23

Is there a way to do symbolic matrix algebra in Mathematica for matrices where the dimensions are unknown? For example, if I have an MxL matrix A and an LxN matrix B, I would like to be able to enter

A.B

And have it give me a matrix whose element ab[i,j] is given by

Sum[a[i,l]*b[l,j],{l,1,L}]

The problem I'm working on is like this one, but involves the product of 12 matrices, including the same matrix (and its transpose) repeated several times. It will probably be possible to simplify the values of the resulting matrix, but it's not obvious whether this is possible until after I do the algebra. This may be a problem that I have to solve by hand, but it would be much easier if Mathematica could provide some help in simplifying the algebra.

7
  • As Sasha pointed out, it is doable. But, I'd do this be hand, and rely on Mathematica to check it along the way. I'd use the Einstein summation convention, though, as it will save a lot of time and it makes most manipulations easier.
    – rcollyer
    Apr 18, 2011 at 20:27
  • @rcollyer I think I'm missing something in your comment. What do you mean by using index contraction? If your explanation is more than a comment can hold, I could post an ad-hoc question Apr 18, 2011 at 21:58
  • @belisarius: I think @rcollyer was referring to using shorter notations when doing calculations by hand, as it is more convenient; not in mma. For example, a_1b_1+...+a_nb_n can be conveniently written as a_ib_i, with the summation over all n being implied. Dot products, dyadic products, traces etc can all be written compactly this way. Things get messier when exponentials are involved, as the notation gets confusing (I'm not sure if they even use this notation in that case).
    – abcd
    Apr 18, 2011 at 22:20
  • 3
    @belisarius: A quick google search led me to this package which lets you perform symbolic tensor computations using Einstein summation convention. I haven't tested it, but if it's any good, it should be added to the CW post on Mathematica tools.
    – abcd
    Apr 18, 2011 at 22:35
  • 4
    It doesn't help us at the moment, but Stephen Wolfram has promised that a capability is coming Real Soon Now that is "going to make doing serious tensor analysis feel pretty much like doing ordinary algebra". I'm eager to see what he means by that, and whether the capability will address problems such as the one raised by this question.
    – WReach
    Apr 18, 2011 at 23:11

5 Answers 5

20

Here's the code [dead-link removed] that wasted my morning... It's not complete, but it basically works. You can either get the notebook from the previous link [dead] or copy the code below.

Note that a similar question turned up on ask.sagemath not so long ago.

Almost like Sasha's solution, you define a symbolic matrix using

A = SymbolicMatrix["A", {n, k}]

for some string "A" that does not have to be the same as the symbol A. Ok, here's the code:

ClearAll[SymbolicMatrix]
Options[SymbolicMatrix] = {Transpose -> False, Conjugate -> False, MatrixPower -> 1};

Short hand for entering square matrices (could make it work for different heads...)

SymbolicMatrix[name_String, n:_Symbol|_Integer, opts : OptionsPattern[]] := SymbolicMatrix[name, {n, n}, opts]

Behavior under Transpose, Conjugate, ConjugateTranspose and Inverse

SymbolicMatrix/:Transpose[SymbolicMatrix[name_String,{m_,n_},opts:OptionsPattern[]]]:=SymbolicMatrix[name,{n,m},
  Transpose->!OptionValue[SymbolicMatrix,Transpose],Sequence@@FilterRules[{opts},Except[Transpose]]]
SymbolicMatrix/:Conjugate[SymbolicMatrix[name_String,{m_,n_},opts:OptionsPattern[]]]:=SymbolicMatrix[name,{m,n},
  Conjugate->!OptionValue[SymbolicMatrix,Conjugate],Sequence@@FilterRules[{opts},Except[Conjugate]]]
SymbolicMatrix/:ConjugateTranspose[A:SymbolicMatrix[name_String,{m_,n_},opts:OptionsPattern[]]]:=Conjugate[Transpose[A]]
SymbolicMatrix/:Inverse[SymbolicMatrix[name_String,{n_,n_},opts:OptionsPattern[]]]:=SymbolicMatrix[name,{n,n},
  MatrixPower->-OptionValue[SymbolicMatrix,MatrixPower],Sequence@@FilterRules[{opts},Except[MatrixPower]]]

