Confusion about implicit differentiation $frac{dy}{dx}$












2














Today I learnt about implicit differentiation using this:



$frac{d}{dx}(f)$ = $frac{df}{dy} times frac{dy}{dx}$



I don't understand when doing implicit differentiation how the d/dy part works for y terms:



$frac{d(y^2)}{dx} = frac{d(y^2)}{dy}timesfrac{dy}{dx}=2yfrac{dy}{dx}$



Why is the derivative of $y^2$ with respect to $y$, $2y$? Do you assume it's a function of something else?
And similarly if you apply this same formula to an $x$ term (even though its not needed) you get:



$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$



How does that simplify to the $2x$ I know it is?



Thanks










share|cite|improve this question
























  • What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
    – A.Γ.
    Nov 26 at 18:14












  • @A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
    – DevinJC
    Nov 26 at 18:16












  • If $y=x^2$ it still works perfectly.
    – A.Γ.
    Nov 26 at 18:18
















2














Today I learnt about implicit differentiation using this:



$frac{d}{dx}(f)$ = $frac{df}{dy} times frac{dy}{dx}$



I don't understand when doing implicit differentiation how the d/dy part works for y terms:



$frac{d(y^2)}{dx} = frac{d(y^2)}{dy}timesfrac{dy}{dx}=2yfrac{dy}{dx}$



Why is the derivative of $y^2$ with respect to $y$, $2y$? Do you assume it's a function of something else?
And similarly if you apply this same formula to an $x$ term (even though its not needed) you get:



$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$



How does that simplify to the $2x$ I know it is?



Thanks










share|cite|improve this question
























  • What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
    – A.Γ.
    Nov 26 at 18:14












  • @A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
    – DevinJC
    Nov 26 at 18:16












  • If $y=x^2$ it still works perfectly.
    – A.Γ.
    Nov 26 at 18:18














2












2








2







Today I learnt about implicit differentiation using this:



$frac{d}{dx}(f)$ = $frac{df}{dy} times frac{dy}{dx}$



I don't understand when doing implicit differentiation how the d/dy part works for y terms:



$frac{d(y^2)}{dx} = frac{d(y^2)}{dy}timesfrac{dy}{dx}=2yfrac{dy}{dx}$



Why is the derivative of $y^2$ with respect to $y$, $2y$? Do you assume it's a function of something else?
And similarly if you apply this same formula to an $x$ term (even though its not needed) you get:



$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$



How does that simplify to the $2x$ I know it is?



Thanks










share|cite|improve this question















Today I learnt about implicit differentiation using this:



$frac{d}{dx}(f)$ = $frac{df}{dy} times frac{dy}{dx}$



I don't understand when doing implicit differentiation how the d/dy part works for y terms:



$frac{d(y^2)}{dx} = frac{d(y^2)}{dy}timesfrac{dy}{dx}=2yfrac{dy}{dx}$



Why is the derivative of $y^2$ with respect to $y$, $2y$? Do you assume it's a function of something else?
And similarly if you apply this same formula to an $x$ term (even though its not needed) you get:



$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$



How does that simplify to the $2x$ I know it is?



Thanks







differential-equations implicit-differentiation






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share|cite|improve this question













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edited Nov 26 at 18:56









Wesley Strik

1,494422




1,494422










asked Nov 26 at 18:10









DevinJC

937




937












  • What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
    – A.Γ.
    Nov 26 at 18:14












  • @A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
    – DevinJC
    Nov 26 at 18:16












  • If $y=x^2$ it still works perfectly.
    – A.Γ.
    Nov 26 at 18:18


















  • What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
    – A.Γ.
    Nov 26 at 18:14












  • @A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
    – DevinJC
    Nov 26 at 18:16












  • If $y=x^2$ it still works perfectly.
    – A.Γ.
    Nov 26 at 18:18
















What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
– A.Γ.
Nov 26 at 18:14






What is $y$ in your last differentiation? Take $y=x$ then it works perfectly.
– A.Γ.
Nov 26 at 18:14














@A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
– DevinJC
Nov 26 at 18:16






@A.Γ. Its just an example, I'm not really sure, I thought of it as $y=x^2$ and $y=f$and did it using the formula at the top.
– DevinJC
Nov 26 at 18:16














If $y=x^2$ it still works perfectly.
– A.Γ.
Nov 26 at 18:18




If $y=x^2$ it still works perfectly.
– A.Γ.
Nov 26 at 18:18










3 Answers
3






active

oldest

votes


















2














Yes, here they assume that $y$ is a function of something else.



