1933286232319932995122205331239212113324902021733370620223334889192293360401923533716219
1934286462319942997321205431260212114325102121743372620223434908202294360591923543718118
1935286682319952999422205531281212115325312121753374620223534928192295360781923553719918
1936286912219963001622205631302212116325522021763376620223634947202296360971923563721818
1937287132219973003822205731323222117325722121773378620223734967192297361161923573723618
1938287352319983006021205831345212118325932021783380620223834986192298361351923583725419
1939287582319993008122205931366212119326132121793382620223935005202299361541923593727318
1940287802320003010322206031387212120326342121803384620224035025192300361731923603729118
1941288032220013012521206131408212121326542121813386619224135044202301361921923613731018
1942288252220023014622206231429212122326752021823388520224235064192302362111823623732818
1943288472320033016822206331450212123326952021833390520224335083192303362291923633734619
1944288702320043019022206431471212124327152121843392520224435102202304362481923643736518
1945288922220053021122206531492212125327362121853394520224535122192305362671923653738318
1946289142320063023322206631513212126327562121863396520224635141192306362861923663740119
1947289372220073025521206731534212127327772021873398520224735160202307363051923673742018
1948289592220083027622206831555212128327972121883400520224835180192308363241823683743819
1949289812220093029822206931576212129328182121893402520224935199192309363421823693745718
1950290032320103032022207031597212130328382121903404420225035218202310363611923703747518
1951290262220113034122207131618212131328582121913406420225135238192311363801923713749318
1952290482220123036321207231639212132328792021923408420225235257192312363991923723751119
1953290702220133038422207331660212133328992121933410420225335276192313364181823733753018
1954290922220143040622207431681212134329192121943412420225435295202314364361823743754818
1955291152320153042822207531702212135329402121953414320225535315192315364551923753756619
1956291372220163044922207631723212136329602221963416320225635334192316364741923763758518
1957291592220173047121207731744212137329802121973418320225735353192317364931823773760318
1958291812220183049222207831765202138330012121983420320225835372202318365111923783762118
1959292032320193051422207931785212139330212121993422320225935392202319365301923793763918
1960292262320203053522208031806212140330412122003424220226035411192320365491923803765818
1961292482220213055721208131827212141330622022013426220226135430192321365681823813767618
1962292702220223057822208231848212142330822022023428219226235449192322365861823823769418
1963292922220233060021208331869212143331022122033430120226335468202323366051923833771219
1964293142220243062122208431890212144331222122043432120226435488202324366241823843773118
1965293362220253064322208531911202145331432022053434120226535507192325366421923853774918
1966293582220263066421208631931212146331632022063436119226635526192326366611923863776718
1967293802320273068522208731952212147331832022073438020226735545192327366801823873778518
1968294032220283070721208831973212148332032122083440020226835564192328366981923883780318
1969294252220293072822208931994212149332242022093442019226935583202329367171923893782219
1970294472220303075022209032015202150332442022103443920227035603192330367361823903784018
1971294692220313077121209132035212151332642022113445920227135622192331367541923913785818
1972294912220323079222209232056212152332842022123447919227235641192332367731823923787618
1973295132220333081421209332077212153333042122133449820227335660192333367911923933789418
1974295352220343083521209432098202154333242022143451819227435679192334368101923943791219
1975295572220353085622209532118212155333452022153453720227535698192335368291823953793118
197629579222036308782120963213921215633365202216345572022763571719233636847192396379491
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
2400382211824603909417252040140172580411621726404216017270043136162760440911628204502515
2401382391824613911118252140157182581411791726414217717270143152172761441071528214504016
2402382571824623912917252240175172582411961626424219316270243169162762441221628224505615
2403382751824633914618252340192172583412121726434221016270343185162763441381628234507115
2404382931924643916418252440209172584412291726444222617270443201162764441541628244508616
2405383121824653918217252540226172585412461726454224316270543217162765441721528254510215
2406383301824663919918252640243172586412631726464225916270643233162766441851628264511716
2407383481824673921718252740261182587412801626474227517270743249162767442011628274513315
2408383661624683923517252840278172588412961726484229216270843265162768442171528284514815
2409383841824693925218252940295172589413131626494230817270943281162769442321628294516316
2410384021824703927017253040312172590413301726504232516271043297162770442481628304517915
2411384201824713928718253140329172591413471626514234116271143313162771442641528314519415
2412384381824723930517253240346172592413631626524235716271243329162772442791528324520916
2413384561824733932218253340364182593413801726534237416271343345162773442951628334522515
2414384741824743934018253440381172594413971726544239216271443361162774443111528344524015
2415384921824753935817253540398172595414141626554240617271543377162775443261628354525516
2416385101824763937518253640415172596414301726564242316271643393162776443421628364527115
2417385281824773939317253740432172597414471726574243916271743409162777443581528374528615
2418385461824783941018253840449172598414641726584245517271843425162778443731628384530116
2419385641824793942817253940466172599414811626594247216271943441162779443891528394531715
2420385821724803944518254040483172600414971726604248816272043457162780444041628404533215
2421385991824813946317254140500182601415141726614250417272143473162781444201628414534715
2422386171824823948018254240518182602415311626624252117272243489162782444361528424536216
2423386351824833949817254340535172603415471726634253716272343505162783444511628434537815
2424386531824843951518254440552172604415641726644255316272443521162784444671628444539315
2425386711824853953317254540569172605415811626654257017272543537162785444831628454540815
2426386891824863955018254640586172606415971726664258616272643553162786444981528464542316
2427387071824873956817254740603172607416141726674260216272743569152787445141528474543915
2428387251824883958517254840620172608416311626684261917272843584162788445291628484545415
2429387431824893960218254940637172609416471626694263516272943600162789445451528494546915
2430387611724903962017255040654172610416641726704265116273043616162790445601628504548416
2431387781824913963718255140671172611416811626714266717273143632162791445761628514550016
2432387961824923965517255240688172612416971726724268416273243648162792445921528524551515
2433388141824933967218255340705172613417141726734270016273343664162793446071628534553015
2434388321824943969017255440722172614417311626744271616273443680162794446231528544554516
2435388501824953970717255540739172615417471726754273217273543696162795446381628554556115
2436388681824963972418255640756172616417641726764274916273643712152796446541528564557615
2437388861724973974217255740773172617417801626774276516273743727162797446691628574559115
2438389031824983975918255840790172618417971726784278117273843743162798446851528584560615
2439389211824993977717255940807172619418141626794279716273943759162799447001628594562116
2440389391825003979417256040824172620418301726804281317274043775162800447161528604563715
2441389571825013981118256140841172621418471726814283017274143791162801447311628614565215
2442389751825023982917256240858172622418631626824284616274243807162802447471628624566715
2443389931825033984617256340875172623418801726834286216274343823152803447621528634568215
2444390101825043986318256440892172624418961626844287816274443838162804447781628644569715
2445390281825053988117256540909172625419131726854289417274543854162805447931528654571216
2446390461825063989817256640926172626419291626864291116274643870162806448091628664572815
2447390631825073991518256740943172627419461726874292716274743886162807448241528674574315
2448390811825083993317256840960172628419631726884294316274843902152808448401528684575815
2449390991825093995017256940976172629419791626894295916274943917162809448551528694577315
2450391171725103996718257040993172630419961726904297516275043933162810448711528704578815
2451391341825113998517257141010172631420121726914299117275143949162811448861628714580315
2452391521825124000217257241027172632420291726924300817275243965162812449021628724581816
2453391701825134001918257341044172633420451626934302416275343981152813449171528734583415
2454391871725144003718257441061172634420621726944304016275443996162814449321628744584915
2455392051825154005417257541078172635420781726954305616275544012162815449481528754586415
24563922318251640071172576410951726364209516269643072162756440281628164496316
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
288045939294046835300047712306048572312049415318050243324051055330051851
288145954294146850300147727306148586312149429318150256324151068330151865
288245969294246864300247741306248601312249443318250270324251081330251878
288345984294346879300347756306348615312349457318350284324351095330351891
288446000294446894300447770306448629312449471318450297324451108330451904
288546015294546909300547784306548643312549485318550311324551121330551917
288646030294646923300647799306648657312649499318650325324651135330651930
288746045294746938300747813306748671312749513318750338324751148330751945
288846060294846953300847828306848686312849527318850352324851162330851957
288946075294946967300947842306948700312949541318950365324951175330951970
289046090295046982301047857307048714313049554319050379325051188331051983
289146105295146997301147871307148728313149568319150393325151202331151996
289246120295247012301247885307248742313249582319250406325251215331252009
289346135295347026301347900307348756313349596319350420325351228331352022
289446150295447041301447914307448770313449610319450433325451242331452035
289546165295547056301547929307548785313549624319550447325551255331552048
289646180295647070301647943307648799313649638319650461325651268331652061
289746195295747085301747958307748813313749651319750474325751282331752075
289846210295847100301847972307848827313849665319850488325851295331852088
289946225295947114301947986307948841313949679319950501325951308331952101
290046240296047129302048001308048855314049693320050515326051322332052114
290146255296147144302148015308148869314149707320150529326151335332152127
290246270296247159302248029308248883314249721320250542326251348332252140
290346285296347173302348044308348897314349734320350556326351362332352153
290446300296447188302448058308448911314449748320450569326451375332452166
290546315296547202302548073308548926314549762320550583326551388332552179
290646330296647217302648087308648940314649776320650596326651402332652192
290746345296747232302748101308748954314749790320750610326751415332752205
290846359296847246302848116308848968314849803320850623326851428332852218
290946374296947261302948130308948982314949817320950637326951441332952231
291046389297047276303048144309048996315049831321050651327051455333052244
291146404297147290303148159309149010315149845321150664327151468333152257
291246419297247305303248173309249024315249859321250678327251481333252270
291346434297347319303348187309349038315349872321350691327351495333352284
291446449297447334303448202309449052315449886321450705327451508333452297
