Solve the differential equation $sin xfrac {dy}{dx}+(cos x)y=sin(x^2)$ [on hold]
$$sin xfrac {dy}{dx}+(cos x)y=sin(x^2)$$
$$frac {d}{dx} y sin x=sin(x^2)$$
$$ysin x=int sin(x^2)dx = -frac{1}{2x}cos(x^2)+C$$
$$y=-frac{cos(x^2)}{2xsin x}+frac {C}{sin x}$$
where C is constant
Is my answer correct?
differential-equations
edited 2 days ago
John Doe
10.6k11237
asked 2 days ago
MaggieMaggie
638
put on hold as off-topic by Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost yesterday
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost
If this question can be reworded to fit the rules in the help center, please edit the question.
add a comment |
$$sin xfrac {dy}{dx}+(cos x)y=sin(x^2)$$
$$frac {d}{dx} y sin x=sin(x^2)$$
$$ysin x=int sin(x^2)dx = -frac{1}{2x}cos(x^2)+C$$
$$y=-frac{cos(x^2)}{2xsin x}+frac {C}{sin x}$$
where C is constant
Is my answer correct?
differential-equations
edited 2 days ago
John Doe
10.6k11237
asked 2 days ago
MaggieMaggie
638
put on hold as off-topic by Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost yesterday
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost
If this question can be reworded to fit the rules in the help center, please edit the question.
1
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
1
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago
add a comment |
$$sin xfrac {dy}{dx}+(cos x)y=sin(x^2)$$
$$frac {d}{dx} y sin x=sin(x^2)$$
$$ysin x=int sin(x^2)dx = -frac{1}{2x}cos(x^2)+C$$
$$y=-frac{cos(x^2)}{2xsin x}+frac {C}{sin x}$$
where C is constant
Is my answer correct?
differential-equations
edited 2 days ago
John Doe
10.6k11237
asked 2 days ago
MaggieMaggie
638
$$sin xfrac {dy}{dx}+(cos x)y=sin(x^2)$$
$$frac {d}{dx} y sin x=sin(x^2)$$
$$ysin x=int sin(x^2)dx = -frac{1}{2x}cos(x^2)+C$$
$$y=-frac{cos(x^2)}{2xsin x}+frac {C}{sin x}$$
where C is constant
Is my answer correct?
differential-equations
differential-equations
edited 2 days ago
John Doe
10.6k11237
asked 2 days ago
MaggieMaggie
638
edited 2 days ago
John Doe
10.6k11237
asked 2 days ago
MaggieMaggie
638
edited 2 days ago
John Doe
10.6k11237
edited 2 days ago
John Doe
10.6k11237
edited 2 days ago
John Doe
10.6k11237
10.6k11237
asked 2 days ago
MaggieMaggie
638
asked 2 days ago
MaggieMaggie
638
asked 2 days ago
MaggieMaggie
638
638
put on hold as off-topic by Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost yesterday
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost
If this question can be reworded to fit the rules in the help center, please edit the question.
put on hold as off-topic by Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost yesterday
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Nosrati, metamorphy, Ali Caglayan, amWhy, Paul Frost
If this question can be reworded to fit the rules in the help center, please edit the question.
1
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
1
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago
add a comment |
1
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
1
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago
1
1
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
1
1
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago
add a comment |
2 Answers
2
active
oldest
votes
The answer given in your textbook is correct - you have tried to oversimplify it! You got to $$frac {d}{dx} y sin x=sin(x^2)$$Then you integrate both sides $$ysin x=intsin(x^2) mathrm dx+C$$Then you divide by $sin x$ to get $$y=frac{intsin(x^2)mathrm dx+C}{sin x}$$
as required.
There is no need to try and integrate the $sin(x^2)$ term, the way you did it is not correct. To check why this is the case, try to differentiate your result. If you had done it correctly, it would give you $sin(x^2)$. However, what it really gives you is $$sin(x^2)+frac{cos(x^2)}{2x^2}$$so there has been a mistake.