Whenever we apply implicit differentiation like with $frac{dy^2(x)}{dx}$, we sort of first forget it is a function of something else, say $x$, we just derive it using the chain rule and then we need to correct for this via the familiar additional factor:



$$ frac{d y^2(x)}{d x} =2 y(x) cdotfrac{d y(x) }{dx}$$



Actually implict differentiation often boils down to just using the chain rule. Notice that if $y$ is not a function of $x$, we get that $frac{ d y}{dx} =0$ and the equation just reads $0=0$.



For your second case where you state:
$$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$$
We could call $y=x^2$ because you really need to tell the reader what this new variable $y$ is in relation to the old variable $x$, else the derivative could be anything. We then get:
$$ frac{dy}{dx} =frac{dy}{dy}timesfrac{d x^2 }{dx}= 1 cdot 2x $$



In general we use implicit differentiation when there is some complicated variable dependence and you cannot directly express some variable explicitly in terms of the other. An example of such an equation would be:
$$t+ t^2 + 3z^2 + z^3 = 6$$
Using implicit differentiation we could construct the tangent line for $(t,z)=(1,1)$, we will derive both sides with respect to $t$, we do not know if $z$ is is a function of $t$ so we need to use the chain rule.



We would get:
$$1+ 2t + 6z frac{dz}{dt} + 3 z^2 frac{dz}{dt} = 0$$
Now we plug in the value at (1,1) to get:
$$1+ 2 + 6 frac{dz}{dt} + 3 frac{dz}{dt} = 0$$
Or after rearranging:
$$9 frac{dz}{dt} = -3 rightarrow frac{dz}{dt}= -frac{1}{3}$$
We get the tangent line $z= -frac{1}{3}(t-1) +1$






share|cite|improve this answer























  • Thanks a lot this really helped.
    – DevinJC
    Nov 26 at 18:35










  • any time ;) we're all here to help
    – Wesley Strik
    Nov 26 at 18:36










  • Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
    – DevinJC
    Nov 27 at 10:10












  • Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
    – Wesley Strik
    Nov 27 at 12:53






  • 1




    It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
    – Wesley Strik
    Nov 27 at 14:30





















4














You implicitly utilize the formula of derivative of a composite functions or a chain rule:
$$
f = y(x)^2, qquadfrac{df}{dx}=frac{d(y^2)}{dx},\
f=g(y(x)),qquad g(y)=y^2,\
frac{d}{dx}g(y(x))=frac{dg(y(x))}{dy}frac{dy(x)}{dx}=(2y(x))frac{dy}{dx}
$$






share|cite|improve this answer





























    2














    The derivative of $y^2$ with respect to $y$ is $2y$ because of the definition of derivative:
    $$lim_{h to 0} frac{(y+h)^2-y^2}{h} = 2y.$$



    In the last expression you write
    $$frac{d(x^2)}{dx} = frac{d(x^2)}{dy}frac{dy}{dx}$$
    but this is meaningful only when $x$ is a function of $y$. So assume $x = f(y)$. Then, by the first equation you mention in the question, the right hand side is
    $$frac{d(f^2)}{dy}frac{dy}{dx} = 2f(y)f'(y)frac{dy}{dx} = 2xf'(y)frac{dy}{dx} = 2xfrac{dx}{dy}frac{dy}{dx} = 2xfrac{dx}{dx} = 2x.$$






    share|cite|improve this answer





















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      3 Answers
      3






      active

      oldest

      votes








      3 Answers
      3






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes









      2














      Yes, here they assume that $y$ is a function of something else.



