Elements of the Differential and Integral Calculus/Chapter IX

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DIFFERENTIALS

87. Introduction. Thus far we have represented the derivative of ${\displaystyle y=f(x)}$ by the notation

We have taken special pains to impress on the student that the symbol

was to be considered not as an ordinary fraction with dy as numerator and dx as denominator, but as a single symbol denoting the limit of the quotient

as ${\displaystyle \Delta x}$ approaches the limit zero.

Problems do occur, however, where it is very convenient to be able to give a meaning to dx and dy separately, and it is especially useful in applications of the Integral Calculus. How this may be done is explained in what follows.

88. Definitions. If ${\displaystyle f'(x)}$ is the derivative of ${\displaystyle f(x)}$ for a particular value of x, and ${\displaystyle \Delta x}$ is an arbitrarily chosen increment of x, then the differential of ${\displaystyle f(x)}$, denoted by the symbol ${\displaystyle df(x)}$, is defined by the equation

(A)	${\displaystyle df(x)=f'(x)\Delta x.}$

If now ${\displaystyle f(x)=x}$, then ${\displaystyle f'(x)=1}$, and (A) reduces to

showing that when x is the independent variable, the differential of x (= dx) is identical with ${\displaystyle \Delta x}$. Hence, if ${\displaystyle y=f(x)}$, (A) may in general be written in the form

(B)	${\displaystyle dy=f'(x)dx.}$[1]

The differential of a function equals its derivative multiplied by the differential of the independent variable.

Let us illustrate what this means geometrically.

Let ${\displaystyle f'(x)}$ be the derivative of ${\displaystyle y=f(x)}$ at P. Take ${\displaystyle dx=PQ}$, then

Therefore ${\displaystyle dy}$, or ${\displaystyle df(x)}$, is the increment (= QT) of the ordinate of the tangent corresponding to dx.^[2]

This gives the following interpretation of the derivative as a fraction.

If an arbitrarily chosen increment of the independent variable x for a point P(x, y) on the curve y = f(x) be denoted by dx, then in the derivative

dy denotes the corresponding increment of the ordinate drawn to the tangent.

89. Infinitesimals. In the Differential Calculus we are usually concerned with the derivative, that is, with the ratio of the differentials dy and dx. In some applications it is also useful to consider dx as an infinitesimal (see §15), that is, as a variable whose values remain numerically small, and which, at some stage of the investigation, approaches the limit zero. Then by (B), §88, and (2), §20, dy is also an infinitesimal.

In problems where several infinitesimals enter we often make use of the following

Theorem. In problems involving the limit of the ratio of two infinitesimals, either infinitesimal may be replaced by an infinitesimal so related to it that the limit of their ratio is unity.

Proof. Let ${\displaystyle \alpha ,\beta ,\alpha ',\beta '}$ be infinitesimals so related that

We have	${\displaystyle {\frac {\alpha }{\beta }}}$	${\displaystyle ={\frac {\alpha '}{\beta '}}\cdot {\frac {alpha}{\alpha '}}\cdot {\frac {\beta '}{\beta }}}$ identically,
and	${\displaystyle \lim {\frac {\alpha }{\beta }}}$	${\displaystyle =\lim {\frac {\alpha '}{\beta '}}\cdot \lim {\frac {\alpha }{\alpha '}}\cdot \lim {\frac {\beta '}{\beta }}}$	Th. II, §20
		${\displaystyle =\lim {\alpha '}{\beta '}\cdot 1\cdot 1}$.	By (C)
(D)	∴ ${\displaystyle \lim {\frac {\alpha }{\beta }}}$	${\displaystyle =\lim {\frac {\alpha '}{\beta '}}}$	Q.E.D

Now let us apply this theorem to the two following important limits.

For the independent variable x, we know from the previous section that ${\displaystyle \Delta x}$ and dx are identical.

Hence their ratio is unity, and also limit ${\displaystyle {\tfrac {\Delta x}{dx}}=1}$. That is, by the above theorem,

(E)	In the limit of the ratio of ${\displaystyle \Delta x}$ and a second infinitesimal, ${\displaystyle \Delta x}$ may be replaced by dx.

On the contrary it was shown that, for the dependent variable y, ${\displaystyle \Delta y}$ and dy are in general unequal. But we shall now show, however, that in this case also

${\displaystyle \lim {\frac {\Delta y}{dy}}=1}$.

Since ${\displaystyle \lim _{\Delta x=0}{\tfrac {\Delta y}{\Delta x}}=f'(x)}$ we may write

${\displaystyle {\frac {\Delta y}{\Delta x}}=f'(x)+\epsilon }$,

where ${\displaystyle \epsilon }$ is an infinitesimal which approaches zero when ${\displaystyle \Delta x{\dot {=}}0}$.

