Quiz:Differentiation rules: Difference between revisions

Latest revision as of 17:04, 19 October 2011

Review the rules before or while attempting the quiz questions: [SHOW MORE]

For a full list, see Category:Differentiation rules.

Method for constructing new functions from old	In symbols	Derivative in terms of the old functions and their derivatives	Proof
pointwise sum	$f+g$ is the function $x\mapsto f(x)+g(x)$ $f_{1}+f_{2}+\dots +f_{n}$ is the function $x\mapsto f_{1}(x)+f_{2}(x)+\dots +f_{n}(x)$	Sum of the derivatives of the functions being added (the derivative of the sum is the sum of the derivatives) $\!f'+g'$ $\!f_{1}'+f_{2}'+\dots +f_{n}'$	differentiation is linear
pointwise difference	$f-g$ is the function $x\mapsto f(x)-g(x)$	Difference of the derivatives, i.e., $f'-g'$	differentiation is linear
scalar multiple by a constant	$af$ is the function $x\mapsto af(x)$ where $a$ is a real number	$x\mapsto af'(x)$	differentiation is linear
pointwise product	$f\cdot g$ (sometimes denoted $fg$ ) is the function $x\mapsto f(x)g(x)$ $f_{1}\cdot f_{2}\cdot \dots f_{n}$ (sometimes denoted $f_{1}f_{2}\dots f_{n}$ is the function $x\mapsto f_{1}(x)f_{2}(x)\dots f_{n}(x)$	For two functions, $x\mapsto f'(x)g(x)+f(x)g'(x)$ For multiple functions, $x\mapsto f_{1}'(x)f_{2}(x)\dots f_{n}(x)+f_{1}(x)f_{2}'(x)\dots f_{n}(x)+\dots +f_{1}(x)f_{2}(x)\dots f_{n}'(x)$	product rule for differentiation
pointwise quotient	$f/g$ is the function $x\mapsto f(x)/g(x)$	$x\mapsto {\frac {g(x)f'(x)-f(x)g'(x)}{(g(x))^{2}}}$	quotient rule for differentiation
composite of two functions	$f\circ g$ is the function $x\mapsto f(g(x))$	$x\mapsto f'(g(x))g'(x)$	chain rule for differentiation
inverse function of a one-one function	$f^{-1}$ sends $x$ to the unique $y$ such that $f(y)=x$	$\!{\frac {1}{f'(f^{-1}(x))}}$	inverse function theorem
piecewise definition	$f(x):=\left\lbrace {\begin{array}{rl}f_{1}(x),&x<c\\f_{2}(x),&c<x\\v,&x=c\end{array}}\right.$ where $f_{1},f_{2}$ can be extended to differentiable functions on all reals	$f'=f_{1}'$ to the left of $c$ and $f'=f_{2}'$ to the right of $c$ . At $c$ , $f$ is differentiable iff $f_{1}(c)=f_{2}(c)=v$ and $f_{1}'(c)=f_{2}'(c)$ .	differentiation rule for piecewise definition by interval

See also Category:Differentiation rules for a list of all the differentiation rules pages (including pages for higher derivatives, which are not in this table).

Qualitative and existential questions

Generic point computation questions

Predicting when things become zero

The questions here can be done in two ways. The first is to use the abstract differentiation rules to figure things out. The second is to actually determine the possibilities for the functions at hand, and then figure out what we can say about their sums, products, and composites.

@@ Line 90: / Line 90: @@
 <quiz display=simple>
-{Suppose <math>f,g</math> are everywhere differentiable functions on <math>\R</math> and <math>f' = g' = 0</math> everywhere. For which of the following functions can we ''not'' conclude that the derivative is zero everywhere?
+{Suppose <math>\! f,g</math> are everywhere differentiable functions on <math>\R</math> and <math>\! f' = g' = 0</math> everywhere. For which of the following functions can we ''not'' conclude that the derivative is zero everywhere?
 |type="()"}
-- <math>f + g</math>
+- <math>\! f + g</math>
 - <math>f \cdot g</math>
 - <math>f \circ g</math>
@@ Line 98: / Line 98: @@
 + None of the above, i.e., the derivative is necessarily zero everywhere for each of these functions
-{Suppose <math>f,g</math> are everywhere twice differentiable functions on <math>\R</math> and <math>f'' = g'' = 0</math> everywhere. For which of the following functions can we ''not'' conclude that the second derivative is zero everywhere?
+{Suppose <math>\! f,g</math> are everywhere twice differentiable functions on <math>\R</math> and <math>\! f'' = g'' = 0</math> everywhere. For which of the following functions can we ''not'' conclude that the second derivative is zero everywhere?
 |type="()"}
-- <math>f + g</math>
+- <math>\! f + g</math>
 + <math>f \cdot g</math>
 || <math>f</math> and <math>g</math> must both be either constant or linear functions. However, the product of two linear functions is quadratic and hence not linear. For instance <math>f(x) = x</math> and <math>g(x) = x</math> are examples.
@@ Line 107: / Line 107: @@
 - None of the above, i.e., the second derivative is necessarily zero everywhere for each of these functions
-{Suppose <math>f,g</math> are everywhere thrice differentiable functions on <math>\R</math> and <math>f''' = g''' = 0</math> everywhere. For which of the following functions can we ''definitively'' conclude that the third derivative is zero everywhere?
+{Suppose <math>\! f,g</math> are everywhere thrice differentiable functions on <math>\R</math> and <math>\! f''' = g''' = 0</math> everywhere. For which of the following functions can we ''definitively'' conclude that the third derivative is zero everywhere?
 |type="()"}
-+ <math>f + g</math>
++ <math>\! f + g</math>
 - <math>f \cdot g</math>
 || Both <math>f</math> and <math>g</math> are polynomials of degree at most 2, but their product need not be.