      Whenever we apply implicit differentiation like with $frac{dy^2(x)}{dx}$, we sort of first forget it is a function of something else, say $x$, we just derive it using the chain rule and then we need to correct for this via the familiar additional factor:



      $$ frac{d y^2(x)}{d x} =2 y(x) cdotfrac{d y(x) }{dx}$$



      Actually implict differentiation often boils down to just using the chain rule. Notice that if $y$ is not a function of $x$, we get that $frac{ d y}{dx} =0$ and the equation just reads $0=0$.



      For your second case where you state:
      $$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$$
      We could call $y=x^2$ because you really need to tell the reader what this new variable $y$ is in relation to the old variable $x$, else the derivative could be anything. We then get:
      $$ frac{dy}{dx} =frac{dy}{dy}timesfrac{d x^2 }{dx}= 1 cdot 2x $$



      In general we use implicit differentiation when there is some complicated variable dependence and you cannot directly express some variable explicitly in terms of the other. An example of such an equation would be:
      $$t+ t^2 + 3z^2 + z^3 = 6$$
      Using implicit differentiation we could construct the tangent line for $(t,z)=(1,1)$, we will derive both sides with respect to $t$, we do not know if $z$ is is a function of $t$ so we need to use the chain rule.



      We would get:
      $$1+ 2t + 6z frac{dz}{dt} + 3 z^2 frac{dz}{dt} = 0$$
      Now we plug in the value at (1,1) to get:
      $$1+ 2 + 6 frac{dz}{dt} + 3 frac{dz}{dt} = 0$$
      Or after rearranging:
      $$9 frac{dz}{dt} = -3 rightarrow frac{dz}{dt}= -frac{1}{3}$$
      We get the tangent line $z= -frac{1}{3}(t-1) +1$






      share|cite|improve this answer























      • Thanks a lot this really helped.
        – DevinJC
        Nov 26 at 18:35










      • any time ;) we're all here to help
        – Wesley Strik
        Nov 26 at 18:36










      • Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
        – DevinJC
        Nov 27 at 10:10












      • Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
        – Wesley Strik
        Nov 27 at 12:53






      • 1




        It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
        – Wesley Strik
        Nov 27 at 14:30


















      2














      Yes, here they assume that $y$ is a function of something else.



      Whenever we apply implicit differentiation like with $frac{dy^2(x)}{dx}$, we sort of first forget it is a function of something else, say $x$, we just derive it using the chain rule and then we need to correct for this via the familiar additional factor:



      $$ frac{d y^2(x)}{d x} =2 y(x) cdotfrac{d y(x) }{dx}$$



      Actually implict differentiation often boils down to just using the chain rule. Notice that if $y$ is not a function of $x$, we get that $frac{ d y}{dx} =0$ and the equation just reads $0=0$.



      For your second case where you state:
      $$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$$
      We could call $y=x^2$ because you really need to tell the reader what this new variable $y$ is in relation to the old variable $x$, else the derivative could be anything. We then get:
      $$ frac{dy}{dx} =frac{dy}{dy}timesfrac{d x^2 }{dx}= 1 cdot 2x $$



      In general we use implicit differentiation when there is some complicated variable dependence and you cannot directly express some variable explicitly in terms of the other. An example of such an equation would be:
      $$t+ t^2 + 3z^2 + z^3 = 6$$
      Using implicit differentiation we could construct the tangent line for $(t,z)=(1,1)$, we will derive both sides with respect to $t$, we do not know if $z$ is is a function of $t$ so we need to use the chain rule.



