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Questions tagged [partial-derivative]

For questions regarding partial derivatives. The partial derivative of a function of several variables is the derivative of the function with respect to one of those variables, with all others held constant.

The partial derivative of a function of several variables is the derivative of the function with respect to one of the variables, with the others held constant. The partial derivative, like the ordinary derivative, describes the rate of change of a function in a particular direction.

If $f = f(a_1, a_2, \dots, a_n)$ is a function of $n$ variables, then the partial derivative of $f$ with respect to the variable $a_i$ can be written as a limit:

$$\frac{\partial f}{\partial a_i} = \lim_{h \to 0} \frac{f(a_1, \dots, a_i + h, \dots, a_n) - f(a_1, \dots, a_i, \dots, a_n)}{h}.$$

Alternatively, this quantity can be denoted as $f_{a_i}$.

If the function has continuous partial second derivatives, then:

$$\frac{\partial}{\partial x_i}\left(\frac{\partial}{\partial x_j}\right)=\frac{\partial}{\partial x_j}\left(\frac{\partial}{\partial x_i}\right)$$

a result known as Schwarz's Theorem.

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How to Multiply Partial Derivatives

To start I find the derivative with respect to fx = 2y + x derivative with respect to fy = 2 x - e^x/((e^x + 2)^2 (1/(e^x + 2)^2 + 1)) + y Then to find the answer multiply fx by fy. However the correct answer is 1 and apparently it can be found…
sawreals2
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Why is the summation dropped when calculating this derivative?

Here is the expression to take the derivative of. $$C = \frac{1}{2}\sum_j (y_j - a_j^L)^2$$ Here is the result. $$\frac{\partial C}{\partial a_j^L} = 2(a_j^L-y_j)$$ Multiplying by 2, then again by the derivative of the inside (-1) seems reasonable,…
compguy24
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How to correctly differentiate sum term

Given a function $f_i (x_1,\dots, x_N)$ that is summed over, how do I find the correct partial derivative? \begin{equation} f_i = \sum _{j=1}^Nc_{ij}x_ix_j \end{equation} Then, \begin{equation} \frac{\partial}{\partial x_k}f_i =…
RedPen
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partial derivative with respect to itself

Given some state function $$f(x,y,z)=0$$ I want to prove the reciprocity relationship $$\left(\dfrac{\partial x}{\partial y}\right)_z=\dfrac{1}{\left(\dfrac{\partial y}{\partial x}\right)_z}$$ I know how to do this the standard way (implicit…
wrkyle
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Partial Differentiation Confusion

Please see image. This is a screenshot of a lecture slide from a Control Engineering module, however I can't seem to understand how the partial dc/dg was used to give the RHS of the equation in the red ellipse. I've tried deriving it put I'm sure…
star_it8293
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prove if Hessian determinant is zero then second derivative test fails

I know if Hessian determinant is zero then second derivative test fails.. But I find that the following proof is a contradiction ! Moving along the unit vector $$u=u_1 i + u_2 j$$ and knowing that the crtical point is $$(x_0,y_0)$$ $$$$…
MCS
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$f(x,y) = \ln (1-x^2-y^2)$. What's the derivative?

What's is the derivative of $f(x,y)= \ln(1-x^2-y^2)$? I got it to $f_x(x,y)= 2x^-1$ and the same for $f_y(x,y)$, but that's obviously incorrect. How do I solve this problem properly?
Emil
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partial derivative $ e^{\frac{x^2}{2}}y $

$ e^{\frac{x^2}{2}}y $ find $ f_{xxxxxxxxxxxxxxxxxxxxxxxyxxxxxxxxxxxxyxxxxxxx} $ I already worked out 6 terms but still cannot see any pattern. am i suppose to do all these?
Nestro Abarca
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Intuition behind one second partial derivative test case

I want the geometrical interpretation of the following: If $f_{xx}f_{yy} < f_{xy}^2$ and $f_{xx}$ has the same sign as $f_{yy}$ at a point, then why is that point a saddle point? Because,in the case that they have the same sign,one would expect…
TheQuantumMan
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implicit derivatives on a surface

Given a surface defined implicitly by a function like $f(x,y,z) = c$, I'm trying to show that $\frac{dx}{dy}\frac{dy}{dz}\frac{dz}{dx} = -1 $ for derivatives taken along the surface. I have no clue where to start on this, it seems like by the chain…
Peter Booth
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If $f(x,y)=\int^x_y \cos(t^2)\,dt$, find the first partial derivatives of the function

Problem: If $f(x,y)=\int^x_y \cos(t^2) \, dt$, find the first partial derivatives of the function. My thoughts: By the Fundamental Theorem of Calculus, I know that $f_x=\cos(x^2)$, since $y$ is just treated as a constant. But what about $f_y$? Am I…
Asker
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Solving for a Partial Derivative with Cramer's Rule

In Advanced Calculus by Widder I have come across a problem on page 30 regarding Cramer's rule and solving for a partial derivative. I understand the…
bjd2385
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Is the Legendre transformation just simple substitution?

I am confused by the Legendre transform. I did the math and carried it out for a function $f(x,y)$, but I don't understand what good it does. What is the purpose? Didn't I merely just redefine my variables in terms of other variables? It seems to…
Stan Shunpike
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Partial Differentiation Chain Rule Confusion

If $\rho=\rho(x(t),t)$ and $P=f(\rho)$ is it correct to write: $\displaystyle\frac{dP}{dt}=f'(\rho) \frac{\partial \rho}{\partial t} +f'(\rho) \frac{\partial \rho}{\partial x} \frac{dx}{dt}$ using the chain rule?
user144895
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theorems of partial differentiation

Can we simply hold $x$ or $z$ constant for all of the equation ? (not only for one partial differentiation) furthermore, if we hold $x$ constant so that $dx= 0$ like what he did in the last equation, we will have so:
user3613971
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