291546464297547349303548216309549066315549900321550718327551521333552310
291646479297647363303648230309649080315649914321650732327651534333652323
291746494297747378303748244309749094315749927321750745327751548333752336
291846509297847392303848259309849108315849941321850759327851561333852349
291946523297947407303948273309949122315949955321950773327951574333952362
292046538298047422304048287310049136316049969322050786328051587334052375
292146553298147436304148302310149150316149982322150799328151601334152388
292246568298247451304248316310249164316249996322250813328251614334252401
292346583298347465304348330310349178316350010322350826328351627334352414
292446598298447480304448344310449192316450024322450840328451640334452427
292546613298547494304548359310549206316550037322550853328551654334552440
292646627298647509304648373310649220316650051322650866328651667334652453
292746642298747524304748387310749234316750065322750880328751680334752466
292846657298847538304848401310849248316850079322850893328851693334852479
292946672298947553304948416310949262316950092322950907328951706334952492
293046687299047567305048430311049276317050106323050920329051720335052504
293146702299147582305148444311149290317150120323150934329151733335152517
293246716299247596305248458311249304317250133323250947329251746335252530
293346731299347611305348473311349318317350147323350961329351759335352543
293446746299447625305448487311449332317450161323450974329451772335452556
293546761299547640305548501311549346317550174323550987329551786335552569
293646776299647654305648515311649360317650188323651001329651799335652582
293746790299747669305748530311749374317750202323751014329751812335752595
293846805299847683305848544311849388317850215323851028329851825335852608
293946820299947698305948558311949402317950229323951041329951838335952621
294046835300047712306048572312049415318050243324051055330051851336052634
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
3360526341334205340312348054158123540549001336005563012366056348123720570541237805774912
3361526471334215341513348154170133541549131236015564212366156360123721570661237815776111
3362526601334225342813348254183123542549251236025565412366256372123722570781137825777212
3363526731334235344112348354195133543549371236035566612366356384123723570891237835778411
3364526861334245345312348454208133544549491236045567812366456396113724571011237845779512
3365526991334255346613348554220133545549621336055569112366556407123725571131137855780711
3366527111334265347912348654233123546549741236065570312366656419123726571241237865781812
3367527241334275349113348754245133547549861236075571512366756431123727571361237875783011
3368527371334285350413348854258123548549981336085572712366856443123728571481137885784111
3369527501334295351712348954270133549550111236095573912366956455123729571591137895785211
3370527631334305352912349054283133550550231236105575112367056467113730571711237905786411
3371527761334315354213349154295123551550351236115576312367156478123731571831137915787512
3372527891334325355512349254307133552550471236125577512367256490123732571941237925788711
3373528021334335356713349354320123553550601236135578712367356502123733572061137935789812
3374528151334345358013349454332123554550721236145579912367456514123734572171237945791011
3375528271334355359312349554345133555550841236155581112367556526123735572291237955792112
3376528401334365360513349654357133556550961236165582312367656538113736572411137965793311
3377528531334375361813349754370123557551081336175583512367756549123737572521237975794411
3378528661334385363112349854382123558551211336185584712367856561123738572641237985795512
3379528791334395364313349954394123559551331236195585912367956573123739572761237995796711
3380528921334405365612350054407133560551451236205587112368056585123740572871138005797812
3381529051234415366813350154419133561551571236215588312368156597113741572991138015799011
3382529171334425368113350254432123562551691336225589512368256608123742573101238025800112
3383529301334435369412350354444123563551821236235590712368356620123743573221238035801311
3384529431334445370613350454456123564551941236245591912368456632123744573341138045802411
3385529561334455371913350554469123565552061236255593112368556644123745573451138055803512
3386529691334465373213350654481133566552181236265594312368656656113746573571238065804711
3387529821234475374413350754494123567552301236275595512368756667123747573681238075805812
3388529941334485375712350854506123568552421336285596712368856679123748573801238085807012
3389530071334495376913350954518123569552551236295597912368956691123749573921238095808111
3390530201334505378213351054531123570552671236305599112369056703113750574031138105809212
3391530331334515379413351154543123571552791236315600312369156714123751574151138115810411
3392530461234525380713351254555133572552911236325601512369256726123752574261238125811512
3393530581334535382012351354568123573553031236335602711369356738123753574381138135812711
3394530711334545383213351454580123574553151236345603812369456750113754574491138145813811
3395530841334555384513351554593123575553281336355605012369556761123755574611238155814911
3396530971334565385713351654605123576553401236365606212369656773123756574731138165816111
3397531101234575387012351754617133577553521236375607412369756785123757574841238175817212
3398531221334585388213351854630123578553641236385608612369856797113758574961138185818411
3399531351334595389513351954642123579553761236395609812369956808123759575071138195819511
3400531481334605390812352054654133580553881236405611012370056820123760575191238205820611
3401531611234615392013352154667123581554001336415612212370156832123761575301138215821811
3402531731334625393312352254679123582554131336425613412370256844113762575421138225822911
3403531861334635394513352354691133583554251336435614612370356855123763575531238235824012
3404531991334645395813352454704123584554371236445615812370456867123764575631238245825212
3405532121234655397013352554716123585554491236455617012370556879123765575761138255826311
3406532241334665398312352654728133586554611236465618212370656891113766575881238265827412
3407532371334675399513352754741123587554731236475619411370756902123767576001138275828611
3408532501334685400812352854753133588554851236485620512370856914123768576111238285829712
3409532631334695402013352954765123589554971236495621712370956926123769576231238295830912
3410532751334705403313353054777133590555091336505622912371056937123770576341138305832011
3411532881334715404513353154790123591555221236515624112371156949123771576461138315833111
3412533011334725405812353254802123592555341236525625312371256961113772576571238325834312
3413533141234735407013353354814133593555461236535626512371356972123773576691138335835411
3414533261334745408312353454827133594555581236545627712371456984123774576801138345836511
3415533391334755409513353554839123595555701236555628912371556996123775576921238355837711
3416533521234765410813353654851133596555821236565630111371657008113776
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
384058433390059106396059770402060423408061066414061702420062325426062941
384158444390159118396159780402160433408161077414161711420162335426162951
384258456390259129396259791402260444408261087414261721420262346426262961
384358467390359140396359802402360455408361098414361731420362356426362972
384458478390459151396459813402460466408461109414461742420462366426462982
384558490390559162396559824402560477408561119414561752420562377426562992
384658501390659173396659835402660487408661130414661763420662387426663002
384758512390759184396759846402760498408761140414761773420762397426763012
384858524390859195396859857402860509408861151414861784420862408426863022
384958535390959207396959868402960520408961162414961794420962418426963033
385058546391059218397059879403060531409061172415061805421062428427063043
385158557391159229397159890403160541409161183415161815421162439427163053
385258569391259240397259901403260552409261194415261826421262449427263063
385358580391359251397359912403360563409361204415361836421362459427363073
385458591391459262397459923403460574409461215415461847421462469427463083
385558602391559273397559934403560585409561225415561857421562478427563094
385658613391659284397659945403660595409661236415661868421662489427663104
385758625391759295397759956403760606409761247415761878421762500427763114
385858636391859306397859966403860617409861257415861888421862511427863124
385958647391959318397959977403960627409961268415961899421962521427963134
386058659392059329398059988404060638410061278416061909422062531428063144
386158670392159340398159999404160649410161289416161920422162542428163155
386258681392259351398260010404260660410261300416261930422262552428263165
386358692392359362398360021404360670410361310416361941422362562428363175
386458704392459373398460032404460681410461321416461951422462572428463185
386558715392559384398560043404560692410561331416561962422562583428563195
386658726392659395398660054404660703410661342416661972422662593428663205
386758737392759406398760065404760713410761352416761982422762603428763215
386858749392859417398860076404860724410861363416861993422862613428863225
386958760392959428398960086404960735410961374416962003422962624428963235
387058771393059439399060097405060746411061384417062014423062634429063246
387158782393159450399160108405160756411161395417162024423162644429163256
387258794393259461399260119405260767411261405417262034423262655429263266
387358805393359472399360130405360778411361416417362045423362665429363276
387458816393459483399460141405460788411461426417462055423462675429463286
387558827393559494399560152405560799411561437417562066423562685429563296
387658838393659506399660163405660810411661448417662076423662696429663306
387758850393759517399760173405760821411761458417762086423762706429763317
387858861393859528399860184405860831411861469417862097423862716429863327
387958872393959539399960195405960842411961479417962107423962726429963337
388058883394059550400060206406060853412061490418062118424062737430063347
388158894394159561400160217406160863412161500418162128424162747430163357
388258906394259572400260228406260874412261511418262138424262757430263367
388358917394359583400360239406360885412361521418362149424362767430363377
388458928394459594400460249406460895412461532418462159424462777430463387
388558939394559605400560260406560906412561542418562170424562788430563397
388658950394659616400660271406660917412661553418662180424662798430663407
388758961394759627400760282406760927412761563418762190424762808430763417
388858973394859638400860293406860938412861574418862201424862818430863428
388958984394959649400960304406960949412961584418962211424962829430963438
389058995395059660401060314407060959413061595419062221425062839431063448
389159006395159671401160325407160970413161606419162232425162849431163458
389259017395259682401260336407260981413261616419262242425262859431263468
389359028395359693401360347407360991413361627419362252425362870431363478
389459040395459704401460358407461002413461637419462263425462880431463488
389559051395559715401560369407561013413561648419562273425562890431563498
389659062395659726401660379407661023413661658419662284425662900431663508
389759073395759737401760390407761034413761669419762294425762910431763518
389859084395859748401860401407861045413861679419862304425862921431863528
389959095395959759401960412407961055413961690419962315425962931431963538
390059106396059970402060423408061066414061700420062325426062941432063548
LOGARITHMS OF NUMBERS.
<
N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.
