Page images
PDF
EPUB

Indeterminate Coefficients.

CHAPTER IV.

NUMERICAL EQUATIONS.

SECTION I.

Indeterminate Coefficients.

162. Theorem. If a polynomial

A + B x + С x2 + D x3 + E x2 + &c.

is such, as to be equal to zero independently of x, that is, if it is equal to zero whatever values are given to x, it must always be the case that

A=0, B=0, C=0, D=0, E = 0, &c.; that is, that the aggregate of all the coefficients of each power of x is equal to zero, and also the aggregate of all the terms which do not contain x is equal

to zero.

Proof. Since the equation

A+B+C x2 + D x3 + &c. = 0

is true for every value which can be given to x, it must be true when we make

x = 0;

in which case all the terms of the first member vanish ex cept the first, and we have

A = 0.

Indeterminate Coefficients.

This equation, being subtracted from the given equation,

gives

BxCx2+ D x3 + &c. = 0;

and, dividing by x,

B+Cx + D x2 + &c. = 0;

whence we may prove as above, that

B = 0.

By continuing this process, we can prove that
C = 0, D = 0, E = 0, &c.

163. Theorem. If two polynomials

A + B x + C x2 + D x3 + E xa +&c.,
A' + B' x + C′ x2 + D′ x3 + E' xa + &c.

are identical, that is, equal, independently of x, it must always be the case that

A = A', B = B', C — C', D = D', &c.

Proof. For the equation

=

A+Bx+Cx2+ &c. = A'+ B' x + C' x2 + &c.

gives, by transposition,

= 0;

(A — A')+(B — B') x + ( C — C') x2 + &c.= whence, by the preceding theorem,

that is,

A-A'=0, B-B'0, C-C' = 0, &c.;

A=A', B=B', C= C, &c.

A Function; its Variable, and Rate of Change.

SECTION II.

Derivation.

164. Definition. When quantities are so connected that their values are dependent upon each other, each is said to be a function of the others: which are called variables when they are supposed to be changeable in their values, and constants when they are supposed to be unchangeable.

[blocks in formation]

y is a function of the a, b, and x; but if x is variable while a and b are constant, it is more usual to regard y as simply a function of x.

165. Definition. In the case of a change in the value of a function, arising from an infinitely small change in the value of one of its variables, the relative rate of change of the function and the variable, that is, the ratio of the change in the value of the function to that in the value of the variable, is called the derivative of the function.

The derivative of the derivative of a function is called the second derivative of the function; the derivative of the second derivative is called the third derivative; and so on.

166. Corollary. The derivative of a constant is

zero.

167. Corollary. The derivative of the variable, regarded as a function of itself, is unity; and the second derivative is zero.

The Derivative of the sum of any Functions.

168. Theorem.

The derivative of the sum of two

functions is the sum of their derivatives.

Proof. Let the two functions be u and v, and let their values, arising from an infinitesimal change i in the value of their variable, be u' and v'; the increase of their sum will be

[merged small][merged small][merged small][ocr errors][merged small][merged small][merged small][merged small][merged small][ocr errors][merged small][merged small][merged small]

which is obviously the sum of their derivatives.

169. Corollary. By reversing the sign of v, it may be shown, in the same way, that the derivative of the difference of two functions is the difference of their derivatives.

170. Corollary.

The derivative of the algebraic sum of several functions connected by the signs + and is the algebraic sum of their derivatives.

171. Corollary. If, in this sum, any function is repeated any number of times, its derivative must be repeated the same number of times; in other words, if a function is multiplied by a constant its derivative must be multiplied by the same constant.

Thus, if the derivatives of u, v, and w are respectively U, V, and W, and if a, b, c, and e are constant, the derivative of

is

a u + b v c w + e is

a Ub V-c W.

172. Problem.

The Derivative of a Power.

power of a variable.

To find the derivative of any

Solution. Let the variable be a and the power a", and let b differ infinitely little from a; the derivative of an is

[blocks in formation]

Now when bis equal to a, the value of this quotient is, by art. 51,

n an -1;

and this must differ from the present value of this quotient, by an infinitely small quantity, which being neglected gives

for the derivative of a".

nan-1

The derivative of any power of a variable is, therefore, found by multiplying by the exponent, and diminishing the exponent by unity.

173. Corollary. The derivative of man when m is constant and a variable is n m an−1.

174. Problem. To find the derivative of any power of a function.

Solution. Let the variable be a, the function u, and the power un; let b differ infinitely little from a, and let v be the corresponding value of u; if U is the derivative of u and U that of u", we have

[ocr errors][merged small][merged small][merged small][merged small][ocr errors][merged small][merged small][merged small][merged small][merged small][merged small][merged small][merged small][merged small][ocr errors][merged small]
« PreviousContinue »