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Logarithm, in mathematics, the exponent or power to which a stated number, called the base, is raised to yield a specific number. For example, in the expression 102 = 100, the logarithm of 100 to the base 10 is 2. This is written log10 100 = 2. Logarithms were originally invented to help simplify the arithmetical processes of multiplication, division, expansion to a power, and extraction of a root, but they are now used for a variety of purposes in pure and applied mathematics.
The first tables of logarithms were published independently by the Scottish mathematician John Napier in 1614 and the Swiss mathematician Justus Byrgius in 1620. The first table of common logarithms was compiled by the English mathematician Henry Briggs. Common logarithms use the number 10 as the base number. A system of logarithms often employed uses the transcendental number e as a base; they are called natural logarithms.
The method of logarithms can be illustrated by considering a sequence of powers of the number 2: 21, 22, 23, 24, 25, and 26, corresponding to the sequence of numbers 2, 4, 8, 16, 32, and 64. The exponents 1, 2, 3, 4, 5, and 6 are the logarithms of these numbers to the base 2. To multiply any number in this sequence by any other number in the series it is only necessary to add the logarithms of the numbers, then find the antilogarithm of the sum of the logarithms, which is equal to the base number raised to the power of the sum. Thus, to multiply 16 by 4, first note that the logarithm of 16 is 4, and the logarithm of 4 is 2. The sum of the logarithms 4 and 2 is equal to 6, and the antilogarithm of 6 is 64, which is the product desired. In division the logarithms are subtracted. To divide 32 by 8 subtract 3 from 5, giving 2, which is the logarithm of the quotient, 4.
To expand a number to any power, multiply the logarithm by the power desired, and take the antilogarithm of the product. Thus, to find 43: log 2 4 = 2; 3 × 2 = 6; antilog 6 = 64, which is the third power of 4. Roots are extracted by dividing the logarithm by the desired root. To find the fifth root of 32: log2 32 = 5; 5 ÷ 5 = 1; antilog 1 = 2, which is the fifth root of 32.
The problem in constructing a table of logarithms is to make the intervals between successive entries sufficiently small. In the above example, where the entries are the powers 2, 4, 8, and so on, the entries are too far apart to be useful in multiplying any larger numbers. By advanced mathematical processes, the logarithm of any number to any base can be calculated, and exhaustive tables of logarithms have been prepared. Each logarithm consists of a whole number and a decimal fraction, called respectively the characteristic and the mantissa. In the common system of logarithms, which has the base 10, the logarithm of the number 7 has the characteristic 0 and the mantissa .84510 (correct to five decimal places) and is written 0.84510. The logarithm of the number 70 is 1.84510; and the logarithm of the number 700 is 2.84510. The logarithm of the number .7 is -0.15490, which is sometimes written 9.84510-10 for convenience in calculation. Logarithm tables have been replaced by electronic calculators and computers with logarithmic functions.
| Trigonometry
Trigonometry, branch of mathematics that deals with the relationships between the sides and angles of triangles and with the properties and applications of the trigonometric functions of angles. The two branches of trigonometry are plane trigonometry, which deals with figures lying wholly in a single plane, and spherical trigonometry, which deals with triangles that are sections of the surface of a sphere. The earliest applications of trigonometry were in the fields of navigation, surveying, and astronomy, in which the main problem generally was to determine an inaccessible distance, such as the distance between the earth and the moon, or of a distance that could not be measured directly, such as the distance across a large lake. Other applications of trigonometry are found in physics, chemistry, and almost all branches of engineering, particularly in the study of periodic phenomena, such as vibration studies of sound, a bridge, or a building, or the flow of alternating current.
The concept of the trigonometric angle is basic to the study of trigonometry. A trigonometric angle is generated by a rotating ray. The rays OA and OB (Fig. 1a, 1b, and 1c) are considered originally coincident at OA, which is called the initial side. The ray OB then rotates to a final position called the terminal side. An angle and its measure are considered positive if they are generated by counterclockwise rotation in the plane, and negative if they are generated by clockwise rotation. Two trigonometric angles are equal if they are congruent and if their rotations are in the same direction and of the same magnitude.
An angular unit of measure usually is defined as an angle with a vertex at the center of a circle and with sides that subtend, or cut off, a certain part of the circumference (Fig. 2).