4320635481043806414710444064738104500653211045606590610462066494104680670259474067578948006812494860686719
4321635581043816415710444164748104501653311045616590610462166474104681670349474167587948016813494861686819
43226356811438264167104442647581045026534110456265916946226648394682670439474267596948026814394862686919
4323635791043836417710444364768104503653509456365925104623664921046836705210474367605948036815294863687029
432463589104384641871044446477710450465360945646593594624665029468467062947446761410480468162948646871110
4325635991043856419710444564787104505653691045656594410462566511104685670711047456762494805681711048656872010
43266360910438664207104446647971045066537910456665954946266652194686670809474667633948066818094866687299
4327636191043876421710444764807945076538994567659639462766530946876708910474767642948076819094867687389
4328636291043886422710444864816104508653981045686597394628665391046886709910474867651948086820094868687479
43296363910438964237944496482610450965408104569659821046296654994689671089474967660948096821094869687569
4330636491043906424610445064836104510654189457065992946306655894690671171047506766910481068220948706876510
433163659104391642561044516484610451165427104571660011046316656710469167127104751676791048116823094871687749
43326366910439264266104452648561045126543710457266011104632665771046926713610475267688948126824094872687839
4333636791043936427610445364865104513654479457366020104633665861046936714510475367697948136825094873687929
433463689104394642861044546487510451465456104574660309463466596946946715410475467706948146826094874688019
43356369910439564296104455648851045156546610457566039946356660594695671649475567715948156827094875688119
433663709104396643061044566489594516654751045766604994636666141046966717310475667724948166828094876688209
43376371910439764316104457649041045176548510457766058946376662494697671829475767733948176829094877688309
43386372910439864326944586491410451865495945786606810463866633946986719194758677421048186830094878688409
43396373910439964335104459649249451965504945796607710463966642104699672019475967752948196831094879688509
434063749104400643451044606493310452065514945806608710464066652104700672109476067761948206832094880688609
4341637591044016435510446164943104521655231045816609610464166661104701672199476167770948216833094881688709
4342637691044026436510446264953104522655331045826610610464266671104702672289476267779948226834094882688809
434363779104403643751044636496394523655439458366115946436668094703672379476367788948236835094883688909
4344637891044046438510446464972104524655521045846612410464466689104704672479476467797948246836094884689009
434563799104405643959446564982104525655629458566134946456669994705672569476567806948256837094885689109
4346638091044066440410446664992104526655711045866614310464666708947066726594766678151048266838094886689209
434763819104407644141044676500210452765581104587661531046476671710470767274104767678251048276839094887689309
4348638291044086442410446865011104528655911045886616294648667271047086728410476867834948286840094888689409
43496383910440964434104469650211045296560010458966172946496673694709672939476967843948296841094889689509
43506384910441064444104470650319453065610945906618110465066745104710673029477067852948306842094890689609
4351638591044116445410447165040104531656191045916619110465166755947116731110477167861948316843094891689709
4352638691044126446494472650501045326562910459266200104652667641047126732110477267870948326844094892689809
43536387910441364473104473650601045336563910459366210104653667731047136733010477367879948336845094893689909
4354638891044146448310447465070945346564810459466219104654667831047146733910477467888948346846094894690009
43556389910441564493104475650791045356565894595662291046556679294715673489477567897948356847094895690109
435663909104416645031044766508910453665667104596662381046566680110471667357104776679061048366848094896690209
43576391910441764513104477650991045376567794597662471046576681110471767367104777679161048376849094897690309
4358639291044186452394478651081045386568610459866257104658668201047186737610477867925948386850094898690409
43596393910441964532104479651181045396569610459966266104659668291047196738510477967934948396851094899690509
4360639491044206454210448065128104540657069460066276946606683994720673949478067943948406852094900690609
43616395910442164552104481651371045416571510460166285104661668481047216740310478167952948416853094901690709
43626396910442264562104482651471045426572510460266295104662668571047226741310478267961948426854094902690809
4363639799442364572104483651571045436573410460366304104663668671047236742210478367970948436855094903690909
43646398810442464582944846516710454465744946046631410466466876947246743110478467979948446856094904691009
436563998104425645911044856517610454565753104605663231046656688594725674409478567988948456857094905691109
43666400810442664601104486651861045466576310460666332
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
48056812494860686649492069197849806972395040702439510070757951607126585220717678
48016813394861686739492169205949816973295041702529510170766951617127395221717758
48026814294862686819492269214949826974095042702609510270774951627128295222717848
48036815194863686909492369223949836974995043702699510370783951637129095223717928
48046816094864686999492469232949846975895044702789510470791951647129995224718008
48056816994865687089492569241949856976795045702869510570790951657130795225718098
48066817894866687179492669249949866977595046702959510670808951667131595226718178
48076818794867687269492769258949876978495047703039510770817951677132495227718258
48086819694868687359492869267949886979395048703129510870825951687133295228718348
48096820594869687449492969276949896980195049703219510970834951697134195229718428
48106821594870687539493069285949906981095050703299511070842951707134995230718508
48116822494871687629493169294949916981995051703389511170851951717135795231718588
48126823394872687719493269302949926982795052703469511270859951727136695232718678
48136824294873687809493369311949936983695053703559511370868951737137495233718758
48146825194874687899493469320949946984595054703649511470876951747138395234718838
48156826094875687979493569329949956985495055703729511570885951757139195235718928
48166826994876688069493669338949966986295056703819511670893951767139995236719008
48176827894877688159493769346949976987195057703899511770902951777140895237719088
48186828794878688249493869355949986988095058703989511870910951787141695238719178
48196829694879688339493969364949996988895059704069511970919951797142595239719258
48206830594880688429494069373950006989795060704159512070927951807143395240719338
48216831494881688519494169381950016990695061704249512170935951817144195241719418
48226832394882688609494269390950026991495062704329512270944951827145095242719508
48236833294883688699494369399950036992395063704419512370952951837145895243719588
48246834194884688789494469408950046993295064704499512470961951847146695244719668
48256835094885688869494569417950056994095065704589512570969951857147395245719738
48266835994886688959494669425950066994995066704679512670978951867148395246719838
48276836894887689049494769434950076995895067704759512770986951877149295247719918
48286837794888689139494869443950086996695068704849512870995951887150095248719998
48296838694889689229494969452950096997595069704929512971003951897150895249720088
48306839594890689319495069461950106998495070705019513071012951907151795250720168
48316840494891689409495169469950116999295071705099513171020951917152595251720248
48326841394892689499495269478950127000195072705189513271029951927153395252720328
48336842294893689589495369487950137001095073705269513371037951937154295253720418
48346843194894689669495469496950147001895074705359513471046951947155095254720498
48356844094895689759495569504950157002795075705449513571055951957155995255720578
48366844994896689849495669513950167003695076705529513671063951967156795256720668
48376845894897689939495769522950177004495077705619513771071951977157595257720748
48386846794898690029495869531950187005395078705699513871079951987158495258720828
48396847694899690119495969539950197006295079705789513971088951997159295259720908
48406848594900690209496069548950207007095080705869514071096952007160095260720998
48416849494901690289496169557950217007995081705959514171105952017160995261721078
48426850294902690379496269566950227008895082706039514271113952027161795262721158
48436851194903690469496369574950237009695083706129514371122952037162595263721238
48446852094904690559496469583950247010595084706219514471130952047163495264721328
48456852994905690649496569592950257011495085706299514571139952057164295265721408
48466853894906690739496669601950267012295086706389514671147952067165095266721488
48476854794907690829496769609950277013195087706469514771155952077165995267721568
48486855694908690909496869618950287014095088706559514871164952087166795268721658
48496856594909691009496969627950297014895089706639514971172952097167595269721738
48506857494910691089497069636950307015795090706729515071181952107168495270721818
48516858394911691179497169644950317016595091706809515171189952117169295271721898
48526859294912691269497269653950327017495092706899515271198952127170095272721988
48536860194913691359497369662950337018395093706979515371206952137170995273722068
48546861094914691449497469671950347019195094707069515471214952147171795274722148
48556861994915691529497569679950357020095095707149515571223952157172595275722228
48566862894916691619497669688950367020995096707239515671231952167173495276722308
48576863794917691709497769697950377021795097707319515771240952177174295277722398
48586864694918691799497869705950387022695098707409515871248952187175095278722478
485968655
LOGARITHMS OF NUMBERS.
N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.
52807226385340727548540073239854607371985520741948558074663856407512885700755878
52817227285341727628540173247854617372785521742028558174671856417513685701755958
52827228085342727708540273255854627373585522742108558274679856427514385702756038
52837228885343727798540373263854637374385523742188558374687856437515185703756108
52847229685344727878540473272854647375185524742258558474695856447515985704756188
52857230485345727958540573280854657375985525742338558574702856457516685705756268
52867231385346728038540673288854667376785526742418558674710856467517485706756338
52877232185347728118540773296854677377585527742498558774718856477518285707756418
52887232985348728198540873304854687378385528742578558874726856487518985708756488
52897233785349728278540973312854697379185529742658558974733856497519785709756568
52907234685350728358541073320854707379985530742738559074741856507520585710756648
52917235485351728438541173328854717380785531742808559174749856517521385711756718
52927236285352728528541273336854727381585532742888559274757856527522085712756798
52937237085353728608541373344854737382385533742968559374764856537522885713756868
52947237885354728688541473352854747383085534743048559474772856547523685714756948
52957238785355728768541573360854757383885535743128559574780856557524385715757028
52967239585356728848541673368854767384685536743208559674788856567525185716757098
52977240385357728928541773376854777385485537743278559774796856577525985717757178
52987241185358729008541873384854787386285538743358559874803856587526685718757248
52997241985359729088541973392854797387085539743438559974811856597527485719757328
53007242885360729168542073400854807387885540743518560074819856607528285720757408
53017243685361729258542173408854817388685541743598560174827856617528985721757478
53027244485362729338542273416854827389485542743678560274834856627529785722757558
53037245285363729418542373424854837390285543743748560374842856637530585723757628
53047246085364729498542473432854847391085544743828560474850856647531285724757708
53057246985365729578542573440854857391885545743908560574858856657532085725757788
53067247785366729658542673448854867392685546743988560674865856667532885726757858
53077248585367729738542773456854877393385547744068560774873856677533585727757938
53087249385368729818542873464854887394185548744148560874881856687534385728758008
53097250185369729898542973472854897394985549744218560974889856697535185729758088
53107250985370729978543073480854907395785550744298561074896856707535885730758158
53117251885371730068543173488854917396585551744378561174904856717536685731758238
53127252685372730148543273496854927397385552744458561274912856727537485732758318
53137253485373730228543373504854937398185553744538561374920856737538185733758388
53147254285374730308543473512854947398985554744618561474927856747538985734758468
53157255085375730388543573520854957399785555744688561574935856757539785735758538
53167255885376730468543673528854967400585556744768561674943856767540485736758618
53177256785377730548543773536854977401385557744848561774950856777541285737758688
53187257585378730628543873544854987402085558744928561874958856787542085738758768
53197258385379730708543973552854997402885559745008561974966856797542785739758848
53207259185380730788544073560855007403685560745078562074974856807543585740758918
53217259985381730868544173568855017404485561745158562174981856817544285741758998
53227260785382730948544273576855027405285562745238562274989856827545085742759068
53237261685383731028544373584855037406085563745318562374997856837545885743759148
53247262485384731108544473592855047406885564745398562475005856847546585744759218
53257263285385731198544573600855057407685565745478562575012856857547385745759298
53267264085386731278544673608855067408485566745548562675020856867548185746759378
53277264885387731358544773616855077409285567745628562775028856877548885747759448
53287265685388731438544873624855087409985568745708562875035856887549685748759528
53297266585389731518544973632855097410785569745788562975043856897550485749759598
53307267385390731598545073640855107411585570745868563075051856907551185750759678
53317268185391731678545173648855117412385571745938563175059856917551985751759748
53327268985392731758545273656855127413185572746018563275066856927552685752759828
53337269785393731838545373664855137413985573746098563375074856937553485753759898
53347270585394731918545473672855147414785574746178563475082856947554285754759978
53357271385395731998545573679855157415585575746248563575089856957554985755760058
53367272285396732078545673687855167416285576746328563675097856967555785756760128
53377273085397732158545773695855177417085577746408563775105856977556585757760208
53387273885398732238545873703855187417885578746488563875113856987557285758760278
