Finding maximum and minimum of $f(x)=x-2cos(x)$ Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)Local maximum and minimum helpFinding intervals using local min and max (in interval notation form)Find Maximum and Minimum at xFinding Maximum/Minimum of Trigonometric FunctionsFind the absolute minimum and maximum values of $f(theta) = cos theta$Composite Functions and DerivativesShowing the local maximum or minimum, while the function changes sign infinitely oftenfind maximum and minimum values of f on R bounded by ellipseFinding maximum volume and minimum volume of a rotated solidFinding the Maximum and Minimum Values of a Function in a Domain
Antler Helmet: Can it work?
When to stop saving and start investing?
Single word antonym of "flightless"
ListPlot join points by nearest neighbor rather than order
Is above average number of years spent on PhD considered a red flag in future academia or industry positions?
How much radiation do nuclear physics experiments expose researchers to nowadays?
Do I really need recursive chmod to restrict access to a folder?
How can players work together to take actions that are otherwise impossible?
Why does Python start at index 1 when iterating an array backwards?
How to motivate offshore teams and trust them to deliver?
What would be the ideal power source for a cybernetic eye?
The logistics of corpse disposal
How widely used is the term Treppenwitz? Is it something that most Germans know?
WAN encapsulation
Did Kevin spill real chili?
Is the Standard Deduction better than Itemized when both are the same amount?
Does the Giant Rocktopus have a Swim Speed?
Why is black pepper both grey and black?
How do I stop a creek from eroding my steep embankment?
What is a Meta algorithm?
Stars Make Stars
How to say 'striped' in Latin
Does surprise arrest existing movement?
Is there a Spanish version of "dot your i's and cross your t's" that includes the letter 'ñ'?
Finding maximum and minimum of $f(x)=x-2cos(x)$
Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)Local maximum and minimum helpFinding intervals using local min and max (in interval notation form)Find Maximum and Minimum at xFinding Maximum/Minimum of Trigonometric FunctionsFind the absolute minimum and maximum values of $f(theta) = cos theta$Composite Functions and DerivativesShowing the local maximum or minimum, while the function changes sign infinitely oftenfind maximum and minimum values of f on R bounded by ellipseFinding maximum volume and minimum volume of a rotated solidFinding the Maximum and Minimum Values of a Function in a Domain
$begingroup$
Finding maximum and minimum of $f(x)=x-2cos(x)$
I don't know how to proceed with this problem. The first derivative is $1+2sin(x)$. Set this equal $0$, one obtains $x = dfrac7pi6+2kpi$ and $x = dfrac11pi6+2kpi$. I know that maximum value of $1+2sin(x)=2$ and minimum $=-2$
What should I do next to determine whether these values are local minimum or maximum? Graphing this function on Desmos shows that it is monotonically increasing, but how do I show this via the first derivative test?
calculus
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
$endgroup$
|
show 2 more comments
$begingroup$
Finding maximum and minimum of $f(x)=x-2cos(x)$
I don't know how to proceed with this problem. The first derivative is $1+2sin(x)$. Set this equal $0$, one obtains $x = dfrac7pi6+2kpi$ and $x = dfrac11pi6+2kpi$. I know that maximum value of $1+2sin(x)=2$ and minimum $=-2$
What should I do next to determine whether these values are local minimum or maximum? Graphing this function on Desmos shows that it is monotonically increasing, but how do I show this via the first derivative test?
calculus
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
$endgroup$
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
5
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28
|
show 2 more comments
$begingroup$
Finding maximum and minimum of $f(x)=x-2cos(x)$
I don't know how to proceed with this problem. The first derivative is $1+2sin(x)$. Set this equal $0$, one obtains $x = dfrac7pi6+2kpi$ and $x = dfrac11pi6+2kpi$. I know that maximum value of $1+2sin(x)=2$ and minimum $=-2$
What should I do next to determine whether these values are local minimum or maximum? Graphing this function on Desmos shows that it is monotonically increasing, but how do I show this via the first derivative test?
calculus
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
$endgroup$
Finding maximum and minimum of $f(x)=x-2cos(x)$
I don't know how to proceed with this problem. The first derivative is $1+2sin(x)$. Set this equal $0$, one obtains $x = dfrac7pi6+2kpi$ and $x = dfrac11pi6+2kpi$. I know that maximum value of $1+2sin(x)=2$ and minimum $=-2$
What should I do next to determine whether these values are local minimum or maximum? Graphing this function on Desmos shows that it is monotonically increasing, but how do I show this via the first derivative test?
calculus
calculus
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
edited Mar 31 at 23:55
James Warthington
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
asked Mar 31 at 23:10
James WarthingtonJames Warthington
48929
48929
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
5
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28
|
show 2 more comments
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
5
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
5
5
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28
|
show 2 more comments
1 Answer
1
active
oldest
votes
$begingroup$
You have correctly found the critical points, that is, the points at which the first derivative is equal to zero. To determine the relative extrema, we have two options. We can apply the First Derivative Test or the Second Derivative Test.
