(u±r)+i(v±s) = (u + iv) ±(r+is) Thus the law of indices obtains for complex quantities. (Cf. Art. 27.) 79. The Addition Theorem. Operating upon both sides of the equation last written with log, we have log (Bw B1)=w±t, which, if Bw =z and Bt=z', and therefore z=log w and 'log, t, becomes logk (z z′)=log ̧ z±log ̧≈", which is the addition theorem for complex quantities. (Cf. Art. 28.) 80. The Logarithmic Spiral. The locus of P, in Fig. 36 of Art. 68, is obviously a spiral. Its polar equation may be obtained by considering the rates of change of p and 0, which are respectively λp and wλ tan (4 — ß). By the definition of a logarithm for real quantities (Art. 23), is here the logarithm of p with respect to the modulus λ tan (ø — 3) / λ = tan (6 — 3); or in equivalent terms, This locus is called the logarithmic spiral. It is obvious from the definition of the motion of the point that generates this curve (Art. 68), that the spiral encircles the origin an infinite number of times, coming nearer to it with every return, and that it likewise passes around the circumference of the unit circle an infinite number of times, going continually farther away from it. 81. Periodicity of Exponentials. From its character as an operator that turns any line in the plane through the angle whose arc-ratio is 0, it is evident that cis acquires once all its possible values corresponding to real values of 0, when passes continuously from 0 to 2′′ and, ✯ being 27 k any integer, repeats the same cycle of values through every interval from 2 kr to 2(k+1), so that for all integral values of k, cis (0+ 2k) = cis 0. In consequence of this property, cis is said to be periodic, having the period 2π. The exponential Bw has similarly a period. Solving for ❝ and v the two linear eqations, or this result may be inferred by direct inspection of Fig. 36. Hence the equation Bu+wbu cis v'/m, of Art. 73, may be written = で m = In this formula let z'o and v' 2km, k being any integer. Then, since cis 2kπ= 1, Hence Bw has the period 2iKT. In particular e has the period 21π. It is obvious that the only series of values of v′ that will render cis '/m=1 is 2km, where k is an integer (Art. 63). Hence the only value of w, that will render Bw+w, Bw is w, 2kiк. The function Bw, therefore = = has only one period and is said to be singly periodic. 82. Many-Valuedness of Logarithms. As a consequence of the periodicity of Bwz, the logarithm (for all integral values of k) has the form log=w+zikкя, that is, log, for a given value of z, has an indefinitely great number of values, differing from each other, in successive pairs, by 2iκπ. The logarithm is therefore said to be many-valued; specifically its many-valuedness is infinite. We shall discover this property in other functions. In the natural agonic system, 83. Direct and Inverse Processes. In the present section and in Sec. VII we have had occasion to speak of logarithms and exponentials as inverse to one another. More explicitly, the exponential is called the direct function, the logarithm its inverse. We express the operation of inversion in general terms by letting ƒ (or some other letter) stand for any one of the direct functional symbols used, such as B, or b, thus expressing z as a direct function of w in the form and then writing z=ƒ(w), w=ƒ ̃1(2), for the purpose of expressing the fact that w is the corresponding inverse function of z. Thus when Bw takes the place of ƒ (w), log takes the place of ƒ ̃1(~). K In other terms, inversion is described as that process which annuls the effect of the direct process. If z=f(w), the effect of the operation ƒ is annulled by the operation f, thus: f'(2)=ƒ ̄f(w)=w. In accordance with this definition the following processes are inverse to each other: (i). Addition and subtraction: (x+a) a = x, (x − a) +a=x. = (ii). Multiplication and division: (xa)/a=x, (x/a)× a=x, (iii). Exponentiation and logarithmic operation: (iv). Involution and evolution : (xa)/ax, (x1/a)α=x. In the use of the notation of inversion here described, its application to symbolic operation, in the form ƒƒ—1 (w)=w, must be carefully distinguished from its application to products and quotients by which from abc is derived a=b-c. Whenever the direct function is periodic its inverse is obviously many-valued; for, if p be a period of ƒ(w), so that f(w+np)=ƒ(w)=2, f(z) = w+np, then for all integral values of n. (Cf. Art. 82.) 84. Agenda. Reduction of Exponential and Logarithmic Forms. Prove the following: (1). (a+b)u+iv == cu / 2 • In (a2+b2)—v tan ̄1 b/a cis[†vln (a2 + b2) + u tan ̄1b/a]. (2). (ib)u+iveunb-v/2 cis (vlnbu). + (5). logm+in (x + iy) = † m ln (x2 + y2) — n tan ̄1y/x + in ln (x2 + y2)+m tan-1y/x]. (6). logm+iniy=mlny-n+i (n lny + žmπ). (7). log(x)=ilnx-π. (8). log-(-x)= ln x-in. (9). log; iπ, log; (— i) = {π. (10). Given a + ib as the base of a system of logarithms, find the modulus and reduce it to the form u + iv. (11). Express a+iblog (x + iy) in the form u + iv in terms of a, b, x and y. (12). If u'=u cos ẞ+v sin ß, v': = cos ß- u sin ß, w=u+iv and κm (cos ẞ+ i sin ẞ), prove: u' = (ew/K+e-w/K) = cosh COS +isinh sin (13). From ƒ(w) = m u' ข m m m COS +icosh- sin m aw2+2bw+c=z deduce ƒ1(2)=(b±√ b2 — ac + az)/a. m m |