5339
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
57607604285820764928588076938759407737976000778157606078247761207867576180790997
57617605075821765007588176945759417738676001778227606178254761217868276181791067
57627605775822765077588276953759427739376002778307606278262761227868976182791137
57637606575823765157588376960759437740176003778377606378269761237869676183791207
57647607275824765227588476967759447740876004778447606478276761247870476184791277
57657608075825765307588576975759457741576005778517606578283761257871176185791347
57667608775826765377588676982759467742276006778597606678290761267871876186791417
57677609575827765457588776989759477743076007778667606778297761277872576187791487
57687610375828765527588876997759487743776008778737606878305761287873276188791557
57697611075829765597588977004759497744476009778807606978312761297873976189791627
57707611875830765677589077012759507745276010778877607078319761307874676190791697
57717612575831765747589177019759517745976011778957607178326761317875376191791767
57727613375832765827589277026759527746676012779027607278333761327876076192791837
57737614075833765897589377034759537747476013779097607378340761337876776193791907
57747614875834765977589477041759547748176014779167607478347761347877476194791977
57757615575835766047589577048759557748876015779247607578355761357878176195792047
57767616375836766127589677056759567749576016779317607678362761367878976196792117
57777617075837766197589777063759577750376017779387607778369761377879676197792187
57787617875838766267589877070759587751076018779457607878376761387880376198792257
57797618575839766347589977078759597751776019779527607978383761397881076199792327
57807619375840766417590077085759607752576020779607608078390761407881776200792397
57817620075841766497590177093759617753276021779677608178398761417882476201792467
57827620875842766567590277100759627753976022779747608278405761427883176202792537
57837621575843766647590377107759637754676023779817608378412761437883876203792607
57847622375844766717590477115759647755476024779887608478419761447884576204792677
57857623075845766787590577122759657756176025779967608578426761457885276205792747
57867623875846766867590677129759667756876026780037608678433761467885976206792817
57877624575847766937590777137759677757676027780107608778440761477886676207792887
57887625375848767017590877144759687758376028780177608878447761487887376208792957
57897626075849767087590977151759697759076029780257608978455761497888076209793027
57907626875850767167591077159759707759776030780327609078462761507888876210793097
57917627575851767237591177166759717760576031780397609178469761517889576211793167
57927628375852767307591277173759727761276032780467609278476761527890276212793237
57937629075853767387591377181759737761976033780537609378483761537890976213793307
57947629875854767457591477188759747762776034780617609478490761547891676214793377
57957630575855767537591577195759757763476035780687609578497761557892376215793447
57967631375856767607591677203759767764176036780757609678504761567893076216793517
57977632075857767687591777210759777764876037780827609778512761577893776217793587
57987632875858767757591877217759787765676038780897609878519761587894476218793657
57997633575859767827591977225759797766376039780977609978526761597895176219793727
58007634375860767907592077232759807767076040781047610078533761607895876220793797
58017635075861767977592177240759817767776041781117610178540761617896576221793867
58027635875862768057592277247759827768576042781187610278547761627897276222793937
58037636575863768127592377254759837769276043781257610378554761637897976223794007
58047637375864768197592477262759847769976044781327610478561761647898676224794077
58057638075865768277592577269759857770676045781407610578568761657899376225794147
58067638875866768347592677276759867771476046781477610678576761667900076226794217
58077639575867768427592777283759877772176047781547610778583761677900776227794287
58087640375868768497592877291759887772876048781617610878590761687901476228794357
58097641075869768567592977298759897773576049781687610978597761697902176229794427
58107641875870768647593077305759907774376050781767611078604761707902976230794497
58117642575871768717593177313759917775076051781837611178611761717903676231794567
58127643375872768797593277320759927775776052781907611278618761727904376232794637
58137644075873768867593377327759937776476053781977611378625761737905076233794707
58147644875874768937593477335759947777276054782047611478633761747905776234794777
58157645575875769017593577342759957777976055782117611578640761757906476235794847
58167646275876769087593677349759967778676056782197611678647761767907176236794917
58177647075877769167593777357759977779376057782267611778654761777907876237794987
58187647775878769237593877364759987780176058782337611878661761787908576238795057
581976485
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
62407951876300799347636080346764208075476480811587654081558766008195476660823477
62417952576301799417636180353764218076076481811647654181564766018196176661823547
62427953276302799487636280359764228076776482811717654281571766028196876662823607
62437953976303799557636380366764238077476483811787654381578766038197476663823677
62447954676304799627636480373764248078176484811847654481584766048198176664823737
62457955376305799697636580380764258078776485811917654581591766058198776665823807
62467956076306799757636680387764268079476486811987654681598766068199476666823877
62477956776307799827636780393764278080176487812047654781604766078200176667823937
62487957476308799897636880400764288080876488812117654881611766088200776668824007
62497958176309799967636980407764298081476489812187654981617766098201476669824067
62507958876310800037637080414764308082176490812247655081624766108202076670824137
62517959576311800107637180421764318082876491812317655181631766118202776671824197
62527960276312800177637280428764328083576492812387655281637766128203376672824267
62537960976313800247637380434764338084176493812457655381644766138204076673824327
62547961676314800307637480441764348084876494812517655481651766148204676674824397
62557962376315800377637580448764358085576495812587655581657766158205376675824457
62567963076316800447637680455764368086276496812657655681664766168206076676824527
62577963776317800517637780462764378086876497812717655781671766178206676677824587
62587964476318800587637880468764388087576498812787655881677766188207376678824657
62597965076319800657637980475764398088276499812857655981684766198207976679824717
62607965776320800727638080482764408088976500812917656081690766208208676680824787
62617966476321800797638180489764418089576501812987656181697766218209276681824847
62627967176322800857638280496764428090276502813057656281704766228209976682824917
62637967876323800927638380502764438090976503813117656381710766238210576683824977
62647968576324800997638480509764448091676504813187656481717766248211276684825047
62657969276325801067638580516764458092276505813257656581723766258211976685825107
62667969976326801137638680523764468092976506813317656681730766268212576686825177
62677970676327801207638780530764478093676507813387656781737766278213276687825237
62687971376328801277638880536764488094376508813457656881743766288213876688825307
62697972076329801347638980543764498094976509813517656981750766298214576689825367
62707972776330801407639080550764508095676510813587657081757766308215176690825437
62717973476331801477639180557764518096376511813657657181763766318215876691825497
62727974176332801547639280564764528096976512813717657281770766328216476692825567
62737974876333801617639380570764538097676513813787657381776766338217176693825627
62747975476334801687639480577764548098376514813857657481783766348217876694825697
62757976176335801757639580584764558099076515813927657581790766358218476695825757
62767976876336801827639680591764568099676516813987657681796766368219176696825827
62777977576337801887639780598764578100376517814057657781803766378219776697825887
62787978276338801957639880604764588101076518814117657881809766388220476698825957
62797978976339802027639980611764598101776519814187657981816766398221076699826017
62807979676340802097640080618764608102376520814257658081823766408221776700826077
62817980376341802167640180625764618103076521814317658181829766418222376701826147
62827981076342802237640280632764628103776522814387658281836766428223076702826207
62837981776343802297640380638764638104376523814457658381842766438223676703826277
62847982476344802367640480645764648105076524814517658481849766448224376704826337
62857983176345802437640580652764658105776525814587658581856766458224976705826407
62867983776346802507640680659764668106476526814657658681862766468225676706826467
62877984476347802577640780665764678107076527814717658781869766478226376707826537
62887985176348802647640880672764688107776528814787658881875766488226976708826597
62897985876349802717640980679764698108476529814857658981882766498227676709826667
62907986576350802777641080686764708109076530814917659081889766508228276710826727
62917987276351802847641180693764718109776531814987659181895766518228976711826797
62927987976352802917641280699764728110476532815057659281902766528229576712826857
62937988676353802987641380706764738111176533815117659381908766538230276713826927
62947989376354803057641480713764748111776534815187659481915766548230876714826987
62957990076355803127641580720764758112476535815257659581921766558231576715827057
62967990676356803187641680726764768113176536815317659681928766568232176716827117
62977991376357803257641780733764778113776537815387659781935766578232876717827187
62987992076358803327641880740764788114476538815447659881941766588233476718827247
629979927
LOGARITHMS OF NUMBERS.
N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.
672082737667808312366840835066690083885669608426167020846346708085003671408537067200857376
672182743767818312976841835127690183891769618426777021846407708185009771418537677201857437
672282750667828313666842835186690283897669628427367022846466708285016671428538267202857496
672382756767838314276843835257690383904769638428077023846527708385022771438538877203857557
672482763667848314966844835316690483910669648428667024846586708485028671448539467204857616
672582769767858315576845835377690583916769658429277025846657708585034771458540077205857677
672682776667868316166846835446690683923669668429867026846716708685040671468540667206857736
672782782767878316876847835507690783929769678430577027846777708785046771478541277207857797
672882789667888317466848835566690883935669688431167028846836708885052671488541867208857856
672982795767898318176849835637690983942769698431777029846897708985058771498542577209857917
673082802667908318766850835696691083948669708432367030846966709085065671508543167210857986
673182808767918319376851835757691183954769718433077031847027709185071771518543777211858047
673282814667928320066852835826691283962669728433667032847086709285077671528544367212858106
673382821767938320676853835887691383967769738434277033847147709385083771538544977213858167
673482827667948321366854835946691483973669748434867034847206709485089671548545567214858226
673582834767958321976855836017691583979769758435477035847267709585095771558546177215858287
673682840667968322566856836076691683985669768436167036847336709685101671568546767216858346
673782847767978323276857836137691783992769778436777037847397709785107771578547377217858407
673882853667988323866858836206691883998669788437367038847456709885114671588547967218858466
673982860767998324576859836267691984004769798437977039847517709985120771598548577219858527
674082866668008325166860836326692084011669808438667040847576710085126671608549167220858586
674182872768018325776861836397692184017769818439277041847637710185132771618549777221858647
674282879668028326466862836456692284023669828439867042847706710285138671628550367222858706
674382885768038327076863836517692384029769838440477043847767710385144771638550977223858767
674482892668048327666864836586692484036669848441067044847826710485150671648551667224858826
674582898768058328376865836647692584042769858441777045847887710585156771658552277225858887
674682905668068328966866836706692684048669868442367046847946710685163671668552867226858946
674782911768078329676867836777692784055769878442977047848007710785169771678553477227859007
674882918668088330266868836836692884061669888443567048848076710885175671688554067228859066
674982924768098330876869836897692984067769898444277049848137710985181771698554677229859127
675082930668108331566870836966693084073669908444867050848196711085187671708555267230859186
675182937768118332176871837027693184080769918445477051848257711185193771718555877231859247
675282943668128332766872837086693284086669928446067052848316711285199671728556467232859306
675382950768138333476873837157693384092769938446677053848377711385205771738557077233859367
675482956668148334066874837216693484098669948447367054848446711485211671748557667234859426
675582963768158334776875837277693584105769958447977055848507711585217771758558277235859487
675682969668168335366876837346693684111669968448567056848566711685224671768558867236859546
675782975768178335976877837407693784117769978449177057848627711785230771778559477237859607
675882982668188336666878837466693884123669988449767058848686711885236671788560067238859666
675982988768198337276879837537693984130769998450477059848747711985242771798560677239859727
676082995668208337866880837596694084136670008451067060848806712085248671808561267240859786
676183001768218338576881837657694184142770018451677061848877712185254771818561877241859847
676283008668228339166882837716694284148670028452267062848936712285260671828562567242859906
676383014768238339876883837787694384155770038452877063848997712385266771838563177243859967
676483020668248340466884837846694484161670048453567064849056712485272671848563767244859996
676583027768258341076885837907694584167770058454177065849117712585278771858564377245860057
676683033668268341766886837976694684173670068454767066849176712685285671868564967246860116
676783040768278342376887838037694784180770078455377067849247712785291771878565577247860177
676883046668288342966888838096694884186670088455967068849306712885297671888566167248860236
676983052768298343676889838167694984192770098456677069849367712985303771898566777249860297
677083059668308344266890838226695084198670108457267070849426713085309671908567367250860356
677183065768318344876891838287695184205770118457877071849487713185315771918567977251860417
67728307266832834556689283835669528421167012845846707284954671328
LOGARITHMS OF NUMBERS.
N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D.