      We would get:
      $$1+ 2t + 6z frac{dz}{dt} + 3 z^2 frac{dz}{dt} = 0$$
      Now we plug in the value at (1,1) to get:
      $$1+ 2 + 6 frac{dz}{dt} + 3 frac{dz}{dt} = 0$$
      Or after rearranging:
      $$9 frac{dz}{dt} = -3 rightarrow frac{dz}{dt}= -frac{1}{3}$$
      We get the tangent line $z= -frac{1}{3}(t-1) +1$






      share|cite|improve this answer























      • Thanks a lot this really helped.
        – DevinJC
        Nov 26 at 18:35










      • any time ;) we're all here to help
        – Wesley Strik
        Nov 26 at 18:36










      • Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
        – DevinJC
        Nov 27 at 10:10












      • Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
        – Wesley Strik
        Nov 27 at 12:53






      • 1




        It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
        – Wesley Strik
        Nov 27 at 14:30
















      2












      2








      2






      Yes, here they assume that $y$ is a function of something else.



      Whenever we apply implicit differentiation like with $frac{dy^2(x)}{dx}$, we sort of first forget it is a function of something else, say $x$, we just derive it using the chain rule and then we need to correct for this via the familiar additional factor:



      $$ frac{d y^2(x)}{d x} =2 y(x) cdotfrac{d y(x) }{dx}$$



      Actually implict differentiation often boils down to just using the chain rule. Notice that if $y$ is not a function of $x$, we get that $frac{ d y}{dx} =0$ and the equation just reads $0=0$.



      For your second case where you state:
      $$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$$
      We could call $y=x^2$ because you really need to tell the reader what this new variable $y$ is in relation to the old variable $x$, else the derivative could be anything. We then get:
      $$ frac{dy}{dx} =frac{dy}{dy}timesfrac{d x^2 }{dx}= 1 cdot 2x $$



      In general we use implicit differentiation when there is some complicated variable dependence and you cannot directly express some variable explicitly in terms of the other. An example of such an equation would be:
      $$t+ t^2 + 3z^2 + z^3 = 6$$
      Using implicit differentiation we could construct the tangent line for $(t,z)=(1,1)$, we will derive both sides with respect to $t$, we do not know if $z$ is is a function of $t$ so we need to use the chain rule.



      We would get:
      $$1+ 2t + 6z frac{dz}{dt} + 3 z^2 frac{dz}{dt} = 0$$
      Now we plug in the value at (1,1) to get:
      $$1+ 2 + 6 frac{dz}{dt} + 3 frac{dz}{dt} = 0$$
      Or after rearranging:
      $$9 frac{dz}{dt} = -3 rightarrow frac{dz}{dt}= -frac{1}{3}$$
      We get the tangent line $z= -frac{1}{3}(t-1) +1$






      share|cite|improve this answer














      Yes, here they assume that $y$ is a function of something else.



      Whenever we apply implicit differentiation like with $frac{dy^2(x)}{dx}$, we sort of first forget it is a function of something else, say $x$, we just derive it using the chain rule and then we need to correct for this via the familiar additional factor:



      $$ frac{d y^2(x)}{d x} =2 y(x) cdotfrac{d y(x) }{dx}$$



      Actually implict differentiation often boils down to just using the chain rule. Notice that if $y$ is not a function of $x$, we get that $frac{ d y}{dx} =0$ and the equation just reads $0=0$.



      For your second case where you state:
      $$frac{d(x^2)}{dx} =frac{d(x^2)}{dy}timesfrac{dy}{dx}$$
      We could call $y=x^2$ because you really need to tell the reader what this new variable $y$ is in relation to the old variable $x$, else the derivative could be anything. We then get:
      $$ frac{dy}{dx} =frac{dy}{dy}timesfrac{d x^2 }{dx}= 1 cdot 2x $$



      In general we use implicit differentiation when there is some complicated variable dependence and you cannot directly express some variable explicitly in terms of the other. An example of such an equation would be:
      $$t+ t^2 + 3z^2 + z^3 = 6$$
      Using implicit differentiation we could construct the tangent line for $(t,z)=(1,1)$, we will derive both sides with respect to $t$, we do not know if $z$ is is a function of $t$ so we need to use the chain rule.