First Derivative Test. Let $f$ be a function that is continuous on $[a, b]$ and differentiable on $(a, b)$ except possibly at a point $c$.
(a) If $f'(x) > 0$ for all $x < c$ and $f'(x) < 0$ for all $x > c$, then $f$ has a relative maximum at $c$.
(b) If $f'(x) < 0$ for all $x < c$ and $f'(x) > 0$ for all $x > c$, then $f$ has a relative minimum at $c$.
Second Derivative Test. If $f$ has a critical point $c$ and $f''$ exists in an open interval $(a, b)$ and
(a) if $f''$ is negative in $(a, b)$, then $f$ has a relative maximum at $c$;
(b) if $f''$ is positive in $(a, b)$, then $f$ has a relative minimum at $c$.
In this case, it is easier to apply the Second Derivative Test. We have
beginalign*
f(x) & = x - 2cos x\
f'(x) & = 1 + 2sin x\
f''(x) & = 2cos x
endalign*
As you determined, the critical points are
beginalign*
x & = frac7pi6 + 2kpi, k in mathbbZ\
x & = frac11pi6 + 2kpi, k in mathbbZ
endalign*
At the points $x = frac7pi6 + 2kpi, k in mathbbZ$, which lie in the third quadrant, $f''(x) = cos x < 0$, so the Second Derivative Test tells us these points are relative maxima. At the points $x = frac11pi6 + 2kpi, k in mathbbZ$, which lie in the fourth quadrant, $f''(x) = cos x > 0$, so the Second Derivative Test tells us these points are relative minima.
We get the same result if we apply the First Derivative Test. Since the sine function decreases from $0$ to $-1$ in the third quadrant, the first derivative
$f'(x) = 1 + 2sin x$ changes from positive to negative at the points $x = frac7pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative maxima. Since the sine function increases from $-1$ to $0$ in the fourth quadrant, the first derivative $f'(x) = 1 + 2sin x$ changes from negative to positive at the points $x = frac11pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative minima.
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
$endgroup$
add a comment |
Your Answer
StackExchange.ready(function()
var channelOptions =
tags: "".split(" "),
id: "69"
;
initTagRenderer("".split(" "), "".split(" "), channelOptions);
StackExchange.using("externalEditor", function()
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled)
StackExchange.using("snippets", function()
createEditor();
);
else
createEditor();
);
function createEditor()
StackExchange.prepareEditor(
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: true,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: 10,
bindNavPrevention: true,
postfix: "",
imageUploader:
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
,
noCode: true, onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
);
);
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3170001%2ffinding-maximum-and-minimum-of-fx-x-2-cosx%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
You have correctly found the critical points, that is, the points at which the first derivative is equal to zero. To determine the relative extrema, we have two options. We can apply the First Derivative Test or the Second Derivative Test.
First Derivative Test. Let $f$ be a function that is continuous on $[a, b]$ and differentiable on $(a, b)$ except possibly at a point $c$.
(a) If $f'(x) > 0$ for all $x < c$ and $f'(x) < 0$ for all $x > c$, then $f$ has a relative maximum at $c$.
(b) If $f'(x) < 0$ for all $x < c$ and $f'(x) > 0$ for all $x > c$, then $f$ has a relative minimum at $c$.
Second Derivative Test. If $f$ has a critical point $c$ and $f''$ exists in an open interval $(a, b)$ and
(a) if $f''$ is negative in $(a, b)$, then $f$ has a relative maximum at $c$;
(b) if $f''$ is positive in $(a, b)$, then $f$ has a relative minimum at $c$.
In this case, it is easier to apply the Second Derivative Test. We have
beginalign*
f(x) & = x - 2cos x\
f'(x) & = 1 + 2sin x\
f''(x) & = 2cos x
endalign*
As you determined, the critical points are
beginalign*
x & = frac7pi6 + 2kpi, k in mathbbZ\
x & = frac11pi6 + 2kpi, k in mathbbZ
endalign*
At the points $x = frac7pi6 + 2kpi, k in mathbbZ$, which lie in the third quadrant, $f''(x) = cos x < 0$, so the Second Derivative Test tells us these points are relative maxima. At the points $x = frac11pi6 + 2kpi, k in mathbbZ$, which lie in the fourth quadrant, $f''(x) = cos x > 0$, so the Second Derivative Test tells us these points are relative minima.