72008573367262860946732086451673808680667440871576750087506675608785267620881936
72018573967261861006732186457673818681267441871636750187512675618785867621882016
72028574567262861066732286463673828681767442871696750287518675628786467622882076
72038575167263861126732386469673838682367443871756750387523675638786967623882136
72048575767264861186732486475673848682967444871816750487529675648787567624882186
72058576367265861246732586481673858683567445871866750587535675658788167625882246
72068576967266861306732686487673868684167446871926750687541675668788767626882306
72078577567267861366732786493673878684767447871986750787547675678789267627882356
72088578167268861416732886499673888685367448872046750887552675688789867628882416
72098578877269861476732986504673898685967449872106750987558675698790467629882476
72108579467270861536733086510673908686467450872166751087564675708791067630882526
72118580067271861596733186516673918687067451872216751187570675718791567631882586
72128580667272861656733286522673928687667452872276751287576675728792167632882646
72138581267273861716733386528673938688267453872336751387581675738792767633882706
72148581867274861776733486534673948688867454872396751487587675748793367634882756
72158582467275861836733586540673958689467455872456751587593675758793867635882816
72168583067276861896733686546673968690067456872516751687599675768794467636882876
72178583667277861956733786552673978690667457872566751787604675778795067637882926
72188584267278862016733886558673988691167458872626751887610675788795567638882986
72198584867279862076733986564673998691767459872686751987616675798796167639883046
72208585467280862136734086570674008692367460872746752087622675808796767640883096
72218586067281862196734186576674018692967461872806752187628675818797367641883156
72228586667282862256734286581674028693567462872866752287633675828797867642883216
72238587267283862316734386587674038694167463872916752387639675838798467643883266
72248587867284862376734486593674048694767464872976752487645675848799067644883326
72258588467285862436734586599674058695367465873036752587651675858799667645883386
72268589067286862496734686605674068695867466873096752687656675868800167646883436
72278589667287862556734786611674078696467467873156752787662675878800767647883496
72288590267288862616734886617674088697067468873206752887668675888801367648883556
72298590867289862676734986623674098697667469873266752987674675898801867649883606
72308591467290862736735086629674108698267470873326753087679675908802467650883666
72318592067291862796735186635674118698867471873386753187685675918803067651883726
72328592667292862856735286641674128699467472873446753287691675928803667652883776
72338593267293862916735386646674138699967473873496753387697675938804167653883836
72348593867294862976735486652674148700567474873556753487703675948804767654883896
72358594467295863036735586658674158701167475873616753587708675958805367655883956
72368595067296863086735686664674168701767476873676753687714675968805867656884006
72378595667297863146735786670674178702367477873736753787720675978806467657884066
72388596267298863206735886676674188702967478873796753887726675988807067658884126
72398596867299863266735986682674198703567479873846753987731675998807667659884176
72408597467300863326736086688674208704067480873906754087737676008808167660884236
72418598067301863386736186694674218704667481873966754187743676018808767661884296
72428598667302863446736286700674228705267482874026754287749676028809367662884346
72438599267303863506736386705674238705867483874086754387754676038809867663884406
72448599867304863566736486711674248706467484874136754487760676048810467664884466
72458600467305863626736586717674258707067485874196754587766676058811067665884516
72468601067306863686736686723674268707567486874256754687772676068811667666884576
72478601667307863746736786729674278708167487874316754787777676078812167667884636
72488602267308863806736886735674288708767488874376754887783676088812767668884686
72498602867309863866736986741674298709367489874426754987789676098813367669884746
72508603467310863926737086747674308709967490874486755087795676108813867670884806
72518604067311863986737186753674318710567491874546755187800676118814467671884856
72528604667312864046737286759674328711167492874606755287806676128815067672884916
72538605267313864106737386764674338711667493874666755387812676138815667673884976
72548605867314864156737486770674348712267494874716755487818676148816167674885026
72558606467315864216737586776674358712867495874776755587823676158816767675885086
72568607067316864276737686782674368713467496874836755687829676168817367676885136
72578607667317864336737786788674378714067497874896755787835676178817867677885196
72588608267318864396737886794674388714667498874956755887841676188818467678885256
72598608867319
N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.N.Log.D.
76808853667740888746780089209678608954267920898735798090200680409052658100908495
76818854257741888805780189215578618954857921898785798190206580419053158101908545
76828854757742888855780289221578628955357922898835798290211580429053658102908595
76838855357743888915780389226578638955957923898895798390217580439054258103908655
76848855957744888975780489232578648956457924898945798490222580449054758104908705
76858856457745889025780589237578658957057925899005798590227580459055358105908755
76868857057746889085780689243578668957557926899055798690233580469055858106908815
76878857657747889135780789248578678958157927899115798790238580479056358107908865
76888858157748889195780889254578688958657928899165798890244580489056958108908915
76898858757749889255780989260578698959257929899225798990249580499057458109908975
76908859357750889305781089265578708959757930899275799090255580509058058110909025
76918859857751889365781189271578718960357931899335799190260580519058558111909075
76928860457752889415781289276578728960957932899385799290266580529059058112909135
76938861057753889475781389282578738961457933899445799390271580539059658113909185
76948861557754889535781489287578748962057934899495799490276580549060158114909245
76958862157755889585781589293578758962557935899555799590282580559060758115909295
76968862757756889645781689298578768963157936899605799690287580569061258116909345
76978863257757889695781789304578778963657937899665799790293580579061758117909405
76988863857758889755781889310578788964257938899715799890298580589062358118909455
76998864357759889815781989315578798964757939899775799990304580599062858119909505
77008864957760889865782089321578808965357940899825800090309580609063458120909565
77018865557761889925782189326578818965857941899885800190314580619063958121909615
77028866057762889975782289332578828966457942899935800290320580629064458122909665
77038866657763890035782389337578838966957943899985800390325580639065058123909725
77048867257764890095782489343578848967557944900045800490331580649065558124909775
77058867757765890145782589348578858968257945900095800590336580659066058125909825
77068868357766890205782689354578868968657946900155800690342580669066658126909885
77078868957767890255782789360578878969157947900205800790347580679067158127909935
77088869457768890315782889365578888969757948900265800890352580689067758128909985
77098870057769890375782989371578898970257949900315800990358580699068258129910045
77108870557770890425783089376578908969857950900375801090363580709068758130910095
77118871157771890485783189382578918971357951900425801190369580719069358131910145
77128871757772890535783289387578928971957952900485801290374580729069858132910205
77138872257773890595783389393578938972457953900535801390380580739070358133910255
77148872857774890645783489398578948973057954900595801490385580749070958134910305
77158873457775890705783589404578958973557955900645801590390580759071458135910365
77168873957776890765783689409578968974157956900695801690396580769072058136910415
77178874557777890815783789415578978974657957900755801790401580779072558137910465
77188875057778890875783889421578988975257958900805801890407580789073058138910525
77198875657779890925783989426578998975757959900865801990412580799073658139910575
77208876257780890985784089432579008976357960900915802090417580809074158140910625
77218876757781891045784189437579018976857961900975802190423580819074758141910685
77228877357782891095784289443579028977457962901025802290428580829075258142910735
77238877957783891155784389448579038977957963901085802390434580839075758143910785
77248878457784891205784489454579048978557964901135802490439580849076358144910845
77258879057785891265784589459579058979057965901195802590445580859076858145910895
77268879557786891315784689465579068979657966901245802690450580869077358146910945
77278880157787891375784789470579078980157967901295802790455580879077958147911005
77288880757788891435784889476579088980757968901355802890461580889078458148911055
77298881257789891485784989481579098981257969901405802990466580899078958149911105
77308881857790891545785089487579108981857970901465803090472580909079558150911165
77318882457791891595785189492579118982357971901515803190477580919080058151911215
77328882957792891655785289498579128982957972901575803290482580929080658152911265
77338883557793891705785389504579138983457973901625803390488580939081158153911325
77348884057794891765785489509579148984057974901685803490493580949081658154911375
77358884657795891825785589515579158984557975901735803590499580959082258155911425
77368885257796891875785689520579168985157976901795803690504580969082758156911485
77378885757797891935785789526579178985657977901845803790509580979083258157911535
77388886357798891985785889531579188986257978901895803890515580989083858158911585
773988868577998920
LOGARITHMS OF NUMBERS.
N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D. N.Log.D.
81609116958220914875823091803583409211758400924285846092737585209304458580933495
81619117458221914926828191808583419212258401924335846192742585219304958581933545
81629118068222914985828291814683429212758402924385846292747585229305458582933595
81639118558223915035828391819583439213258403924436846392752585239305958583933645
81649119068224915086828491824583449213758404924495846492758585249306458584933695
81659119558225915146828591829583459214358405924545846592763585259306958585933745
81669120158226915195828691834683469214858406924595846692768585269307558586933795
81679120658227915245828791840583479215358407924645846792773585279308058587933845
81689121258228915296828891845583489215858408924695846892778585289308558588933895
81699121758229915355828991850583499216358409924745846992783585299309058589933945
81709122258230915405829091855583509216958410924805847092788585309309558590933995
81719122858231915455829191861583519217458411924855847192793685319310058591934045
81729123358232915516829291866583529217958412924905847292799585329310558592934095
81739123858233915565829391871583539218458413924955847392804585339311058593934146
81749124368234915615829491876583549218958414925005847492809585349311558594934205
81759124958235915666829591882583559219558415925055847592814585359312058595934255
81769125458236915725829691887583569220058416925115847692819585369312558596934305
81779125958237915775829791892583579220558417925165847792824585379313158597934355
81789126558238915825829891897583589221058418925215847892829585389313658598934405
81799127058239915876829991902583599221558419925265847992834585399314158599934455
81809127558240915935830091908583609222158420925315848092840585409314658600934505
81819128158241915985830191913583619222658421925365848192845585419315158601934555
81829128658242916035830291918583629223158422925425848292850585429315658602934605
81839129158243916095830391924583639223658423925475848392855585439316158603934655
81849129758244916145830491929583649224158424925525848492860585449316658604934705
81859130258245916195830591934583659224758425925575848592865585459317158605934755
81869130758246916245830691939583669225258426925625848692870585469317658606934805
81879131258247916305830791944583679225758427925675848792875585479318158607934855
81889131858248916355830891950583689226258428925725848892881585489318658608934905
81899132358249916405830991955583699226758429925785848992886585499319258609934955
81909132858250916455831091960583709227358430925835849092891585509319758610935005
81919133458251916515831191965583719227858431925885849192896585519320258611935055
81929133958252916565831291971583729228358432925935849292901585529320758612935105
81939134458253916615831391976583739228858433925985849392906585539321258613935155
81949135068254916665831491981583749229358434926035849492911585549321758614935205
81959135558255916725831591986583759229858435926095849592916585559322258615935265
81969136058256916775831691991583769230458436926145849692921585569322758616935315
81979136558257916825831791997583779230958437926195849792927585579323258617935365
81989137158258916875831892002583789231458438926245849892932585589323758618935415
81999137658259916935831992007583799231958439926295849992937585599324258619935465
82009138158260916985832092012583809232458440926345850092942585609324758620935515
82019138758261917035832192018583819233058441926395850192947585619325258621935565
82029139258262917095832292023583829233558442926455850292952585629325858622935615
82039139758263917145832392028583839234058443926505850392957585639326358623935665
82049140358264917195832492033583849234558444926555850492962585649326858624935715
82059140858265917245832592038583859235058445926605850592967585659327358625935765
82069141358266917305832692044583869235558446926655850692973585669327858626935815
82079141858267917355832792049583879236158447926705850792978585679328358627935865
82089142458268917405832892054583889236658448926755850892983585689328858628935915
82099142958269917455832992059583899237158449926815850992988585699329358629935965
82109143458270917515833092065583909237658450926865851092993585709329858630936015
82119144058271917565833192070583919238158451926915851192998585719330358631936065
82129144558272917615833292075583929238758452926965851293003585729330858632936115
82139145058273917665833392080583939239258453927015851393008585739331358633936165
82149145558274917725833492085583949239758454927065851493013585749331858634936215
82159146158275917775833592091583959240258455927115851593018585759332358635936265
82169146658276917825833692096583969240758456927165851693024585769332858636936315
82179147158277917875833792101583979241258457927225851793029585779333458637936365
82189147758278917935833892106583989241858458927275851893034585789333958638936415
82199148258279917985833992111583999242358459927325851993039585799334458639936465
82209148758280918035834092117584009242858460927375852093044585809334958640936515
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
364093651870093952870094250588209454758880948415894095134590009542459060957135
36419365658701939575876194255588219455258881948465894195139590019542959061957185
36429366158702939625876294260588229455758882948515894295144590029543459062957225
36439366658703939675876394265588239456258883948565894395148590039543959063957275
36449367158704939725876494270588249456758884948615894495153590049544459064957325
36459367668705939775876594275588259457158885948665894595158590059544959065957375
36469368258706939825876694280588269457658886948715894695163590069545459066957425
36479368758707939875876794285588279458158887948765894795168590079545959067957465
36489369258708939925876894290588289458658888948815894895173590089546459068957515
36499369758709939975876994295588299459158889948855894995177590099546859069957565
36509370258710940025877094300588309459658890925925895095182590109547259070957615
36519370758711940075877194305588319460158891948955895195187590119547759071957665
36529371258712940125877294310588329460658892949005895295192590129548259072957705
36539371758713940175877394315588339461158893949055895395197590139548759073957755
36549372258714940225877494320588349461658894949105895495202590149549259074957805
36559372758715940275877594325588359462158895949155895595207590159549759075957855
36569373258716940325877694330588369462658896949195895695211590169550159076957895
36579373758717940375877794335588379463058897949245895795216590179550659077957945
36589374258718940425877894340588389463558898949295895895221590189551159078957995
36599374758719940475877994345588399464058899949345895995226590199551659079958045
36609375258720940525878094349588409464558900949395896095231590209552159080958095
36619375758721940575878194354588419465058901949445896195236590219552559081958135
36629376258722940625878294359588429465558902949495896295240590229553059082958185
36639376758723940675878394364588439466058903949545896395245590239553559083958235
36649377258724940725878494369588449466558904949595896495250590249554059084958285
36659377758725940775878594374588459467058905949635896595255590259554559085958325
36669378258726940825878694379588469467558906949685896695260590269555059086958375
36679378758727940875878794384588479468058907949735896795265590279555459087958425
36689379258728940915878894389588489468558908949785896895270590289555959088958475
36699379758729940965878994394588499468958909949835896995274590299556459089958525
36709380258730941015879094400588509469458910949885897095279590309556959090958565
36719380758731941065879194404588519469958911949935897195284590319557459091958615
36729381258732941115879294409588529470458912949985897295289590329557959092958665
36739381758733941165879394414588539470958913950025897395294590339558359093958715
36749382258734941215879494419588549471458914950075897495299590349558859094958755
36759382758735941265879594424588559471958915950125897595303590359559359095958805
36769383258736941315879694429588569472458916950175897695308590369559859096958855
36779383758737941365879794433588579472958917950225897795313590379560259097958905
36789384258738941415879894438588589473458918950275897895318590389560759098958955
36799384758739941465879994443588599473858919950325897995323590399561259099958995
36809385258740941515880094448588609474358920950365898095328590409561759100959045
36819385758741941565880194453588619474858921950415898195333590419562259101959095
36829386258742941615880294458588629475358922950465898295337590429562659102959145
36839386758743941665880394463588639475858923950515898395342590439563159103959185
36849387258744941715880494468588649476358924950565898495347590449563659104959235
36859387758745941765880594473588659476858925950615898595352590459564159105959285
36869388258746941815880694478588669477358926950665898695357590469564659106959335
36879388758747941865880794483588679477858927950715898795361590479565059107959385
36889389258748941915880894488588689478358928950755898895366590489565559108959425
36899389758749941965880994493588699478758929950805898995371590499566059109959475
36909390258750942015881094498588709479258930950855899095376590509566559110959525
36919390758751942065881194503588719479758931950905899195381590519567059111959575
36929391258752942115881294507588729480258932950955899295386590529567459112959615
36939391758753942165881394512588739480758933951005899395391590539567959113959665
36949392258754942215881494517588749481258934951055899495395590549568459114959715
36959392758755942265881594522588759481758935951105899595400590559568959115959765
36969393258756942315881694527588769482258936951145899695405590569569459116959805
36979393758757942365881794532588779482758937951195899795410590579569859117959855
36989394258758942405881894537588789483258938951245899895415590589570359118959905
36999394758759942455881994542588799483658939951295899995419590599570859119959955
37009395258760942505882094547588809484158940951345900095424590609571359120959995
LOGARITHMS OF NUMBERS.