answered 2 days ago
John DoeJohn Doe
10.6k11237
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
add a comment |
The obeservation you have done is pretty good! You have correctly identified the LHS as an application of the product rule since
$$frac{mathrm d}{mathrm d x}left(ysin(x)right)=frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)$$
However, without trying to discourage you but the integration of $sin(x^2)$ is sadly speaking not that simple. You can check that you conjectured anti-derivative is wrong by simple taking the derivative. Thus, the whole solution is given by the following
$$begin{align*}
frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)&=sin(x^2)\
frac{mathrm d}{mathrm d x}left(ysin(x)right)&=sin(x^2)\
ysin(x)&=intsin(x^2)mathrm d x+C
end{align*}$$
$$therefore~y(x)~=~frac1{sin(x)}left(intsin(x^2)mathrm d x+Cright)$$
Adding some details concerning the still remaining integral: According to WolframAlpha the integral can be written in terms of the special function Fresnel Integral. For a straightforward "solution" you can expand the sine as a series and integrate termwise. On the other hand for definite integrals there are some value known, the I would say most important is
$$int_0^infty sin(x^2)mathrm d x~=~frac{sqrt{pi}}{2sqrt 2}$$
answered 2 days ago
mrtaurhomrtaurho
4,04921133
add a comment |
2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
The answer given in your textbook is correct - you have tried to oversimplify it! You got to $$frac {d}{dx} y sin x=sin(x^2)$$Then you integrate both sides $$ysin x=intsin(x^2) mathrm dx+C$$Then you divide by $sin x$ to get $$y=frac{intsin(x^2)mathrm dx+C}{sin x}$$
as required.
There is no need to try and integrate the $sin(x^2)$ term, the way you did it is not correct. To check why this is the case, try to differentiate your result. If you had done it correctly, it would give you $sin(x^2)$. However, what it really gives you is $$sin(x^2)+frac{cos(x^2)}{2x^2}$$so there has been a mistake.
answered 2 days ago
John DoeJohn Doe
10.6k11237
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
add a comment |
The answer given in your textbook is correct - you have tried to oversimplify it! You got to $$frac {d}{dx} y sin x=sin(x^2)$$Then you integrate both sides $$ysin x=intsin(x^2) mathrm dx+C$$Then you divide by $sin x$ to get $$y=frac{intsin(x^2)mathrm dx+C}{sin x}$$
as required.
There is no need to try and integrate the $sin(x^2)$ term, the way you did it is not correct. To check why this is the case, try to differentiate your result. If you had done it correctly, it would give you $sin(x^2)$. However, what it really gives you is $$sin(x^2)+frac{cos(x^2)}{2x^2}$$so there has been a mistake.
answered 2 days ago
John DoeJohn Doe
10.6k11237
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
add a comment |
The answer given in your textbook is correct - you have tried to oversimplify it! You got to $$frac {d}{dx} y sin x=sin(x^2)$$Then you integrate both sides $$ysin x=intsin(x^2) mathrm dx+C$$Then you divide by $sin x$ to get $$y=frac{intsin(x^2)mathrm dx+C}{sin x}$$
as required.
There is no need to try and integrate the $sin(x^2)$ term, the way you did it is not correct. To check why this is the case, try to differentiate your result. If you had done it correctly, it would give you $sin(x^2)$. However, what it really gives you is $$sin(x^2)+frac{cos(x^2)}{2x^2}$$so there has been a mistake.
answered 2 days ago
John DoeJohn Doe
10.6k11237
The answer given in your textbook is correct - you have tried to oversimplify it! You got to $$frac {d}{dx} y sin x=sin(x^2)$$Then you integrate both sides $$ysin x=intsin(x^2) mathrm dx+C$$Then you divide by $sin x$ to get $$y=frac{intsin(x^2)mathrm dx+C}{sin x}$$
as required.
There is no need to try and integrate the $sin(x^2)$ term, the way you did it is not correct. To check why this is the case, try to differentiate your result. If you had done it correctly, it would give you $sin(x^2)$. However, what it really gives you is $$sin(x^2)+frac{cos(x^2)}{2x^2}$$so there has been a mistake.
answered 2 days ago
John DoeJohn Doe
10.6k11237
answered 2 days ago
John DoeJohn Doe
10.6k11237
answered 2 days ago
John DoeJohn Doe
10.6k11237
answered 2 days ago
John DoeJohn Doe
10.6k11237
10.6k11237
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
add a comment |
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
Thanks! I will check my integral next time carefully. You help me a lot.
