Use Math.NET's Fit.Polynomial method on functions of multiple parameters

I previously used Math.NET Numerics library's Fit.Polynomial method to fit a cubic polynomial on a set of data that could be modeled as a function of one parameter `y=f(x)`.
Now I would like to similarly find a 2 or 3 order polynomial that fits data that could be modeled as a function depending on multiple parameters `y=f(x1, x2, x3, x4)`.

Is there already a built-in function in Math.NET that can compute that polynomial?
If not, do you see how I could manipulate my data in order to submit it to Fit.Polynomial?

• What would your f look like exactly in case of, say, 2 variables and order 2? – Christoph Rüegg Dec 26 '13 at 16:56
• To keep it simple, I would say something like: `f(x1, x2) = a*x1*x1 + b*x1 + c*x2*x2 + d*x2 + e` – wip Dec 27 '13 at 0:58
• Maybe I can use the Fit.MultiDim method with an approach similar to what you describe in your post about linear regression: using `x1*x1` and `x2*x2` as separate parameters. However I am afraid this will produce results less accurate than using Fit.Polynomial (it was the case when I tried to do Cubic Function Fitting using your trick to leverage Linear Regression). Do you see any better method? – wip Dec 27 '13 at 1:17

The `Fit` class is just a facade that is good enough in most scenarios, but you can always use the algorithms directly to get exactly what you need.

`Fit.Polynomial:` Polynomial curve fitting with high orders is a bit problematic numerically, so specialized algorithms and routines to tune/refine parameters at the end have been developed. However, Math.NET Numerics just uses a QR decomposition for now (although it is planned to replace the implementation at some point):

``````public static double[] Polynomial(double[] x, double[] y, int order)
{
var design = Matrix<double>.Build.Dense(x.Length, order + 1, (i, j) => Math.Pow(x[i], j));
return MultipleRegression.QR(design, Vector<double>.Build.Dense(y)).ToArray();
}
``````

`Fit.MultiDim` on the other hand uses normal equations by default, which is much faster but less numerically robust than the QR decomposition. That's why you've seen reduced accuracy with this method.

``````public static double[] MultiDim(double[][] x, double[] y)
{
return MultipleRegression.NormalEquations(x, y);
}
``````

In your case I'd try to use the `MultipleRegression` class directly, with either `QR` (if good enough) or `Svd` (if even more robustness is needed; much slower (consider to use native provider if too slow)):

``````var x1 = new double[] { ... };
var x2 = new double[] { ... };
var y = new double[] { ... };

var design = Matrix<double>.Build.DenseOfRowArrays(
Generate.Map2(x1,x2,(x1, x2) => new double[] { x1*x1, x1, x2*x2, x2, 1d }));
double[] p = MultipleRegression.QR(design, Vector<double>.Build.Dense(y)).ToArray();
``````

(Using Math.NET Numerics v3.0.0-alpha7)

• Thank you for the suggestions, I will try them asap. – wip Jan 7 '14 at 2:28
• I managed to get results using MultipleRegression.QR, but I want more precision (no problem if the process is slow). I tried to use MultipleRegression.Svd instead, but I block on an exception on line 2212 of this file (revision 857751979..). Are you aware of a revision where this problem does not happen? – wip Jan 7 '14 at 7:17
• What kind of exception? – Christoph Rüegg Jan 7 '14 at 16:19
• The error is `Index was outside the bounds of the array`. It appears that the size of array `double[] u` passed is 0. It seems to be created here, but is not set afterwards, and passed two lines later to `Control.LinearAlgebraProvider.SingularValueDecomposition` via `u.Values`. – wip Jan 8 '14 at 1:20

RosettaCode proposes this solution for polynomial regression(using Math.Net):

``````    public static double[] Polyfit(double[] x, double[] y, int degree)
{
// Vandermonde matrix
var v = new DenseMatrix(x.Length, degree + 1);
for (int i = 0; i < v.RowCount; i++)
for (int j = 0; j <= degree; j++) v[i, j] = Math.Pow(x[i], j);
var yv = new DenseVector(y).ToColumnMatrix();
QR qr = v.QR();
// Math.Net doesn't have an "economy" QR, so:
// cut R short to square upper triangle, then recompute Q
var r = qr.R.SubMatrix(0, degree + 1, 0, degree + 1);
var q = v.Multiply(r.Inverse());
var p = r.Inverse().Multiply(q.TransposeThisAndMultiply(yv));
return p.Column(0).ToArray();
}
``````

Notice that the x in the linear model can also be a vector x=[x1 x2 ⋯ xk] and the arbitrary functions fi(x) can accept vectors instead of scalars.
Here is something nearly about what you want.