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
9120959959180962845924096567593009684859360971284942097405594809768149540979554
9121960059181962895924196572593019685359361971325942197410594819768549541979594
9122960059182962945924296577593029685859362971375942297414594829769059542979645
9123960149183962984924396581493039686249363971425942397419594839769559543979685
9124960159184963035924496586593049686759364971465942497424594849769959544979735
9125960259185963085924596591493059687249365971514942597428494859770459545979785
9126960259186963134924696595593069687659366971555942697433594869770849546979824
9127960359187963175924796600593079688159367971605942797437494879771359547979875
9128960359188963225924896605493089688649368971655942897442594889771749548979914
9129960429189963275924996609593099689059369971695942997447594899772259549979965
9130960479190963324925096614593109689559370971745943097451494909772749550980004
9131960529191963365925196619593119690049371971794943197456494919773149551980055
9132960579192963415925296624493129690459372971835943297460494929773659552980094
9133960619193963464925396628593139690959373971885943397465594939774059553980145
9134960669194963505925496633593149691449374971925943497470594949774559554980194
9135960719195963555925596638493159691859375971975943597474594959774949555980235
9136960769196963605925696642593169692359376972024943697479594969775459556980285
9137960809197963654925796647593179692859377972065943797483594979775959557980324
9138960859198963695925896652493189693259378972115943897488594989776359558980374
9139960909199963745925996656593199693759379972165943997493594999776859559980415
9140960959200963795926096661593209694249380972205944097497595009777259560980465
9141960909201963844926196666493219694659381972255944197502495019777759561980504
9142961019202963885926296670593229695159382972305944297506495029778259562980555
9143961069203963935926396675593239695659383972345944397511595039778659563980594
9144961119204963984926496680593249696059384972395944497516595049779159564980644
9145961169205964025926596685493259696559385972435944597520595059779559565980684
9146961219206964075926696689593269697059386972485944697525595069780059566980735
9147961269207964125926796694593279697459387972535944797529495079780449567980785
9148961319208964174926896699593289697959388972575944897534595089780959568980824
9149961369209964215926996703593299698449389972625944997539595099781359569980874
9150961429210964265927096708593309698859390972675945097543595109781859570980914
9151961479211964314927196713493319699349391972715945197548595119782359571980965
9152961529212964355927296717593329699759392972764945297552495129782749572981004
9153961579213964405927396722593339700259393972804945397557595139783259573981055
9154961619214964455927496727493349700749394972855945497562595149783649574981095
9155961669215964504927596731593359701159395972904945597566495159784159575981144
9156961719216964544927696736593369701659396972945945697571595169784559576981184
9157961769217964595927796741493379702159397972995945797575495179785059577981235
9158961809218964644927896745593389702559398973045945897580595189785559578981274
9159961859219964685927996750593399703059399973085945997585595199785949579981325
9160961909220964735928096755493409703549400973135946097589595209786449580981374
9161961949221964785928196759593419704059401973175946197594595219786859581981414
9162961999222964834928296764593429704459402973225946297598495229787359582981465
9163962049223964875928396769593439704959403973275946397603595239787749583981504
9164962099224964925928496774493449705349404973315946497606595249788259584981554
9165962139225964974928596778593459705859405973365946597612595259788649585981595
9166962189226965015928696783593469706349406973405946697617595269789159586981644
9167962239227965065928796788593479706759407973455946797621595279789659587981684
9168962289228965115928896792593489707259408973505946897626595289790049588981735
9169962329229965155928996797593499707759409973545946997630595299790559589981775
9170962379230965205929096802593509708159410973595947097635595309790959590981824
9171962429231965255929196806593519708649411973645947197640495319791449591981865
9172962479232965304929296811593529709059412973685947297644495329791859592981915
9173962519233965345929396816593539709559413973735947397649595339792359593981954
9174962569234965395929496820593549710049414973775947497653495349792859594982005
9175962619235965444929596825493559710459415973825947597658595359793259595982045
9176962669236965485929696830593569710959416973875947697663595369793759596982095
9177962709237965535929796834493579711459417973915947797667595379794159597982144
9178962759238965585929896839593589711859418973965947897672595389794659598982184
91799628092399656249299968445
N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D. N. Log. D.
9600982279650984534970098677975098900598009912398509934449900995649950997825
9601982329651984574970198682975198905598019912798519934849901995689951997874
9602982369652984624970298686975298909598029913198529935249902995729952997914
9603982419653984664970398691975398914598039913698539935749903995779953997954
9604982459654984714970498695975498918498049914098549936149904995819954998005
9605982509655984754970598700975598923498059914598559936649905995859955998044
9606982549656984804970698704975698927498069914998569937049906995909956998084
9607982599657984844970798709975798932598079915498579937449907995949957998135
9608982639658984894970898713975898936498089915898589937949908995999958998174
9609982689659984934970998717975998941498099916298599938349909996039959998225
9610982729660984984971098722976098945498109916798609938849910996079960998264
9611982779661985024971198726976198949498119917198619939249911996129961998304
9612982819662985074971298731976298954598129917698629939649912996169962998354
9613982869663985114971398735976398958498139918098639940149913996219963998394
9614982909664985164971498740976498963598149918598649940549914996259964998434
9615982959665985204971598744976598967498159918998659941049915996299965998484
9616982999666985254971698749976698972498169919398669941449916996349966998524
9617983049667985294971798753976798976498179919898679941949917996389967998564
9618983089668985344971898758976898981598189920298689942349918996429968998615
9619983139669985384971998762976998985498199920798699942749919996479969998654
9620983189670985434972098767977098989598209921198709943249920996519970998705
9621983229671985474972198771977198994498219921698719943649921996569971998744
9622983279672985524972298776977298998498229922098729944149922996609972998784
9623983319673985564972398780977399003598239922498739944549923996649973998835
9624983369674985614972498784977499007498249922998749944949924996699974998874
9625983409675985654972598789977599012498259923398759945449925996739975998914
9626983459676985704972698793977699016498269923898769945849926996779976998964
9627983499677985744972798798977799021498279924298779946349927996829977999004
9628983549678985794972898802977899025498289924798789946749928996869978999044
9629983589679985834972998807977999029498299925198799947149929996919979999095
9630983639680985884973098811978099034498309925598809947649930996959980999134
9631983679681985924973198816978199038498319926098819948049931996999981999174
9632983729682985974973298820978299043498329926498829948449932997049982999224
9633983769683986014973398825978399047498339926998839948949933997089983999264
9634983819684986054973498829978499052598349927398849949349934997129984999304
9635983859685986104973598834978599056498359927798859949849935997179985999355
9636983909686986144973698838978699061498369928298869950249936997219986999394
9637983949687986194973798843978799063498379928698879950649937997269987999444
9638983999688986234973898847978899069498389929198889951149938997309988999484
9639984039689986284973998851978999074598399929598899951549939997349989999524
9640984089690986324974098856979099078498409930098909952049940997399990999575
9641984129691986374974198860979199083498419930498919952449941997439991999614
9642984179692986414974298865979299087498429930898929952849942997479992999654
9643984219693986464974398869979399092498439931398939953349943997529993999705
9644984269694986504974498874979499096498449931798949953749944997569994999744
9645984309695986554974598878979599100498459932298959954249945997609995999784
9646984359696986594974698883979699105498469932698969954649946997659996999835
9647984399697986644974798887979799109498479933098979955049947997699997999874
9648984449698986684974898892979899114498489933598989955549948997749998999914
9649984489699986734974998896979999118498499933998999955949949997789999999965
96509845397009867749750989009800991235985099344990099564499509978210000000004
LOGARITHMIC SINES AND TANGENTS.
0 Degrees. 1 Degree.
Inf. neg. Inf. neg. Inf. pos. Inf. pos. Inf. pos. Inf. pos. Inf. pos. Inf. neg. Inf. neg. Inf. pos. Inf. pos. Inf. pos. Inf. pos.
