# Gradient (nabla) of vector/array in Delphi

I am to implement the following formula in Delphi:

Understanding the formula:

Y_k is a floating point number which we'll call just Y.

w[i][j] is an array containing floating point numbers as well (1<=i<=43 and 1<=j<=30).

According to my source paper (p. 12) nabla(w)*Y_k is the partial derivative of (column) vector w with respect to the value Y". Is this correct?

Coding in Delphi (implementation):

So how do I implement this in Delphi?

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I am afraid that I havn't got time to read the article (not even the beginning thereof). You should first make sure that you understand what function you want to implement (otherwise, it is hard to implement it). Secondly, you need to design a data type that can hold the quantities used as input and output of this function, that is, the interface, or signature, of the function. (This might be a simple `array of real`.) Then, and not before that point, you can contemplate about how to implement the function. –  Andreas Rejbrand Feb 21 '11 at 21:07

I will assume that the problem is: "How can I compute a gradient of a scalar function in Delphi?" [I still think that the symbol given above looks more like a connection/covariant derivative as known from differential geometry/tensor calculus!]

You need to specify the input you got. The simplest case is when you got the function f whose gradient you wish to compute. Per definition, if f is a function of the k variables x1, x2, ..., xk, that is, if you'd write

f(x1, x2, ..., xk)

which is a scalar field in ℝk then the gradient is

f = (∂f/∂x1, ∂f/∂x2, ..., ∂f/∂xk)

that is, a vector field in ℝk (at each point in ℝk you get a k-dimensional vector).

This is rather easily implemented in Delphi. The following is an example for the case where k = 3.

``````type
TVector = record
x, y, z: real;
constructor Create(ax, ay, az: real);
end;
TRealValuedFunction = function(v: TVector): real;

function gradient(f: TRealValuedFunction; v: TVector): TVector;
const
h = 0.001;
begin
result.x := (f(TVector.Create(v.x + h, v.y, v.z)) - f(TVector.Create(v.x - h, v.y, v.z))) / (2*h);
result.y := (f(TVector.Create(v.x, v.y + h, v.z)) - f(TVector.Create(v.x, v.y - h, v.z))) / (2*h);
result.z := (f(TVector.Create(v.x, v.y, v.z + h)) - f(TVector.Create(v.x, v.y, v.z - h))) / (2*h);
end;
``````

where, of course,

``````constructor TVector.Create(ax, ay, az: real);
begin
x := ax;
y := ay;
z := az;
end;
``````

Sample usage:

``````function SampleFunction(v: TVector): real;
begin
result := 5*v.x + 7*v.y;
end;

procedure TForm4.FormCreate(Sender: TObject);
begin
with gradient(SampleFunction, TVector.Create(2, 6, 3)) do
ShowMessage(FloatToStr(x) + ', ' + FloatToStr(y) + ', ' + FloatToStr(z))
end;
``````

The result is `5.00000000000256, 7.000000000005, 0` which is a very good approximation to the gradient of `SampleFunction` at `v` (in this case the gradient is constant in space, that is, it doesn't depend on which point `v` in space you select).

Of course, if you are writing anything serious, you will probably use your own vector algebra library.

Also, `h = 0.001` might not be a great value in your case.

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Thank you so much for this detailed and good answer! –  Marco W. Feb 24 '11 at 17:38