SymbolicMatrix/:(Transpose|Conjugate|ConjugateTranspose|Inverse)[eye:SymbolicMatrix[IdentityMatrix,{n_,n_}]]:=eye

Combining matrix powers (including the identity matrix)

SymbolicMatrix/:SymbolicMatrix[a_String,{n_,n_},opt1:OptionsPattern[]].SymbolicMatrix[a_,{n_,n_},opt2:OptionsPattern[]]:=SymbolicMatrix[a,{n,n},Sequence@@FilterRules[{opt1},Except[MatrixPower]],MatrixPower->Total[OptionValue[SymbolicMatrix,#,MatrixPower]&/@{{opt1},{opt2}}]]/;FilterRules[{opt1},Except[MatrixPower]]==FilterRules[{opt2},Except[MatrixPower]]

SymbolicMatrix[a_String,{n_,n_},opts:OptionsPattern[]]:=SymbolicMatrix[IdentityMatrix,{n,n}]/;OptionValue[SymbolicMatrix,{opts},MatrixPower]===0

SymbolicMatrix/:(A:SymbolicMatrix[a_String,{n_,m_},OptionsPattern[]]).SymbolicMatrix[IdentityMatrix,{m_,m_}]:=A
SymbolicMatrix/:SymbolicMatrix[IdentityMatrix,{n_,n_}].(A:SymbolicMatrix[a_String,{n_,m_},OptionsPattern[]]):=A

Pretty printing with the dimension as a tooltip.

Format[SymbolicMatrix[name_String,{m_,n_},opts:OptionsPattern[]]]:=With[{
  base=If[OptionValue[SymbolicMatrix,MatrixPower]===1,
    StyleBox[name,FontWeight->Bold,FontColor->Darker@Brown],
    SuperscriptBox[StyleBox[name,FontWeight->Bold,FontColor->Darker@Brown],OptionValue[SymbolicMatrix,MatrixPower]]],
  c=Which[
    OptionValue[SymbolicMatrix,Transpose]&&OptionValue[SymbolicMatrix,Conjugate],"\[ConjugateTranspose]",
    OptionValue[SymbolicMatrix,Transpose],"\[Transpose]",
    OptionValue[SymbolicMatrix,Conjugate],"\[Conjugate]",
  True,Null]},
  Interpretation[Tooltip[DisplayForm@RowBox[{base,c}/.Null->Sequence[]],{m,n}],SymbolicMatrix[name,{m,n},opts]]]

Format[SymbolicMatrix[IdentityMatrix,{n_,n_}]]:=Interpretation[Tooltip[Style[\[ScriptCapitalI],Bold,Darker@Brown],n],SymbolicMatrix[IdentityMatrix,{n,n}]]

Define some rules for Dot. Need to extend then so that it can handle scalar quantities etc... Also so that inverses of A.B can be taken if A.B is square, even if neither A nor B are square.

SymbolicMatrix::dotdims = "The dimensions of `1` and `2` are not compatible";
Unprotect[Dot]; (*Clear[Dot];*)
Dot/:(a:SymbolicMatrix[_,{_,n_},___]).(b:SymbolicMatrix[_,{m_,_},___]):=(Message[SymbolicMatrix::dotdims,HoldForm[a],HoldForm[b]];Hold[a.b])/;Not[m===n]
Dot/:Conjugate[d:Dot[A_SymbolicMatrix,B__SymbolicMatrix]]:=Map[Conjugate,d]
Dot/:(t:Transpose|ConjugateTranspose)[d:Dot[A_SymbolicMatrix,B__SymbolicMatrix]]:=Dot@@Map[t,Reverse[List@@d]]
Dot/:Inverse[HoldPattern[d:Dot[SymbolicMatrix[_,{n_,n_},___]...]]]:=Reverse@Map[Inverse,d]
A_ .(B_+C__):=A.B+A.Plus[C]
(B_+C__).A_:=B.A+Plus[C].A
Protect[Dot];

Make Transpose, Conjugate and ConjugateTranspose distribute over Plus.