	The sum $f+g$ , i.e., the function $x\mapsto f(x)+g(x)$
	The difference $f-g$ , i.e., the function $x\mapsto f(x)-g(x)$
	The product $f\cdot g$ , i.e., the function $x\mapsto f(x)g(x)$
	The composite $f\circ g$ , i.e., the function $x\mapsto f(g(x))$
	None of the above, i.e., they are all guaranteed to be differentiable.

	The sum $f+g$ , i.e., the function $x\mapsto f(x)+g(x)$
	The difference $f-g$ , i.e., the function $x\mapsto f(x)-g(x)$
	The product $f\cdot g$ , i.e., the function $x\mapsto f(x)g(x)$
	The composite $f\circ g$ , i.e., the function $x\mapsto f(g(x))$
	None of the above, i.e., they are all guaranteed to be everywhere differentiable

	The sum $f+g$ , i.e., the function $x\mapsto f(x)+g(x)$
	The difference $f-g$ , i.e., the function $x\mapsto f(x)-g(x)$
	The product $f\cdot g$ , i.e., the function $x\mapsto f(x)g(x)$
	The composite $f\circ g$ , i.e., the function $x\mapsto f(g(x))$
	None of the above, i.e., they are all guaranteed to have a left hand derivative on all of $\mathbb {R}$

	The derivative of the sum of two functions is the sum of the derivatives of the functions.
	The derivative of the difference of two functions is the difference of the derivatives of the functions.
	The derivative of a constant times a function is the same constant times the derivative of the function.
	The derivative of the product of two functions is the product of the derivatives of the functions.
	None of the above, i.e., they are all valid as general rules.

	$f''\cdot g+f\cdot g''$
	$f''\cdot g+f'\cdot g'+f\cdot g''$
	$f''\cdot g+2f'\cdot g'+f\cdot g''$
	$f''\cdot g-f'\cdot g'+f\cdot g''$
	$f''\cdot g-2f'\cdot g'+f\cdot g''$

	$(f''\circ g)\cdot g''$
	$(f''\circ g)\cdot (f'\circ g')\cdot g''$
	$(f''\circ g)\cdot (f'\circ g')\cdot (f\circ g'')$
	$(f''\circ g)\cdot (g')^{2}+(f'\circ g)\cdot g''$
	$(f'\circ g')\cdot (f\circ g)+(f''\circ g'')$

	$f_{1}'\cdot f_{2}'\cdot f_{3}'$
	$f_{1}'\cdot f_{2}\cdot f_{3}+f_{1}\cdot f_{2}'\cdot f_{3}+f_{1}\cdot f_{2}\cdot f_{3}'$
	$f_{1}\cdot f_{2}'\cdot f_{3}'+f_{1}'\cdot f_{2}\cdot f_{3}'+f_{1}\cdot f_{2}\cdot f_{3}'$
	$f_{1}'\cdot f_{2}+f_{2}'\cdot f_{3}+f_{3}'\cdot f_{1}$
	$f_{1}''\cdot f_{2}'\cdot f_{3}$

	$(f_{1}'\circ f_{2}\circ f_{3})\cdot (f_{2}'\circ f_{3})\cdot f_{3}'$
	$(f_{1}'\cdot f_{2}\cdot f_{3})\circ (f_{2}'\cdot f_{3})\circ f_{3}'$
	$(f_{1}\circ f_{2}'\circ f_{3}')\cdot (f_{2}\circ f_{3}')\cdot f_{3}$
	$(f_{1}\cdot f_{2}'\cdot f_{3}')\circ (f_{2}\cdot f_{3}')\circ f_{3}$
	$f_{1}'\circ f_{2}'\circ f_{3}'$