Meaning of \delta in Implicit Functions

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I've come across a very ambiguous statement in my notes on implicit functions (part of the partial derivatives part of the course). I'll write out the preceding explanation but the problematic line is marked by *

"Sometimes we can define a function z=z(x, y) only in implicit form, i.e. through an equation F(x, y, z) = 0.
It is not always possible to solve this equation for z and obtain the function z=f(x,y).

In order to calculate the derivatives of a function defined implicitly we note that from the above equation it follows that:
* \deltaF=0 \Rightarrow \deltaF = Fx\deltax + Fy\deltay + Fz\deltaz = 0.
Or by taking differentials,
Fxdx + Fydy + Fzdz = 0"

My main problem is understanding how \deltax can stand on its own (above used as a factor). Is it just the same as ∆x, i.e. a change in x and not a derivative?

Also, how the \delta expressions change to d expressions in the second line is unclear to me...
 
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There is some ambiguity in the meaning of delta. Ask a physicist and he/she will tell you that \delta means a small change whereas \Delta corresponds to a large change.
 
i believe that your usage of ∂ is in the form of a partial derivative
and that you are using partial differentials in order to gain a total differential of the function F(x,y,z)
 
Last edited:
raymo39 said:
i believe that your usage of ∂ is in the form of a partial derivative
and that you are using partial differentials in order to gain a total differential of the function F(x,y,z)
The problem is that the Fx term implies ∂F/∂x and so on, whereas these individual partial derivative are then multiplied by the \deltax and so on terms - this is what confuses me.

So is it a partial derivative multiplied by a small change?
 
Yes, \delta x here just means a small change in x. Taking the limit as \delta x becomes "infinitesmal" gives you dx.
 
Ok, so what does dx stand for then? It is again multiplied by Fx, giving ∂F/∂x · dx. Since it isn't a double derivative of F with respect to x (especially since ∂ =/= d), then what is it's meaning here?
 
dx is a "differential".
 
So is it similar to "an infinitesimal change in x" but now it's an "infinitesimally small difference (ie, variation or difference) in x"?
 
well when you are taking differentials, you add limits to your small change in the value as they tend to zero
 
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