# In Mathematica, How calculate P(A) where P is a polynomial and A is a square matrix?

supose i define a matrix like this:

``````A= {{1,1},{2,2}}
``````

and now want to compute A^2 + 3A - 3Id, where a^2 is of course A.A

The syntax in mathematica for doing this is:

``````MatrixPower[A,2] + 3A + 3 IdentityMatrix[2]
``````

Is it posible to change de operators behavior in order to be able to write

``````A^2 + 3A - 3Id
``````

and get the correct answer ?

Or alternatively

``````applyPoly[x + 3x + 3, x, A]
``````

or something like this ?

I was tring some aproaches, but i couldn't do it.

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When you ask about changing the operator behavior, do you mean that you'd like to enter, for instance, `A^2` and have Mathematica understand this? –  Codie CodeMonkey Jun 30 '13 at 19:38
Yes that is what I mean. –  nadapez Jun 30 '13 at 19:43
I'm out of time to do this question justice (family is pulling me away) but you should look at `Unprotect` to allow changes to an operator, and `;/` to specify conditions for a definition. The use something like `m_^n_ := MatrixPower[m,n];/MatchQ[Dimension[m], {n_, n_}]`... or something like that. This is all from distant memory, so take only the flavor of how it's done, don't trust the specifics! When I get back I'll see if it's still unanswered and if not, I'll make it work. –  Codie CodeMonkey Jun 30 '13 at 19:49

I wrote your applyPoly function as follows. `A_?MatrixQ` checks that the input `A` is indeed a matrix, the input `var` is the polynomial variable which in your question is `x`. The variable `c` contains a list of coefficients of your polynomial, starting from power zero.

``````applyPoly[poly_, var_, A_?MatrixQ] :=
With[{c = CoefficientList[poly, var]},
c.MapIndexed[MatrixPower[A, #2[[1]]-1]&, c]]
``````

In version 9, you could use `MatrixFunction` as in

``````MatrixFunction[#^2+3#-3&,A]
``````
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Since you want Mathematica to interpret A^2 as MatrixPower[A, 2], this definitely involves overloading standard definitions which is generally not good.

The approach I suggest aslo slightly modifies standard definitions but feels more acceptable:

``````OverHat[x_] := operator[x]

Format[operator[x_]] := OverscriptBox[x, "^"] // DisplayForm

Times[o_operator, oRest__operator] ^:=
operator[Dot @@ Identity @@@ Hold[o, oRest]]

Plus[o_operator, oRest__operator] ^:=
operator[Plus @@ Identity @@@ Hold[o, oRest]]

Times[n_?NumberQ, operator[m_?MatrixQ]] ^:=
operator[Times[n, m]]

Plus[n_?NumberQ, operator[m_?MatrixQ]] ^:=
operator[Plus[Times[n, IdentityMatrix[Length[m]]], m]]

Power[operator[m_?MatrixQ], n_] ^:=
operator[MatrixPower[m, n]]
``````

`operator` homomorphically maps algebra of Matrices (in the sense of Mathematica) to algebra of some abstract operators. Since it acts homomorphically w.r.t. `Plus`, `Times` and `Power`, you can easily apply polynomials to operators.

Operator corresponding to expression A will be printed as Â. You can also input operators this way, i.e., “A, Ctrl+&, “^”, Ctrl+Space”. The Unicode char Â that I use here and below is not the same as Mathematica's OverHat[A].

Now you can do things like

``````x^2 + 3 x - 3 /. x -> Â
``````

for symbolical operators. Or perform calculations with coordinates:

``````In[1]:= A = {{2, -20, -10}, {0, 4, 1}, {0, -6, -1}};
In[2]:= x^3 - 5 x^2 + 8 x - 4 /. x -> Â
``````

which will eveluate to zero operator (this is charateristic polynomial for ). Please note that it will be a zero operator, not a zero matrix, although it will look almost like one, but with a hat over it, which in turn would look like a hat over the middle zero. (This bug can be fixed.)

The definition

``````operator[m_?MatrixQ][v_List] := m.v
``````

makes it possible then to apply operators (as well as polynomials applied to operators) to vectors:

``````In[3]:= Â[{0, -1, 2}]
Out[3]= {0, -2, 4}
``````

(eigenvector corresponding to eigenvalue 2)

``````In[4]:= (Â - 2)[{0, -1, 2}]
Out[4]= {0, 0, 0}
``````

I haven't implemented solid error-checking but I hope you got the idea and will be able to make improvements if you like it.

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I think it might be better to use a matrix form of Horner's rule for calculating a polynomial. For a polynomial p(x) = a + b x + c x^2 + d x^3 + ..., one extracts the list of coefficients (a, b, c, d, ...) and calculates recursively

``````h(()) = 0;

h((a, b, c, d, ...)) =  a + x h((b, c, d, ...)).
``````

The matrix version would be

``````h(()) = 0;
h((a, b, c, d, ...), A) =  a I +  A. h((b, c, d, ...), A),
``````

where I is the identity matrix. Mathematica code:

``````MatrixHorner[coeffs_, A_] := Module[{size = Length[A]},
If[coeffs == {}, ConstantArray[0, {size, size}],
First[coeffs] IdentityMatrix[size] + A.MatrixHorner[Rest[coeffs], A]]
]

ApplyPoly[p_, var_, A_?MatrixQ] :=
Module[{c = CoefficientList[p, var]},
MatrixHorner[c, A]
]
``````

``````q = -3 + 3 x + x^2
A = {{1, 1}, {2, 2}}
ApplyPoly[q, x,  A]
``````

Output:

``````{{3, 6}, {12, 9}}
``````

I think the point of this is that many fewer matrix multiplications are involved; the total number of matrix multiplications done is just the degree of the polynomial.

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