Let z=2x+5y−−−−−−√

To find the rate of change in z at (2,4) as we change x but hold y fixed, we need to find the partial derivative of z with respect to x.

First, let's differentiate each term in z with respect to x:

∂z/∂x = ∂(2x)/∂x + ∂(5y)/∂x - ∂(√)/∂x

The derivative of 2x with respect to x is simply 2.

The derivative of 5y with respect to x is 0, since y is held fixed and does not vary with x.

The derivative of √( ) with respect to x can be found by applying the chain rule. Let's define a new function u = 2x + 5y. Then we have:

∂(√(u))/∂x = ∂(√(u))/∂u * ∂u/∂x

The derivative of √(u) with respect to u is 1/(2√(u)).

The derivative of u with respect to x is 2.

Substituting these values back into our partial derivative expression, we have:

∂z/∂x = 2 + 0 - (1/(2√(u))) * 2

At the point (2,4), u = 2(2) + 5(4) = 8 + 20 = 28.

√(28) can be simplified as 2√(7).

So, ∂z/∂x at (2,4) is:

∂z/∂x = 2 - (1/(2√(7))) * 2

To find the rate of change in z at (2,4) as we change y but hold x fixed, we need to find the partial derivative of z with respect to y.

Using a similar process as above, we have:

∂z/∂y = ∂(2x)/∂y + ∂(5y)/∂y - ∂(√)/∂y

The derivative of 2x with respect to y is 0, since x is held fixed and does not vary with y.

The derivative of 5y with respect to y is 5.

The derivative of √(u) with respect to y can be found using the chain rule. We already defined u = 2x + 5y. In this case, we have:

∂(√(u))/∂y = ∂(√(u))/∂u * ∂u/∂y

The derivative of √(u) with respect to u is also 1/(2√(u)).

The derivative of u with respect to y is 5.

Substituting these values back into our partial derivative expression, we have:

∂z/∂y = 0 + 5 - (1/(2√(u))) * 5

At the point (2,4), u = 28.

So, ∂z/∂y at (2,4) is:

∂z/∂y = 5 - (1/(2√(28))) * 5