      We would get:
      $$1+ 2t + 6z frac{dz}{dt} + 3 z^2 frac{dz}{dt} = 0$$
      Now we plug in the value at (1,1) to get:
      $$1+ 2 + 6 frac{dz}{dt} + 3 frac{dz}{dt} = 0$$
      Or after rearranging:
      $$9 frac{dz}{dt} = -3 rightarrow frac{dz}{dt}= -frac{1}{3}$$
      We get the tangent line $z= -frac{1}{3}(t-1) +1$







      share|cite|improve this answer














      share|cite|improve this answer



      share|cite|improve this answer








      edited Nov 27 at 12:56


























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      WesleyGroupshaveFeelingsToo













      • Thanks a lot this really helped.
        – DevinJC
        Nov 26 at 18:35










      • any time ;) we're all here to help
        – Wesley Strik
        Nov 26 at 18:36










      • Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
        – DevinJC
        Nov 27 at 10:10












      • Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
        – Wesley Strik
        Nov 27 at 12:53






      • 1




        It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
        – Wesley Strik
        Nov 27 at 14:30




















      • Thanks a lot this really helped.
        – DevinJC
        Nov 26 at 18:35










      • any time ;) we're all here to help
        – Wesley Strik
        Nov 26 at 18:36










      • Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
        – DevinJC
        Nov 27 at 10:10












      • Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
        – Wesley Strik
        Nov 27 at 12:53






      • 1




        It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
        – Wesley Strik
        Nov 27 at 14:30


















      Thanks a lot this really helped.
      – DevinJC
      Nov 26 at 18:35




      Thanks a lot this really helped.
      – DevinJC
      Nov 26 at 18:35












      any time ;) we're all here to help
      – Wesley Strik
      Nov 26 at 18:36




      any time ;) we're all here to help
      – Wesley Strik
      Nov 26 at 18:36












      Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
      – DevinJC
      Nov 27 at 10:10






      Hello, I just saw your edit. why dont the $frac{dy}{dx}$ terms cancel out for the y terms as the $ frac{dx}{dy}$ terms for the x terms. Or do we just not do that otherwise we can't rearrange for what we want ($frac{dy/dx}$)
      – DevinJC
      Nov 27 at 10:10














      Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
      – Wesley Strik
      Nov 27 at 12:53




      Maybe I should use different letters to make clear that $y$ is not always equal to $x^2$
      – Wesley Strik
      Nov 27 at 12:53




      1




      1




      It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
      – Wesley Strik
      Nov 27 at 14:30






      It automatically IS, because the function is a relation between $x$ and $y$, but we only derive with respect to $x$. If you would use the chain rule like this for $X=x$: $$ frac{d}{dx} (X(x)^2)= 2X cdot frac{dx}{dx}=2X=2x$$ I think you get what you mean by using the chain rule for a variable you don't need to use it for. Here I mean that $X$ is a function of $x$ (clearly).
      – Wesley Strik
      Nov 27 at 14:30













      4














      You implicitly utilize the formula of derivative of a composite functions or a chain rule:
      $$
      f = y(x)^2, qquadfrac{df}{dx}=frac{d(y^2)}{dx},\
      f=g(y(x)),qquad g(y)=y^2,\
      frac{d}{dx}g(y(x))=frac{dg(y(x))}{dy}frac{dy(x)}{dx}=(2y(x))frac{dy}{dx}
      $$






      share|cite|improve this answer


























        4














        You implicitly utilize the formula of derivative of a composite functions or a chain rule:
        $$
        f = y(x)^2, qquadfrac{df}{dx}=frac{d(y^2)}{dx},\
        f=g(y(x)),qquad g(y)=y^2,\
        frac{d}{dx}g(y(x))=frac{dg(y(x))}{dy}frac{dy(x)}{dx}=(2y(x))frac{dy}{dx}
        $$






        share|cite|improve this answer
























          4












          4








          4






          You implicitly utilize the formula of derivative of a composite functions or a chain rule:
          $$
          f = y(x)^2, qquadfrac{df}{dx}=frac{d(y^2)}{dx},\
          f=g(y(x)),qquad g(y)=y^2,\
          frac{d}{dx}g(y(x))=frac{dg(y(x))}{dy}frac{dy(x)}{dx}=(2y(x))frac{dy}{dx}
          $$






          share|cite|improve this answer












          You implicitly utilize the formula of derivative of a composite functions or a chain rule:
          $$
          f = y(x)^2, qquadfrac{df}{dx}=frac{d(y^2)}{dx},\
          f=g(y(x)),qquad g(y)=y^2,\
          frac{d}{dx}g(y(x))=frac{dg(y(x))}{dy}frac{dy(x)}{dx}=(2y(x))frac{dy}{dx}
          $$