Clearing of fractions, remembering that ${\displaystyle \Delta x{\dot {=}}dx}$,

	${\displaystyle \Delta y}$	${\displaystyle =f'(x)dx+\epsilon \cdot \Delta x}$,
or	${\displaystyle \Delta y}$	${\displaystyle =dy+\epsilon \cdot \Delta x}$,	(B), §89

Dividing both sides by ${\displaystyle \Delta y}$,

	${\displaystyle 1}$	${\displaystyle ={\frac {dy}{\Delta y}}+\epsilon \cdot {\frac {\Delta x}{\Delta y}}}$,
or	${\displaystyle {\frac {dy}{\Delta y}}}$	${\displaystyle =1-\epsilon \cdot {\frac {\Delta x}{\Delta y}}}$.
		∴ ${\displaystyle \lim _{\Delta x\to 0}{\frac {dy}{\Delta y}}=1}$,

and hence ${\displaystyle \lim _{\Delta x\to 0}{\tfrac {\Delta y}{dy}}=1}$. That is, by the above theorem,

(F)	In the limit of the ratio of ${\displaystyle \Delta y}$ and a second infinitesimal, ${\displaystyle \Delta y}$ may be replaced by dy.

90. Derivative of the arc in rectangular coördinates. Let s be the length^[3] of the arc AP measured from a fixed point A on the curve.

Denote the increment of s (= arc PQ) by ${\displaystyle \Delta s}$. The definition of the length of arc depends on the assumption that, as Q approaches P,

If we now apply the theorem in §89 to this, we get

(G)	In the limit of the ratio of chord PQ and a second infinitesimal, chord PQ may be replaced by arc PQ (= ${\displaystyle \Delta s}$).

From the above figure

(H)	${\displaystyle ({\mbox{chord}}PQ)^{2}=(\Delta x)^{2}+(\Delta y)^{2},}$

Dividing through by ${\displaystyle (\Delta x)^{2}}$, we get

(I)	${\displaystyle \left({\frac {{\mbox{chord}}PQ}{\Delta x}}\right)^{2}=1+\left({\frac {\Delta y}{\Delta x}}\right)^{2}}$.

Now let Q approach P as a limiting position; then ${\displaystyle \Delta x{\dot {=}}0}$ and we have

(24)	∴ ${\displaystyle {\frac {ds}{dx}}={\sqrt {1+\left({\frac {dy}{dx}}\right)^{2}}}.}$

Similarly, if we divide (H) by ${\displaystyle (\Delta y)^{2}}$ and pass to the limit, we get

(25)	${\displaystyle {\frac {ds}{dy}}={\sqrt {\left({\frac {dx}{dy}}\right)^{2}+1}}.}$

Also, from the above figure,

Now as Q approaches P as a limiting position ${\displaystyle \theta {\dot {=}}\tau }$, and we get

(26)	${\displaystyle \cos \tau ={\frac {dx}{ds}}}$, ${\displaystyle \sin \tau ={\frac {dy}{ds}}.}$

Using the notation of differentials, formulas (25) and (26) may be written

(27)	${\displaystyle ds=\left[1+\left({\frac {dy}{dx}}\right)^{2}\right]^{\frac {1}{2}}dx}$.
(28)	${\displaystyle ds=\left[\left({\frac {dx}{dy}}\right)^{2}+1\right]^{\frac {1}{2}}dy}$.

Substituting the value of ds from (27) in (26),

(29)	${\displaystyle \cos \tau ={\frac {1}{\left[1+\left({\frac {dy}{dx}}\right)^{2}\right]^{\frac {1}{2}}}},\ \sin \tau ={\frac {\frac {dy}{dx}}{\left[1+\left({\frac {dy}{dx}}\right)^{2}\right]^{\frac {1}{2}}}}}$

An easy way to remember the relations (24)-(26) differentials dx, dy, ds is to note that they are correctly represented by a right triangle whose hypotenuse is ds, whose sides are dx and dy, and whose angle at the base is ${\displaystyle \tau }$. Then

and, dividing by dx or dy, gives (24) or (25) respectively. Also, from the figure,

the same relations given by (26).

91. Derivative of the arc in polar coördinates. In the derivation which follows we shall employ the same figure and the same notation used in §67

From the right triangle PRQ

${\displaystyle ({\mbox{chord}}PQY)^{2}}$	${\displaystyle =(PR)^{2}+(RQ)^{2}}$
	${\displaystyle =(\rho \sin \Delta \theta )^{2}+(\rho +\Delta \rho -\rho \cos \Delta \theta )^{2}}$.