0000000000000
1111111111111
2222222222222
3333333333333
4444444444444
5555555555555
6666666666666
7777777777777
8888888888888
9999999999999
10101010101010101010101010
11111111111111111111111111
12121212121212121212121212
13131313131313131313131313
14141414141414141414141414
15151515151515151515151515
16161616161616161616161616
17171717171717171717171717
18181818181818181818181818
19191919191919191919191919
20202020202020202020202020
21212121212121212121212121
22222222222222222222222222
23232323232323232323232323
24242424242424242424242424
25252525252525252525252525
26262626262626262626262626
27272727272727272727272727
28282828282828282828282828
29292929292929292929292929
30303030303030303030303030
31313131313131313131313131
32323232323232323232323232
33333333333333333333333333
34343434343434343434343434
35353535353535353535353535
36363636363636363636363636
37373737373737373737373737
38383838383838383838383838
39393939393939393939393939
40404040404040404040404040
41414141414141414141414141
42424242424242424242424242
43434343434343434343434343
44444444444444444444444444
45454545454545454545454545
46464646464646464646464646
47474747474747474747474747
48484848484848484848484848
49494949494949494949494949
50505050505050505050505050
51515151515151515151515151
52525252525252525252525252
53535353535353535353535353
54545454545454545454545454
55555555555555555555555555
56565656565656565656565656
57575757575757575757575757
58585858585858585858585858
59595959595959595959595959
60606060606060606060606060
Col. Col. Col. Col. Col. Col. Col. Col. Col. Col. Col. Col. Col.
89 Degrees. 88 Degrees.

LOGARITHMIC SINES AND TANGENTS.

2 Degrees. 3 Degrees.
Sin. Dif. Tang. Dif. Cot. Col. Sin. Dif. Tang. Dif. Cot. Col.
08.542823608.5430836111.456929.999746908.718802408.7194024111.285609.9994000
18.546423578.5466935811.453319.999735918.721202398.7218123911.278199.9994059
28.549993558.5502735811.449739.999735828.723592388.7242023911.275809.9993958
38.553543538.5538235511.446189.999725738.725972378.7265923711.273419.9993857
48.557053518.5573435211.442669.999715648.728342358.7289623611.271049.9993756
58.560543498.5608334911.439179.999715558.730692348.7313223411.268689.9993755
68.564003468.5642934611.435719.999715468.733032348.7336623411.266349.9993654
78.567433438.5677334411.432279.999705378.735332328.7360023211.264009.9993653
88.570843418.5711434111.428869.999705288.737672328.7383223111.261689.9993552
98.574213378.5745233811.425489.999695168.739972298.7406322911.259379.9993451
108.577573368.5778833611.422129.9996950108.742262288.7429222911.257089.9993450
118.580893328.5812133311.418799.9996849118.744542268.7452122711.254799.9993349
128.584193308.5845133011.415499.9996848128.746802268.7474822611.252529.9993248
138.587473288.5877932811.412219.9996747138.749062248.7497422511.250269.9993247
148.590733258.5910532611.408959.9996746148.751302238.7519922411.248019.9993146
158.593953238.5942832311.405729.9996745158.753532228.7542322211.245779.9993045
168.597153188.5974931911.402519.9996644168.755752208.7564522211.243559.9992944
178.600353168.6006831611.399329.9996643178.757952208.7586722011.241339.9992843
188.603493148.6038431411.396169.9996542188.760152198.7608721911.239139.9992842
198.606623138.6069831411.393029.9996441198.762342178.7630621911.236949.9992741
208.609733118.6100931111.389919.9996440208.764512168.7652321711.234759.9992640
218.612823078.6131930711.386819.9996339218.766672168.7674221611.232589.9992539
228.615903058.6162630711.383749.9996338228.768832158.7695821511.230429.9992438
238.618943038.6193130511.380609.9996237238.770972148.7717321411.228279.9992337
248.621963028.6223430311.377669.9996236248.773102128.7738721311.226139.9992236
258.624973018.6235330111.374659.9996135258.775222118.7760021111.224009.9992135
268.627952968.6283429711.371669.9996134268.777332108.7781121111.221869.9992034
278.630912948.6313129711.368699.9996033278.779432098.7802221011.219789.9992133
288.633852918.6342629511.365749.9996032288.781522088.7823220911.217689.9992032
298.636782938.6371829211.362829.9995931298.783602088.7844120811.215599.9992031
308.639682908.6400929111.359919.9995930308.785652068.7864920611.213519.9991930
318.642562878.6429828711.357029.9995829318.787772058.7885520611.211459.9991829
328.645432848.6458528511.354159.9995828328.789792048.7906120511.209399.9991728
338.648272838.6487528411.351309.9995727338.791832038.7926620411.207349.9991627
348.651102818.6515428111.348469.9995626348.793862028.7947520311.205309.9991526
358.653912798.6543528011.345659.9995625358.795882018.7967320211.203279.9991425
368.656702778.6571527811.342859.9995524368.797892018.7987520111.201259.9991324
378.659472768.6599327611.340079.9995523378.799901998.8007620111.199249.9991223
388.662222768.6626927611.337319.9995422388.801891998.8027719911.197239.9991122
398.664972748.6654327411.334579.9995421398.803881978.8047619811.195249.9991021
408.667692728.6681627111.331849.9995320408.805851978.8067419811.193269.9990920
418.670392698.6708726911.329139.9995219418.807821998.8087219611.191289.9990819
428.673082678.6735626811.326449.9995218428.809781958.8106819611.189329.9990718
438.675752668.6762426611.323769.9995117438.811731948.8126419511.187369.9990617
448.678412638.6789526411.321109.9995116448.813671938.8145919411.185419.9990516
458.681042638.6815426311.318469.9995015458.815601928.8165319311.183479.9990415
468.683672608.6841726111.315839.9994914468.817521928.8184619211.181549.9990314
478.686272598.6867526011.313229.9994913478.819441908.8203819211.179629.9990213
488.688862588.6893825811.310629.9994812488.821341908.8223019011.177709.9990112
498.691442568.6919625711.308049.9994811498.823241898.8242019011.175809.9990011
508.694002548.6945325511.305479.9994710508.825131888.8261018911.173929.9989910
518.696542538.6970825411.302929.9994609518.827011878.8279918811.172019.9989809
528.699072528.6996225211.300389.9994608528.828881878.8298718811.170139.9989708
538.701592508.7021425111.297869.9994507538.830751868.8317518611.168259.9989607
548.704092498.7046525011.295359.9994406548.832611858.8336118611.166399.9989506
558.706582478.7071424811.292869.9994405558.834461848.8354718511.164539.9989405
568.709052468.7096224611.290389.9994304568.836301838.8373218411.162689.9989304
578.711512448.7120824511.287929.9994203578.838131838.8391618411.160849.9989203
588.713952438.7145324411.285479.9994202588.839961818.8410018211.159009.9989102
598.716382438.7160724411.283039.9994101598.841771818.8428218211.157189.9989001
608.718802428.7194024311.280609.9994000608.843581818.8446418211.155369.9988900
Col. Cot. Tang. Sim. Col. Cot. Tang. Sim.

87 Degrees.

86 Degrees.

LOGARITHMIC SINES AND TANGENTS.
4 Degrees. 5 Degrees.
° Sin. Dif. Tang. Dif. Cot. Col. ° Sin. Dif. Tang. Dif. Cot. Col.
08.843581818.846418211.153369.99894600.840301448.9419314511.058059.99834
18.845391798.8464018011.153549.99893591.8.941741438.9434014511.056609.99833
28.847181798.8482618011.151749.99892582.8.943171448.9448314511.055159.99832
38.848971788.8500617911.149949.99891573.8.944611428.9463014311.053709.99831
48.850751778.8518517911.148159.99891564.8.946031428.9477314311.052279.99830
58.852521778.8536317811.146379.99890555.8.947401418.9491714411.050839.99829
68.854291768.8554017711.144609.99889546.8.948871428.9506014311.049409.99828
78.856051758.8571717611.142839.99888537.8.950201418.9520214211.047989.99827
88.857801758.8589317611.141079.99887528.8.951701408.9534414211.046569.99825
98.859551738.8606917411.139319.99886519.8.953101408.9548614211.045149.99824
108.861281738.8624317411.137579.998855010.8.954501398.9562714011.043739.99823
118.863011738.8641717411.135839.998844911.8.955801398.9576714111.042339.99822
128.864741718.8659117211.134099.998834812.8.957281398.9590813911.040929.99821
138.866451718.8676317211.132379.998824713.8.958671388.9604714011.039539.99820
148.868161718.8693517111.130659.998814614.8.960051388.9618713811.038139.99819
158.869871698.8710617111.128949.998804515.8.961431378.9632513911.036759.99817
168.871561698.8727717011.127239.998794416.8.962801378.9646413811.035369.99816
178.873251698.8744716911.125539.998794317.8.964171368.9660213711.033989.99815
188.874941678.8761616911.123849.998784218.8.965531368.9673913811.032619.99814
198.876611688.8778516811.122159.998774119.8.966891368.9687713811.031239.99813
208.878291668.8795316711.120479.998764020.8.968251358.9701313711.029879.99812
218.879951668.8812016711.118809.998753921.8.969601358.9715013511.028509.99810
228.881611658.8828716611.117139.998743822.8.970951348.9728513611.027159.99809
238.883261648.8845316511.115479.998733723.8.972291348.9742113511.025799.99808
248.884901648.8861816511.113829.998723624.8.973631338.9755613511.024449.99807
258.886541638.8878316511.112179.998713525.8.974961338.9769113411.023099.99806
268.888171638.8894816311.110529.998703426.8.976291338.9782513411.021759.99804
278.889801628.8911116311.108899.998693327.8.977621328.9795913311.020419.99803
288.891421628.8927416311.107269.998683228.8.978941328.9809213311.019089.99802
298.893041608.8943716111.105639.998673129.8.980261328.9822513311.017759.99801
308.894641618.8959816211.104029.998663030.8.981571318.9835813211.016429.99800
318.896251598.8976016011.102409.998652931.8.982881318.9849013211.015109.99798
328.897841598.8992016011.100809.998642832.8.984191308.9862213111.013789.99797
338.899431598.9008016011.099209.998632733.8.985491308.9875313111.012479.99796
348.901021588.9024915911.097609.998622634.8.986791298.9888413111.011169.99795
358.902601578.9039915811.096019.998612535.8.988081298.9901513011.009839.99793
368.904171578.9055715811.094439.998602436.8.989371298.9914513011.008559.99792
378.905741568.9071515711.092859.998592337.8.990661288.9927513011.007259.99791
388.907301558.9087215711.091289.998582238.8.991941288.9940512911.005959.99790
398.908851558.9102915611.089719.998572139.8.993221288.9953412811.004669.99788
408.910401558.9118315511.088119.998562040.8.994501278.9966212811.003389.99787
418.911951548.9134015511.086609.998551941.8.995771278.9979112811.002099.99786
428.913491538.9149515511.085059.998541842.8.997041268.9991912711.000819.99785
438.915021538.9165015311.083509.998531743.8.998301269.0004612810.999549.99783
448.916551528.9180315411.081979.998521644.8.999561269.0017412710.998269.99782
458.918071528.9195715311.080439.998511545.8.999821259.0030112610.996999.99781
468.919591518.9211015211.078909.998501446.8.999821259.0042712610.995739.99780
478.921101518.9226215211.077389.998481347.8.999821249.0055312610.994479.99778
488.922611508.9241415111.075869.998471248.8.999821259.0067912610.993219.99777
498.924111508.9256315111.074359.998461149.8.999821259.0080512510.991959.99776
508.925611498.9271615011.072849.998451050.8.999821249.0093012510.990709.99775
518.927101498.9286615011.071349.99844951.8.999821239.0105512410.989439.99773
528.928591488.9301614911.069849.99843852.8.999821239.0117912410.988169.99772
538.930071478.9316514811.068359.99842753.8.999821229.0130312410.986979.99771
548.931541478.9331314911.066879.99841654.8.999821229.0142712310.985739.99769
558.933011478.9346214711.065389.99840555.8.999821219.0155012310.984509.99768
568.934481468.9360914711.063919.99839456.8.999821219.0167312310.983279.99767
578.935941468.9375014711.062449.99838357.8.999821219.0179612210.982049.99765
588.937401458.9390314611.060979.99837258.8.999821219.0191812210.980829.99764
598.938851458.9404914611.059519.99836159.8.999821209.0204012210.979629.99763
608.940301458.9419514611.058059.99834060.8.999821209.0216212210.978389.99761
Col. Cot. Tang. Sin. Col. Cot. Tang. Sin.