– Maggie
2 days ago
add a comment |
The obeservation you have done is pretty good! You have correctly identified the LHS as an application of the product rule since
$$frac{mathrm d}{mathrm d x}left(ysin(x)right)=frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)$$
However, without trying to discourage you but the integration of $sin(x^2)$ is sadly speaking not that simple. You can check that you conjectured anti-derivative is wrong by simple taking the derivative. Thus, the whole solution is given by the following
$$begin{align*}
frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)&=sin(x^2)\
frac{mathrm d}{mathrm d x}left(ysin(x)right)&=sin(x^2)\
ysin(x)&=intsin(x^2)mathrm d x+C
end{align*}$$
$$therefore~y(x)~=~frac1{sin(x)}left(intsin(x^2)mathrm d x+Cright)$$
Adding some details concerning the still remaining integral: According to WolframAlpha the integral can be written in terms of the special function Fresnel Integral. For a straightforward "solution" you can expand the sine as a series and integrate termwise. On the other hand for definite integrals there are some value known, the I would say most important is
$$int_0^infty sin(x^2)mathrm d x~=~frac{sqrt{pi}}{2sqrt 2}$$
answered 2 days ago
mrtaurhomrtaurho
4,04921133
add a comment |
The obeservation you have done is pretty good! You have correctly identified the LHS as an application of the product rule since
$$frac{mathrm d}{mathrm d x}left(ysin(x)right)=frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)$$
However, without trying to discourage you but the integration of $sin(x^2)$ is sadly speaking not that simple. You can check that you conjectured anti-derivative is wrong by simple taking the derivative. Thus, the whole solution is given by the following
$$begin{align*}
frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)&=sin(x^2)\
frac{mathrm d}{mathrm d x}left(ysin(x)right)&=sin(x^2)\
ysin(x)&=intsin(x^2)mathrm d x+C
end{align*}$$
$$therefore~y(x)~=~frac1{sin(x)}left(intsin(x^2)mathrm d x+Cright)$$
Adding some details concerning the still remaining integral: According to WolframAlpha the integral can be written in terms of the special function Fresnel Integral. For a straightforward "solution" you can expand the sine as a series and integrate termwise. On the other hand for definite integrals there are some value known, the I would say most important is
$$int_0^infty sin(x^2)mathrm d x~=~frac{sqrt{pi}}{2sqrt 2}$$
answered 2 days ago
mrtaurhomrtaurho
4,04921133
add a comment |
The obeservation you have done is pretty good! You have correctly identified the LHS as an application of the product rule since
$$frac{mathrm d}{mathrm d x}left(ysin(x)right)=frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)$$
However, without trying to discourage you but the integration of $sin(x^2)$ is sadly speaking not that simple. You can check that you conjectured anti-derivative is wrong by simple taking the derivative. Thus, the whole solution is given by the following
$$begin{align*}
frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)&=sin(x^2)\
frac{mathrm d}{mathrm d x}left(ysin(x)right)&=sin(x^2)\
ysin(x)&=intsin(x^2)mathrm d x+C
end{align*}$$
$$therefore~y(x)~=~frac1{sin(x)}left(intsin(x^2)mathrm d x+Cright)$$
Adding some details concerning the still remaining integral: According to WolframAlpha the integral can be written in terms of the special function Fresnel Integral. For a straightforward "solution" you can expand the sine as a series and integrate termwise. On the other hand for definite integrals there are some value known, the I would say most important is
$$int_0^infty sin(x^2)mathrm d x~=~frac{sqrt{pi}}{2sqrt 2}$$
answered 2 days ago
mrtaurhomrtaurho
4,04921133
The obeservation you have done is pretty good! You have correctly identified the LHS as an application of the product rule since
$$frac{mathrm d}{mathrm d x}left(ysin(x)right)=frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)$$
However, without trying to discourage you but the integration of $sin(x^2)$ is sadly speaking not that simple. You can check that you conjectured anti-derivative is wrong by simple taking the derivative. Thus, the whole solution is given by the following
$$begin{align*}
frac{mathrm d y}{mathrm d x}sin(x)+ycos(x)&=sin(x^2)\
frac{mathrm d}{mathrm d x}left(ysin(x)right)&=sin(x^2)\
ysin(x)&=intsin(x^2)mathrm d x+C
end{align*}$$
$$therefore~y(x)~=~frac1{sin(x)}left(intsin(x^2)mathrm d x+Cright)$$
Adding some details concerning the still remaining integral: According to WolframAlpha the integral can be written in terms of the special function Fresnel Integral. For a straightforward "solution" you can expand the sine as a series and integrate termwise. On the other hand for definite integrals there are some value known, the I would say most important is
$$int_0^infty sin(x^2)mathrm d x~=~frac{sqrt{pi}}{2sqrt 2}$$
answered 2 days ago
mrtaurhomrtaurho
4,04921133
answered 2 days ago
mrtaurhomrtaurho
4,04921133
answered 2 days ago
mrtaurhomrtaurho
4,04921133
answered 2 days ago
mrtaurhomrtaurho
4,04921133
4,04921133
add a comment |
add a comment |
1
You cannot integrate $sin(x^2)$ to get $-frac1{2x}cos(x^2)$! If you differentiate this result, you will not end up back at $sin(x^2)$. In fact, integrating $sin(x^2)$ is very hard, and probably requires some special functions. Where did you find this problem?
– John Doe
2 days ago
It is $sin(x^2)$. This question is in my textbook.
– Maggie
2 days ago
Maybe there is a typo. What is the result given by your textbook?
– Robert Z
2 days ago
The answer is $y=frac {int sin(x^2)dx+C}{sinx}$. I don't know why the constant C is there.
– Maggie
2 days ago
1
The constant $C$ is just a constant of integration. You could just include it in the integral if you really wanted, so I'd agree that it is not necessary to write there.
– John Doe
2 days ago