Dividing throughout by ${\displaystyle (\Delta \theta )^{2}}$, we get

Passing to the limit as ${\displaystyle \Delta \theta }$ diminishes towards zero, we get^[4]

	${\displaystyle \left({\frac {ds}{d\theta }}\right)^{2}=\rho ^{2}+\left({\frac {d\rho }{d\theta }}\right)^{2}}$.
(30)	∴ ${\displaystyle {\frac {ds}{d\theta }}={\sqrt {\rho ^{2}+\left({\frac {d\rho }{d\theta }}\right)^{2}}}}$.
In the notation of differentials this becomes
(31)	${\displaystyle \ ds=\left[\rho ^{2}+\left({\frac {d\rho }{d\theta }}\right)^{2}\right]^{\frac {1}{2}}d\theta }$.

These relations between ${\displaystyle \rho }$ and the differentials ds, dp, and ${\displaystyle d\theta }$ are correctly represented by a right triangle whose hypotenuse is ds and whose sides are ${\displaystyle d\rho }$ and ${\displaystyle \rho d\theta }$. Then

and dividing by ${\displaystyle d\theta }$ gives (30).

Denoting by ${\displaystyle \psi }$ the angle between ${\displaystyle dp}$ and ${\displaystyle ds}$, we get at once

which is the same as (A), §67.

Illustrative Example 1. Find the differential of the arc of the circle ${\displaystyle x^{2}+y^{2}=r^{2}}$.

Solution. Differentiating, ${\displaystyle {\tfrac {dy}{dx}}=-{\tfrac {x}{y}}}$.

To find ds in terms of x we substitute in (27), giving

To find ds in terms of y we substitute in (28), giving

Illustrative Example 2. Find the differential of the arc of the cardioid ${\displaystyle \rho =a(l-\cos \theta )}$ in terms of ${\displaystyle \theta }$.

Solution. Differentiating, ${\displaystyle {\tfrac {d\rho }{d\theta }}=a\sin \theta }$

Substituting in (31), gives

Find the differential of arc in each of the following curves:

1. ${\displaystyle y^{2}=4x}$.	Ans.	${\displaystyle ds={\sqrt {\frac {1+x}{x}}}dx.}$
2. ${\displaystyle y=ax^{2}}$.		${\displaystyle ds={\sqrt {1+4a^{2}x^{2}}}dx}$.
3. ${\displaystyle y=x^{3}}$.		${\displaystyle ds={\sqrt {1+9x^{4}}}dx}$.
4. ${\displaystyle y^{3}=x^{2}}$.		${\displaystyle ds={\frac {1}{2}}{\sqrt {4+9y}}dy}$.
5. ${\displaystyle x^{\frac {2}{3}}+y^{\frac {2}{3}}=a^{\frac {2}{3}}}$.		${\displaystyle ds={\sqrt[{3}]{\frac {a}{y}}}dy}$.
6. ${\displaystyle b^{2}x^{2}+a^{2}y^{2}=a^{2}b^{2}}$.		${\displaystyle ds={\sqrt {\frac {a^{2}-e^{2}x^{2}}{a^{2}-x^{2}}}}dx}$.
HINT. ${\displaystyle e^{2}={\frac {a^{2}-b^{2}}{a^{2}}}}$.
7. ${\displaystyle e^{y}\cos x=1}$.		${\displaystyle ds=\sec \ x\ dx}$
8. ${\displaystyle \rho =a\cos \theta }$.		${\displaystyle ds=a\ d\theta }$
9. ${\displaystyle \rho ^{2}=a^{2}\cos 2\theta }$.		${\displaystyle ds={\sqrt {\sec 2\theta }}d\theta }$.
10. ${\displaystyle \rho =ae^{\theta \cot \alpha }}$.		${\displaystyle ds=\rho \csc \alpha d\theta }$.
11. ${\displaystyle \rho =a^{\theta }}$.		${\displaystyle ds=a^{\theta }{\sqrt {1+\log ^{2}a}}d\theta }$.
12. ${\displaystyle \rho =a\theta }$.		${\displaystyle ds={\frac {1}{a}}{\sqrt {a^{2}+\rho ^{2}}}d\rho }$.

13.	(a) ${\displaystyle x^{2}-y^{2}=a^{2}}$.	(h) ${\displaystyle x^{\frac {1}{2}}+y^{\frac {1}{2}}=a^{\frac {1}{2}}}$.
	(b) ${\displaystyle x^{2}=4ay}$.	(i) ${\displaystyle y^{2}=ax^{3}}$.
	(c) ${\displaystyle y=e^{x}+e^{-x}}$.	(j) ${\displaystyle y=\log x}$.
	(d) ${\displaystyle xy=a}$.	(k) ${\displaystyle 4x=y^{3}}$.
	(e) ${\displaystyle y=\log \sec x}$.	(l) ${\displaystyle \rho =a\sec ^{2}{\frac {\theta }{2}}}$.
	(f) ${\displaystyle \rho =2a\tan \theta \sin \theta }$.	(m) ${\displaystyle \rho =1+\sin \theta }$.
	(g) ${\displaystyle \rho =a\sec ^{3}{\frac {\theta }{3}}}$.	(n) ${\displaystyle \rho \theta =a}$.