85 Degrees. 84 Degrees.

LOGARITHMIC SINES AND TANGENTS.

6 Degrees. 7 Degrees.
Sin. Dif. Tang. Dif. Col. Col. Sin. Dif. Tang. Dif. Col. Col.
09.019231209.0216212110.978389.997616009.085891039.0891410510.910869.9967360
19.020431209.0228312110.977179.997605919.086921039.0901910410.909819.9967459
29.021631209.0240412110.975969.997595829.087951029.0912310410.908779.9967558
39.022831199.0252512010.974759.997585739.088971029.0922710310.907739.9967657
49.024021189.0264512110.973539.997575649.089991029.0933510410.906709.9966956
59.025221199.0276611910.972349.997565559.091011019.0943410310.905669.9966755
69.026391189.0288512010.971159.997555469.092021029.0953710310.904639.9966654
79.027571199.0300511910.969959.997545379.093041019.0964010210.903609.9966453
89.028741179.0312411810.968769.997535289.094051019.0974210310.902589.9966352
99.029921179.0324211910.967589.997495199.095061009.0984510210.901559.9966151
109.031091179.0336111810.966399.9974850109.096061019.0994710210.900539.9965950
119.032261169.0347911810.965219.9974749119.097071009.1004910110.899519.9965849
129.033421169.0359711710.964039.9974648129.098071009.1015010210.898509.9965648
139.034581169.0371411810.962869.9974547139.09927999.1025210110.897489.9965547
149.035741169.0383211610.961689.9974446149.10006999.1035310110.896479.9965346
159.036901159.0394811710.960529.9974345159.10106999.1045410110.895469.9965145
169.038051159.0406511610.959359.9974244169.10205999.1055510110.894459.9965044
179.039201159.0418111610.958199.9973843179.10304989.1065610010.893449.9964843
189.040341159.0429711610.957039.9973742189.10402999.1075610010.892449.9964742
199.041491159.0441311510.955879.9973641199.10501989.1085610010.891449.9964541
209.042621149.0452811510.954729.9973440209.10599989.1095610010.890449.9964340
219.043761149.0464311510.953579.9973339219.10697989.110569910.889449.9964239
229.044901139.0475811510.952429.9973138229.10795989.111559910.888459.9964038
239.046031129.0487311410.951279.9973037239.10893979.112549910.887469.9963837
249.047151139.0498711410.950139.9972836249.10990979.113539910.886479.9963736
259.048281129.0510111310.948999.9972735259.11087979.114529910.885489.9963535
269.049401129.0521411410.947869.9972634269.11184979.115519810.884499.9963334
279.050521129.0532811310.946729.9972433279.11281969.116499810.883519.9963233
289.051641119.0544111210.945599.9972332289.11377979.117479810.882539.9963032
299.052751119.0555311310.944479.9972131299.11474969.118459810.881559.9962931
309.053861119.0566611210.943349.9972030309.11570969.119439710.880579.9962730
319.054971109.0577811210.942229.9971829319.11666959.120409810.879609.9962529
329.056071109.0589011210.941109.9971728329.11761969.121389710.878629.9962428
339.057171109.0600211110.939989.9971627339.11857959.122359710.877669.9962227
349.058271109.0611311110.938879.9971526349.11952959.123329610.876689.9962026
359.059371099.0622411110.937769.9971425359.12047959.124289710.875729.9961825
369.060461099.0633511010.936639.9971324369.12142949.125259610.874759.9961724
379.061551099.0644511110.935559.9971223379.12236959.126219610.873799.9961523
389.062641089.0655611010.934449.9970822389.12331949.127179610.872839.9961322
399.063721099.0666610910.933349.9970721399.12425949.128139610.871879.9961221
409.064811089.0677511010.932259.9970520409.12519939.129099510.870919.9961020
419.065891079.0688510910.931159.9970419419.12612949.130049510.869969.9960819
429.066961089.0699410910.930069.9970218429.12706939.130959510.869019.9960718
439.068041079.0710310810.928979.9970117439.12799939.131949510.868069.9960517
449.069111079.0721110910.927899.9969916449.12892939.132899510.867119.9960316
459.070181069.0732010810.926809.9969815459.12985939.133849410.866169.9960115
469.071241079.0742810810.925729.9969614469.13078939.134789510.865229.9960014
479.072311069.0753610710.924679.9969513479.13171929.135739410.864279.9959813
489.073371059.0764310810.923579.9969312489.13263929.136679410.863339.9959612
499.074421069.0775110710.922459.9969211499.13355929.137619410.862399.9959511
509.075481059.0785810610.921429.9969010509.13447929.138549310.861469.9959310
519.076531059.0796410710.920369.9968809519.13539919.139489410.860529.9959109
529.077581059.0807110610.919299.9968708529.13630929.140419310.859569.9958908
539.078651059.0817710610.918239.9968607539.13722919.141349310.858669.9958807
549.079681059.0828310610.917179.9968506549.13815919.142279310.857739.9958606
559.080721049.0838910610.916119.9968405559.13904909.143209210.856809.9958405
569.081761049.0849510510.915059.9968304569.13994919.144129210.855889.9958204
579.082801039.0860010510.914009.9968203579.14085909.145049310.854969.9958103
589.083831039.0870510510.912959.9967802589.14175919.145979110.854039.9957902
599.084861039.0881010410.911909.9967701599.14266909.146889210.853129.9957701
609.085891039.0891410410.910869.9967500609.14356909.147809210.852209.9957500
Col. Col. Tang. Sin. Col. Col. Tang. Sin.

83 Degrees.

82 Degrees.

LOGARITHMIC SINES AND TANGENTS.
8 Degrees. 9 Degrees.
Sin. D. Tang. D. Cot. Col. Sin. D. Tang. D. Cot. Col.
09.14356899.1478010.852209.995756009.19433809.1997110.800299.9946260
19.14443909.1487210.851289.995745919.19513799.2005310.799479.9946059
29.14535899.1496310.850379.995725829.19592809.2013410.798669.9945858
39.14624909.1505410.849469.995705739.19672819.2021610.797849.9945657
49.14713899.1514510.848559.995685649.19751799.2029710.797039.9945456
59.14803909.1523610.847649.995665559.19830809.2037810.796229.9945255
69.14891899.1532710.846739.995655469.19909799.2045910.795419.9945054
79.14980909.1541710.845839.995635379.19988809.2054010.794609.9944853
89.15069899.1550810.844929.995615289.20067799.2062110.793799.9944652
99.15157909.1559810.844029.995595199.20145789.2070110.792999.9944451
109.15245889.1568810.843129.9955750109.20223799.2078210.792189.9944250
119.15333889.1577710.842239.9955649119.20302789.2086210.791389.9944049
129.15421879.1586710.841339.9955448129.20380789.2094210.790589.9943848
139.15508889.1595610.840449.9955247139.20458789.2102210.789789.9943647
149.15596879.1604610.839549.9955046149.20535779.2110210.788989.9943446
159.15683879.1613510.838659.9954845159.20613789.2118210.788189.9943245
169.15770879.1622410.837769.9954644169.20691779.2126110.787399.9943044
179.15857879.1631210.836889.9954543179.20768779.2134110.786599.9942743
189.15944869.1640110.835999.9954342189.20845779.2142010.785809.9942542
199.16030869.1648910.835119.9954141199.20922779.2149910.785019.9942341
209.16116879.1657710.834239.9953940209.20999779.2157810.784229.9942140
219.16203869.1666510.833359.9953739219.21076779.2165710.783439.9941939
229.16289859.1675310.832479.9953538229.21153779.2173610.782649.9941738
239.16374859.1684110.831599.9953337239.21229769.2181410.781869.9941537
249.16460869.1692810.830729.9953236249.21306779.2189310.781079.9941336
259.16545869.1701610.829849.9953035259.21382769.2197110.780299.9941135
269.16631859.1710310.828979.9952834269.21458769.2204910.779519.9940934
279.16716859.1719210.828109.9952633279.21534769.2212710.778739.9940733
289.16801849.1727710.827239.9952432289.21610769.2220510.777959.9940432
299.16886849.1736310.826379.9952231299.21685759.2228310.777179.9940231
309.16970849.1745010.825509.9952030309.21761769.2236110.776399.9940030
319.17055849.1753610.824649.9951829319.21836759.2243810.775629.9939829
329.17139849.1762210.823789.9951728329.21912769.2251610.774849.9939628
339.17223849.1770810.822929.9951527339.21987759.2259310.774079.9939427
349.17307849.1779410.822069.9951326349.22062759.2267010.773309.9939226
359.17391839.1788010.821209.9951125359.22137759.2274710.772539.9939025
369.17474839.1796510.820339.9950924369.22211749.2282410.771769.9938824
379.17558839.1805110.819499.9950723379.22286759.2290110.770999.9938523
389.17641839.1813610.818649.9950522389.22361759.2297710.770239.9938322
399.17724839.1822110.817799.9950321399.22435749.2305410.769469.9938121
409.17807839.1830610.816949.9950120409.22509749.2313010.768709.9937920
419.17890839.1839110.816099.9949919419.22583749.2320610.767949.9937719
429.17973829.1847510.815259.9949718429.22657749.2328310.767179.9937518
439.18055829.1856010.814409.9949517439.22731749.2335910.766419.9937317
449.18137839.1864410.813569.9949416449.22805749.2343510.765659.9937016
459.18220829.1872810.812729.9949215459.22878759.2351010.764909.9936815
469.18302819.1881210.811889.9949014469.22952749.2358610.764149.9936614
479.18383829.1889610.811049.9948813479.23025759.2366110.763399.9936413
489.18465829.1897910.810219.9948612489.23098759.2373710.762639.9936212
499.18547819.1906310.809379.9948411499.23171759.2381210.761889.9935911
509.18628819.1914610.808549.9948210509.23244759.2388710.761139.9935710
519.18709819.1922910.807719.994809519.23317759.2396210.760389.993559
529.18790819.1931210.806889.994788529.23390759.2403710.759639.993538
539.18871819.1939510.806059.994767539.23462759.2411210.758889.993517
549.18952819.1947810.805229.994746549.23535759.2418610.758149.993486
559.19033809.1956110.804399.994725559.23607759.2426110.757399.993465
569.19113809.1964310.803579.994704569.23679759.2433510.756659.993444
579.19193809.1972510.802759.994683579.23752759.2441010.755909.993423
589.19273809.1980710.801939.994662589.23823759.2448410.755169.993402
599.19353809.1988910.801119.994641599.23895759.2455810.754429.993371
609.19433809.1997110.800299.994620609.23967759.2463210.753689.993350
Col. Cot. Tang. Sin. Col. Cot. Tang. Sin.
81 Degrees. 80 Degrees.