We get the same result if we apply the First Derivative Test. Since the sine function decreases from $0$ to $-1$ in the third quadrant, the first derivative
$f'(x) = 1 + 2sin x$ changes from positive to negative at the points $x = frac7pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative maxima. Since the sine function increases from $-1$ to $0$ in the fourth quadrant, the first derivative $f'(x) = 1 + 2sin x$ changes from negative to positive at the points $x = frac11pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative minima.
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
$endgroup$
add a comment |
$begingroup$
You have correctly found the critical points, that is, the points at which the first derivative is equal to zero. To determine the relative extrema, we have two options. We can apply the First Derivative Test or the Second Derivative Test.
First Derivative Test. Let $f$ be a function that is continuous on $[a, b]$ and differentiable on $(a, b)$ except possibly at a point $c$.
(a) If $f'(x) > 0$ for all $x < c$ and $f'(x) < 0$ for all $x > c$, then $f$ has a relative maximum at $c$.
(b) If $f'(x) < 0$ for all $x < c$ and $f'(x) > 0$ for all $x > c$, then $f$ has a relative minimum at $c$.
Second Derivative Test. If $f$ has a critical point $c$ and $f''$ exists in an open interval $(a, b)$ and
(a) if $f''$ is negative in $(a, b)$, then $f$ has a relative maximum at $c$;
(b) if $f''$ is positive in $(a, b)$, then $f$ has a relative minimum at $c$.
In this case, it is easier to apply the Second Derivative Test. We have
beginalign*
f(x) & = x - 2cos x\
f'(x) & = 1 + 2sin x\
f''(x) & = 2cos x
endalign*
As you determined, the critical points are
beginalign*
x & = frac7pi6 + 2kpi, k in mathbbZ\
x & = frac11pi6 + 2kpi, k in mathbbZ
endalign*
At the points $x = frac7pi6 + 2kpi, k in mathbbZ$, which lie in the third quadrant, $f''(x) = cos x < 0$, so the Second Derivative Test tells us these points are relative maxima. At the points $x = frac11pi6 + 2kpi, k in mathbbZ$, which lie in the fourth quadrant, $f''(x) = cos x > 0$, so the Second Derivative Test tells us these points are relative minima.
We get the same result if we apply the First Derivative Test. Since the sine function decreases from $0$ to $-1$ in the third quadrant, the first derivative
$f'(x) = 1 + 2sin x$ changes from positive to negative at the points $x = frac7pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative maxima. Since the sine function increases from $-1$ to $0$ in the fourth quadrant, the first derivative $f'(x) = 1 + 2sin x$ changes from negative to positive at the points $x = frac11pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative minima.
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
$endgroup$
add a comment |
$begingroup$
You have correctly found the critical points, that is, the points at which the first derivative is equal to zero. To determine the relative extrema, we have two options. We can apply the First Derivative Test or the Second Derivative Test.
First Derivative Test. Let $f$ be a function that is continuous on $[a, b]$ and differentiable on $(a, b)$ except possibly at a point $c$.
(a) If $f'(x) > 0$ for all $x < c$ and $f'(x) < 0$ for all $x > c$, then $f$ has a relative maximum at $c$.
(b) If $f'(x) < 0$ for all $x < c$ and $f'(x) > 0$ for all $x > c$, then $f$ has a relative minimum at $c$.
Second Derivative Test. If $f$ has a critical point $c$ and $f''$ exists in an open interval $(a, b)$ and
(a) if $f''$ is negative in $(a, b)$, then $f$ has a relative maximum at $c$;
(b) if $f''$ is positive in $(a, b)$, then $f$ has a relative minimum at $c$.
In this case, it is easier to apply the Second Derivative Test. We have
beginalign*
f(x) & = x - 2cos x\
f'(x) & = 1 + 2sin x\
f''(x) & = 2cos x
endalign*
As you determined, the critical points are
beginalign*
x & = frac7pi6 + 2kpi, k in mathbbZ\
x & = frac11pi6 + 2kpi, k in mathbbZ
endalign*
At the points $x = frac7pi6 + 2kpi, k in mathbbZ$, which lie in the third quadrant, $f''(x) = cos x < 0$, so the Second Derivative Test tells us these points are relative maxima. At the points $x = frac11pi6 + 2kpi, k in mathbbZ$, which lie in the fourth quadrant, $f''(x) = cos x > 0$, so the Second Derivative Test tells us these points are relative minima.
