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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.

Thanks in advance...

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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

3 Answers 3

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  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]
]

Your example:

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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