92. Formulas for finding the differentials of functions. Since the differential of a function is its derivative multiplied by the differential of the independent variable, it follows at once that the formulas for finding differentials are the same as those for finding derivatives given in § 33, if we multiply each one by dx.

This gives us

I		${\displaystyle d(c)}$	${\displaystyle =0}$.
II		${\displaystyle d(x)}$	${\displaystyle =dx}$.
III		${\displaystyle d(u+v-w)}$	${\displaystyle =du+dv-dw}$.
IV		${\displaystyle d(cv)}$	${\displaystyle =cdv}$.
V		${\displaystyle d(uv)}$	${\displaystyle =udv+vdu}$.
VI		${\displaystyle d(v^{n})}$	${\displaystyle =nv^{n-1}dv.}$

VI	a	${\displaystyle d(x^{n})}$	${\displaystyle =nx^{n-1}dx}$.
VII		${\displaystyle d\left({\frac {u}{v}}\right)}$	${\displaystyle ={\frac {vdu-udv}{v^{2}}}}$.
VII	a	${\displaystyle d\left({\frac {u}{c}}\right)}$	${\displaystyle ={\frac {du}{c}}}$.
VIII		${\displaystyle d(log_{a}v)}$	${\displaystyle =\log _{a}e{\frac {dv}{v}}}$.
IX		${\displaystyle d(a^{v})}$	${\displaystyle =a^{v}\log adv}$.
IX	a	${\displaystyle d(e^{v})=}$	${\displaystyle e^{v}dv}$.
X		${\displaystyle d(u^{v})}$	${\displaystyle =vu^{v-1}du+\log u\cdot u^{v}\cdot dv}$.
XI		${\displaystyle d(\sin v)}$	${\displaystyle =\cos vdv}$.
XII		${\displaystyle d(\cos v)}$	${\displaystyle =-\sin vdv}$.
XIII		${\displaystyle d(\tan v)}$	${\displaystyle =\sec ^{2}vdv}$, etc.
XVIII		${\displaystyle d(\arcsin v)}$	${\displaystyle ={\frac {dv}{\sqrt {1-v^{2}}}}}$, etc.

The term "differentiation" also includes the operation of finding differentials.

In finding differentials the easiest way is to find the derivative as usual, and then multiply the result by dx.

Illustrative Example 1. Find the differential of

	${\displaystyle \ y}$	${\displaystyle ={\frac {x+3}{x^{2}+3}}}$
Solution.	${\displaystyle dy=d\left({\frac {x+3}{x^{2}+3}}\right)}$	${\displaystyle ={\frac {(x^{2}+3)d(x+3)-(x+3)d(x^{2}+3)}{(x^{2}+3)^{2}}}}$
	${\displaystyle ={\frac {(x^{2}+3)dx-(x+3)2xdx}{(x^{2}+3)^{2}}}}$	${\displaystyle ={\frac {(3-6x-x^{2})dx}{(x^{2}+3)^{2}}}}$, Ans.

Illustrative Example 2. Find dy from

	${\displaystyle b^{2}x^{2}-a^{2}y^{2}}$	${\displaystyle a^{2}b^{2}}$
Solution.	${\displaystyle 2b^{2}xdx-2a^{2}ydy}$	${\displaystyle 0}$.
	∴ ${\displaystyle dy}$	${\displaystyle ={\frac {b^{2}x}{a^{2}y}}dx}$. Ans.

Illustrative Example 3. Find dy from

	${\displaystyle \rho ^{2}}$	${\displaystyle =a^{2}\cos s\theta }$
Solution.	${\displaystyle 2\rho d\rho }$	${\displaystyle =-a^{2}\sin 2\theta \cdot 2d\theta }$.
	∴ ${\displaystyle d\rho }$	${\displaystyle =-{\frac {a^{2}\sin 2\theta }{\rho }}d\theta }$.

Illustrative Example 4. Find ${\displaystyle d[\arcsin(3t-4t^{3})]}$.

Solution. ${\displaystyle d[\arcsin(3t-4t^{3})]={\frac {d(3t-4t^{3})}{\sqrt {1-(3t-4t^{3})^{2}}}}={\frac {3dt}{\sqrt {1-t^{2}}}}}$. Ans. ​93. Successive differentials. As the differential of a function is in general also a function of the independent variable, we may deal with its differential. Consider the function

${\displaystyle \scriptstyle {y=f(x)}}$.