Directional Derivative and Approach Path

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Homework Help Overview

The problem involves finding the directional derivative of a function C(x, y) in the radial direction at any surface point, as well as determining the shark's approach path from a specified point at the sea surface. The context is centered around concepts in multivariable calculus, particularly related to directional derivatives and gradients.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the meaning of "approach path" and its relation to the gradient vector and directional derivatives. Questions arise regarding whether the approach path is a vector or a curve, and how it relates to the tangent vector at each point.

Discussion Status

The discussion is active, with participants exploring different interpretations of the term "approach path." Some suggest it refers to the quickest route following the gradient, while others clarify that it represents a path or curve defined by a differential equation involving the gradient. There is no explicit consensus yet.

Contextual Notes

Participants are navigating the definitions and implications of directional derivatives and gradients in the context of the problem, indicating a need for clarity on terminology and mathematical relationships.

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Homework Statement


I have a problem that says: Find the directional derivative of C(x, y) in the radial direction at any surface point (x, y).

It then says: Find the shark’s approach path from any point (x0, y0) at the sea surface.

I found the directional derivative in the radial direction, but how do I find the approach path? (Basically, what is meant by "approach path")

Homework Equations



The Attempt at a Solution


See question above.
 
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It seems like "approach path" would mean the quickest route for the shark. In other words, the shark would have to follow the gradient vector at each point because that is when the directional derivative is as large as possible.
 
So does "approach path" refer to a vector?
Would it just be the unit vector in the direction of the gradient vector?
(which also happens to be when the direction derivative is at a maximum)
 
No, "approach path" refers to a path or curve. The point is that, at each point, the tangent vector to that point is tangent to the gradient of the given function. In particular, if gradient vector is <f(x,y), g(x,y)> then the "approach path", y(x), must satisfy dy/dx= g(x,y)/f(x,y). Solve that differential equation to find y(x).
 

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