We get the same result if we apply the First Derivative Test. Since the sine function decreases from $0$ to $-1$ in the third quadrant, the first derivative
$f'(x) = 1 + 2sin x$ changes from positive to negative at the points $x = frac7pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative maxima. Since the sine function increases from $-1$ to $0$ in the fourth quadrant, the first derivative $f'(x) = 1 + 2sin x$ changes from negative to positive at the points $x = frac11pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative minima.
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
$endgroup$
You have correctly found the critical points, that is, the points at which the first derivative is equal to zero. To determine the relative extrema, we have two options. We can apply the First Derivative Test or the Second Derivative Test.
First Derivative Test. Let $f$ be a function that is continuous on $[a, b]$ and differentiable on $(a, b)$ except possibly at a point $c$.
(a) If $f'(x) > 0$ for all $x < c$ and $f'(x) < 0$ for all $x > c$, then $f$ has a relative maximum at $c$.
(b) If $f'(x) < 0$ for all $x < c$ and $f'(x) > 0$ for all $x > c$, then $f$ has a relative minimum at $c$.
Second Derivative Test. If $f$ has a critical point $c$ and $f''$ exists in an open interval $(a, b)$ and
(a) if $f''$ is negative in $(a, b)$, then $f$ has a relative maximum at $c$;
(b) if $f''$ is positive in $(a, b)$, then $f$ has a relative minimum at $c$.
In this case, it is easier to apply the Second Derivative Test. We have
beginalign*
f(x) & = x - 2cos x\
f'(x) & = 1 + 2sin x\
f''(x) & = 2cos x
endalign*
As you determined, the critical points are
beginalign*
x & = frac7pi6 + 2kpi, k in mathbbZ\
x & = frac11pi6 + 2kpi, k in mathbbZ
endalign*
At the points $x = frac7pi6 + 2kpi, k in mathbbZ$, which lie in the third quadrant, $f''(x) = cos x < 0$, so the Second Derivative Test tells us these points are relative maxima. At the points $x = frac11pi6 + 2kpi, k in mathbbZ$, which lie in the fourth quadrant, $f''(x) = cos x > 0$, so the Second Derivative Test tells us these points are relative minima.
We get the same result if we apply the First Derivative Test. Since the sine function decreases from $0$ to $-1$ in the third quadrant, the first derivative
$f'(x) = 1 + 2sin x$ changes from positive to negative at the points $x = frac7pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative maxima. Since the sine function increases from $-1$ to $0$ in the fourth quadrant, the first derivative $f'(x) = 1 + 2sin x$ changes from negative to positive at the points $x = frac11pi6 + 2kpi, k in mathbbZ$, so the First Derivative Test tells us that these points are relative minima.
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
answered Apr 1 at 10:04
N. F. TaussigN. F. Taussig
45.3k103358
45.3k103358
add a comment |
add a comment |
Thanks for contributing an answer to Mathematics Stack Exchange!
- Please be sure to answer the question. Provide details and share your research!
But avoid …
- Asking for help, clarification, or responding to other answers.
- Making statements based on opinion; back them up with references or personal experience.
Use MathJax to format equations. MathJax reference.
To learn more, see our tips on writing great answers.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3170001%2ffinding-maximum-and-minimum-of-fx-x-2-cosx%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
$begingroup$
Take the second derivative.
$endgroup$
– John Douma
Mar 31 at 23:13
$begingroup$
@John Douma Should I insert test points? The first derivative is a periodic function, so I don't know how to determine its signs? Usually, with polynomials, you can judge the sign within each interval of maximum and minimum. In this case, I don't know how to work it out.
$endgroup$
– James Warthington
Mar 31 at 23:17
5
$begingroup$
This function is not monotonic. since its slope varies between $-1$ and $3$. It has infinitely many local max and min. You can use either the sign of $f'$ around them or the sign of $f''$ at the points themselves.
$endgroup$
– GReyes
Mar 31 at 23:18
$begingroup$
You take the second derivative at the points where the first derivative is $0$. This tells you the concavity which tells you whether you have a minimum or maximum.
$endgroup$
– John Douma
Mar 31 at 23:18
$begingroup$
@John Douma The second derivative is $2cos(x)$, what should I do next? Set this derivative = 0?
$endgroup$
– James Warthington
Mar 31 at 23:28