If the subtended arc s (AB) is equal to one-fourth of the total circumference C, that is, s = C, so that OA is perpendicular to OB, the angular unit is a right angle. If s = C, so that the points A, O, and B are on a straight line, the angular unit is a straight angle. If s = 1/360C, the angular unit is one degree. If s = C, so that the subtended arc is equal to the radius of the circle, the angular unit is a radian. By equating the various values of C, it follows that
Each degree is subdivided into 60 equal parts called minutes, and each minute is subdivided into 60 equal parts called seconds. For finer measurements, decimal parts of a second may be used. Radian measurements smaller than a radian are expressed in decimals. The symbol for degree is °; for minutes, ‘; and for seconds, ". For radian measures either the abbreviation rad or no symbol at all may be used. Thus
The angular unit radian is understood in the last entry. (The notation 42".14 may be used instead of 42.14" to indicate decimal parts of seconds.) By convention, a trigonometric angle is labeled with the Greek letter theta (θ). If the angle θ is given in radians, then the formula s = rθ may be used to find the length of the arc s; if θ is given in degrees, then
Trigonometric functions are unitless values that vary with the size of an angle. An angle placed in a rectangular coordinate plane is said to be in standard position if its vertex coincides with the origin and its initial side coincides with the positive x-axis. In Fig. 3, let P, with coordinates x and y, be any point other than the vertex on the terminal side of the angle θ, and r be the distance between Pand the origin. Each of the coordinates x and y may be positive or negative, depending on the quadrant in which the point P lies; x may be zero, if P is on the y- axis, or y may be zero, if P is on the x-axis. The distance r is necessarily positive and is equal to
in accordance with the Pythagorean theorem (see Geometry).
The six commonly used trigonometric functions are defined as follows:
Since x and y do not change if 2 radians are added to the angle—that is, 360° are added—it is clear that sin (θ + 2) = sin θ. Similar statements hold for the five other functions. By definition, three of these functions are reciprocals of the three others, that is,
If point P, in the definition of the general trigonometric function, is on the y-axis, x is 0; therefore, because division by zero is inadmissible in mathematics, the tangent and secant of such angles as 90°, 270°, and -270° do not exist. If P is on the x-axis, y is 0; in this case, the cotangent and cosecant of such angles as 0°, 180°, and -180° do not exist. All angles have sines and cosines, because r is never equal to 0. Since r is greater than or equal to x or y, the values of sin θ and cos θ range from -1 to +1; tan θ and cot θ are unlimited, assuming any real value; sec θ and csc θ may be either equal to or greater than 1, or equal to or less than -1. It is readily shown that the value of a trigonometric function of an angle does not depend on the particular choice of point P, provided that it is on the terminal side of the angle, because the ratios depend only on the size of the angle, not on where the point P is located on the side of the angle. If θ is one of the acute angles of a right triangle, the definitions of the trigonometric functions given above can be applied to θ as follows (Fig. 4). Imagine the vertex A is placed at the intersection of the x-axis and y-axis in Fig. 3, that AC extends along the positive x-axis, and that B is the point P, so that AB = AP = r. Then sin θ = y/r = a/c, and so on, as follows:
The numerical values of the trigonometric functions of a few angles can be readily obtained; for example, either acute angle of an isosceles right triangle is 45°, as shown in Fig. 4. Therefore, it follows that
The numerical values of the trigonometric functions of any angle can be determined approximately by drawing the angle in standard position with a ruler, compass, and protractor; by measuring x, y, and r; and then by calculating the appropriate ratios. Actually, it is necessary to calculate the values of sin θ and cos θ only for a few selected angles, because the values for other angles and for the other functions may be found by using one or more of the trigonometric identities that are listed below.
The following formulas, called identities, which show the relationships between the trigonometric functions, hold for all values of the angle θ, or of two angles, θ and φ, for which the functions involved are:
By repeated use of one or more of the formulas in group V, which are known as reduction formulas, sin θ and cos θ can be expressed for any value of θ, in terms of the sine and cosine of angles between 0° and 90°. By use of the formulas in groups I and II, the values of tan θ, cot θ, sec θ, and csc θ may be found from the values of sin θ and cos θ. It is therefore sufficient to tabulate the values of sin θ and cos θ for values of θ between 0° and 90°; in practice, to avoid tedious calculations, the values of the other four functions also have been made available in tabulations for the same range of θ. |
