Partial differential: partial scalar partial vector

Havik
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Hi,

I have a problem to find the meaning of a special partial differential: partial scalar partial vector.

i.e. dF/dn where F is a scalar and n is a i.e. normal vector. This is a partial diff.

n could be a vector consisting of partial differentials, (dT/dx,dT/dy)

I have looked in literature but found nothing.

Can someone help me?

Thank you very much
/Andreas
 
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Welcome to PF!

Hi Andreas! Welcome to PF! :smile:

(have a curly d: ∂ :wink:)
Havik said:
I have a problem to find the meaning of a special partial differential: partial scalar partial vector.

i.e. dF/dn where F is a scalar and n is a i.e. normal vector. This is a partial diff.

n could be a vector consisting of partial differentials, (dT/dx,dT/dy)

No such thing … you can't have d(scalar)/d(vector) or ∂(scalar)/∂(vector). :wink:

But (for example, when calculating flux) you can have ∂F/∂n or d(F.n^)/dn, where n^ is the unit vector in the normal direction, and n is the distance in that direction. :smile:
 
Havik said:
Hi,

I have a problem to find the meaning of a special partial differential: partial scalar partial vector.

i.e. dF/dn where F is a scalar and n is a i.e. normal vector. This is a partial diff.

n could be a vector consisting of partial differentials, (dT/dx,dT/dy)

I have looked in literature but found nothing.

Can someone help me?

Thank you very much
/Andreas

Perhaps you are thinking about directional derivatives. If F(x,y,z) is a scalar function (perhaps the temperature at (x,y,z)), and V is a vector, then the rate of change of F in the direction of V is:

\frac {\partial F}{\partial \hat v} = D_{\hat v}(F) = \nabla F \cdot \hat V

where \hat V is a unit vector in the direction of V.
 
Hi tiny-tim and LCKurtz,

This is exactly the explanation I am looking for! I had a hard time to understand the meaning of such partial derivative. And it with \partial it should be :smile:

It is the rate of F in the direction of some unit vector n that is normal to an arbitrary surface. I have no problem to find the growth rate of F in x and y but when it came to a other direction depending on other things, it became a problem. But now I understand how to do it!

I actually did not think of the thing that n must be a unit vector. I will make it a unit vector!

Thank you very much for your help on this problem, I have been struggling to find the answer for a long time!
 
Thread 'Direction Fields and Isoclines'

Thread 'Direction Fields and Isoclines'

I sketched the isoclines for $$ m=-1,0,1,2 $$. Since both $$ \frac{dy}{dx} $$ and $$ D_{y} \frac{dy}{dx} $$ are continuous on the square region R defined by $$ -4\leq x \leq 4, -4 \leq y \leq 4 $$ the existence and uniqueness theorem guarantees that if we pick a point in the interior that lies on an isocline there will be a unique differentiable function (solution) passing through that point. I understand that a solution exists but I unsure how to actually sketch it. For example, consider a...
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