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered Nov 26 at 18:21









          Vasily Mitch

          1,32837




          1,32837























              2














              The derivative of $y^2$ with respect to $y$ is $2y$ because of the definition of derivative:
              $$lim_{h to 0} frac{(y+h)^2-y^2}{h} = 2y.$$



              In the last expression you write
              $$frac{d(x^2)}{dx} = frac{d(x^2)}{dy}frac{dy}{dx}$$
              but this is meaningful only when $x$ is a function of $y$. So assume $x = f(y)$. Then, by the first equation you mention in the question, the right hand side is
              $$frac{d(f^2)}{dy}frac{dy}{dx} = 2f(y)f'(y)frac{dy}{dx} = 2xf'(y)frac{dy}{dx} = 2xfrac{dx}{dy}frac{dy}{dx} = 2xfrac{dx}{dx} = 2x.$$






              share|cite|improve this answer


























                2














                The derivative of $y^2$ with respect to $y$ is $2y$ because of the definition of derivative:
                $$lim_{h to 0} frac{(y+h)^2-y^2}{h} = 2y.$$



                In the last expression you write
                $$frac{d(x^2)}{dx} = frac{d(x^2)}{dy}frac{dy}{dx}$$
                but this is meaningful only when $x$ is a function of $y$. So assume $x = f(y)$. Then, by the first equation you mention in the question, the right hand side is
                $$frac{d(f^2)}{dy}frac{dy}{dx} = 2f(y)f'(y)frac{dy}{dx} = 2xf'(y)frac{dy}{dx} = 2xfrac{dx}{dy}frac{dy}{dx} = 2xfrac{dx}{dx} = 2x.$$






                share|cite|improve this answer
























                  2












                  2








                  2






                  The derivative of $y^2$ with respect to $y$ is $2y$ because of the definition of derivative:
                  $$lim_{h to 0} frac{(y+h)^2-y^2}{h} = 2y.$$



                  In the last expression you write
                  $$frac{d(x^2)}{dx} = frac{d(x^2)}{dy}frac{dy}{dx}$$
                  but this is meaningful only when $x$ is a function of $y$. So assume $x = f(y)$. Then, by the first equation you mention in the question, the right hand side is
                  $$frac{d(f^2)}{dy}frac{dy}{dx} = 2f(y)f'(y)frac{dy}{dx} = 2xf'(y)frac{dy}{dx} = 2xfrac{dx}{dy}frac{dy}{dx} = 2xfrac{dx}{dx} = 2x.$$






                  share|cite|improve this answer












                  The derivative of $y^2$ with respect to $y$ is $2y$ because of the definition of derivative:
                  $$lim_{h to 0} frac{(y+h)^2-y^2}{h} = 2y.$$



                  In the last expression you write
                  $$frac{d(x^2)}{dx} = frac{d(x^2)}{dy}frac{dy}{dx}$$
                  but this is meaningful only when $x$ is a function of $y$. So assume $x = f(y)$. Then, by the first equation you mention in the question, the right hand side is
                  $$frac{d(f^2)}{dy}frac{dy}{dx} = 2f(y)f'(y)frac{dy}{dx} = 2xf'(y)frac{dy}{dx} = 2xfrac{dx}{dy}frac{dy}{dx} = 2xfrac{dx}{dx} = 2x.$$







                  share|cite|improve this answer












                  share|cite|improve this answer



                  share|cite|improve this answer










                  answered Nov 26 at 18:28









                  Gibbs

                  4,7583726




                  4,7583726






























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