Unprotect[Transpose, Conjugate, ConjugateTranspose];
Clear[Transpose, Conjugate, ConjugateTranspose];
Do[With[{c = c}, c[p : Plus[a_, b__]] := c /@ p], {c, {Transpose, Conjugate, ConjugateTranspose}}]
Protect[Transpose, Conjugate, ConjugateTranspose];

Here's some simple tests/examples

Test image 1

Test image 2

Now for code that deals with the component expansion. Like Sasha's solution, I'll overload Part.

Clear[SymbolicMatrixComponent]
Options[SymbolicMatrixComponent]={Conjugate->False,MatrixPower->1};

Some notation

Format[SymbolicMatrixComponent[A_String,{i_,j_},opts:OptionsPattern[]]]:=Interpretation[DisplayForm[SubsuperscriptBox[StyleBox[A,Darker@Brown],RowBox[{i,",",j}],
RowBox[{If[OptionValue[SymbolicMatrixComponent,{opts},MatrixPower]===1,Null,OptionValue[SymbolicMatrixComponent,{opts},MatrixPower]],If[OptionValue[SymbolicMatrixComponent,{opts},Conjugate],"*",Null]}/.Null->Sequence[]]]],
SymbolicMatrixComponent[A,{i,j},opts]]

Code to extract parts of matrices and Dot products of matrices Need to add checks to ensure that explicit summation ranges are all sensible.

SymbolicMatrix/:SymbolicMatrix[A_String,{m_,n_},opts:OptionsPattern[]][[i_,j_]]:=SymbolicMatrixComponent[A,If[OptionValue[SymbolicMatrix,{opts},Transpose],Reverse,Identity]@{i,j},Sequence@@FilterRules[{opts},Options[SymbolicMatrixComponent]]]

SymbolicMatrix/:SymbolicMatrix[IdentityMatrix,{m_,n_}][[i_,j_]]:=KroneckerDelta[i,j]

Unprotect[Part]; (*Clear[Part]*)
Part/:((c___.b:SymbolicMatrix[_,{o_,n_},OptionsPattern[]]).SymbolicMatrix[A_String,{n_,m_},opts:OptionsPattern[]])[[i_,j_]]:=With[{s=Unique["i",Temporary]},Sum[(c.b)[[i,s]]SymbolicMatrixComponent[A,If[OptionValue[SymbolicMatrix,{opts},Transpose],Reverse,Identity]@{s,j},Sequence @@ FilterRules[{opts}, Options[SymbolicMatrixComponent]]],{s,n}]]
Part/:(a_+b_)[[i_,j_]]:=a[[i,j]]+b[[i,j]]/;!And@@(FreeQ[#,SymbolicMatrix]&/@{a,b})
Part/:Hold[a_][[i_,j_]]:=Hold[a[[i,j]]]/;!FreeQ[a,SymbolicMatrix]
Protect[Part];

Some examples:

example3 example4

9
  • 1
    This is over my head, but it looks fancy, so: +1
    – Mr.Wizard
    Apr 19, 2011 at 3:27
  • @Mr.Wizard: I doubt that any of it's over your head. It's just a mess of Option* commands...
    – Simon
    Apr 19, 2011 at 4:01
  • Wow, you should posti this in the Mathematica Tool Bag community wiki stackoverflow.com/q/4198961/181759, very nice work.
    – Timo
    Apr 19, 2011 at 11:30
  • Thanks, @Simon ! This is super helpful. I'm not a terribly good Mathematica programmer, so I don't really understand what is going on, but I can almost use your code as-is. As part of the matrix product I'm trying to evaluate, I need to repeatedly multiply by square matrices whose entries are all ones. I tried (and failed) to implement this as a function on SymbolicMatrix, so each entry is replaced by the sum of the elements of that column. Would it be easy for you to show me code that does this? Thanks again for your help - this has inspired me to learn a lot more Mathematica!
    – jack
    Apr 19, 2011 at 15:49
  • @jack: At the moment I haven't decided on the best way to implement the substitution of actual matrices. I want a simple interface where you say SymbolicMatrix -> Matrix, which then will deal with all the transposes, conjugates, MatrixPowers and component expressions for you. I also don't have too much time to play with it. For moment you can use explicit replacement rules. (Sorry... I'll write the code eventually!)
    – Simon
    Apr 20, 2011 at 1:52
7

I am not sure if this is really very helpful, but it could be a start:

ClearAll[SymbolicMatrix]
SymbolicMatrix /: Transpose[SymbolicMatrix[a_, {m_, n_}]] := 
     SymbolicMatrix[Evaluate[a[#2, #1]] & , {n, m}]
SymbolicMatrix /: 
 SymbolicMatrix[a_, {m_, n_}] . SymbolicMatrix[b_, {n_, p_}] := 
     With[{s = Unique[\[FormalI], Temporary]}, 
  SymbolicMatrix[Function[{\[FormalN], \[FormalM]}, 

    Evaluate[Sum[a[\[FormalN], s]*b[s, \[FormalM]], {s, 1, n}]]], {m, 
    p}]]
SymbolicMatrix /: SymbolicMatrix[a_, {m_, n_}][[i_, j_]] := a[i, j]


Now, define some symbolic matrices and do dot product:

In[109]:= amat = SymbolicMatrix[a, {n, k}]; 
bmat = SymbolicMatrix[b, {k, k}]; 

Evaluate matrix elements:

In[111]:= (amat . bmat . Transpose[amat])[[i, j]]

Out[111]= Sum[
 a[j, \[FormalI]$1485]*
  Sum[a[i, \[FormalI]$1464]*
    b[\[FormalI]$1464, \[FormalI]$1485], {\[FormalI]$1464, 1, k}], 
   {\[FormalI]$1485, 1, k}]
4
  • 1
    I see a disadvantage of using In and Out, it makes it much harder to copy. Would you mind putting the definition in one "line" of input, so that we can access it easier?
    – rcollyer
    Apr 18, 2011 at 20:20
  • +1 I like the approach, but you'll need to define an enormous amount of matrix functions such as Transpose. Additionally, for each symbolic matrix you define you'll also have to provide a function name (a,b in line 109). The user should preferably not be bothered by that. Apr 18, 2011 at 20:26
  • ToMatrix was meant to instantiate a matrix for given explicit dimensions but it was no good, so I deleted it in the edit.
    – Sasha
    Apr 18, 2011 at 20:32
  • Thanks a lot for your help, @Sasha. I'm not a terribly good Mathematica programmer, so I'll need to spend some quality time with the documentation before I understand your code (I'll probably read up on modules, scope, etc.) In the meantime, I'll probably just follow @rcollyer 's advice and work it out by hand.
    – jack
    Apr 18, 2011 at 21:29
2

If you're willing to switch from Mathematica to Python the functionality you need is in the development branch of SymPy. It should be in the 0.72 release.

In [1]: from sympy import *
In [2]: X = MatrixSymbol('X', 2,3)
In [3]: Y = MatrixSymbol('Y', 3,3)
In [4]: X*Y*X.T
Out[4]: X⋅Y⋅X'

In [5]: (X*Y*X.T)[0,1]
Out[5]: 
X₀₀⋅(X₁₀⋅Y₀₀ + X₁₁⋅Y₀₁ + X₁₂⋅Y₀₂) + X₀₁⋅(X₁₀⋅Y₁₀ + X₁₁⋅Y₁₁ + X₁₂⋅Y₁₂) + X₀₂⋅(X₁₀⋅Y₂₀ + X₁₁⋅Y₂₁ + X₁₂⋅Y₂₂)

These purely symbolic objects can also make use of all of the standard matrix algorithms for explicitly defined matrices

In [14]: X = MatrixSymbol('X', 2,2)
In [14]: X.as_explicit().det()
Out[14]: X₀₀⋅X₁₁ - X₀₁⋅X₁₀

Symbolic shaped matrices are doable too

In [7]: n,m,k = symbols('n,m,k')
In [8]: X = MatrixSymbol('X', n,m)
In [9]: Y = MatrixSymbol('Y', m,k)
In [10]: (X*Y)[3,4]
Out[10]: 
m - 1                
 ___                 
 ╲                   
  ╲   X(3, k)⋅Y(k, 4)
  ╱                  
 ╱                   
 ‾‾‾                 
k = 0                
1
  • Unfortunately, sympy doesn't see to be able to do much generic algebraic manipulation with matrices symbolically. For example, you can't rearrange expressions with solve: github.com/sympy/sympy/issues/11124
    – mpeac
    Sep 26, 2016 at 22:55
1

You can use NCAlgebra for that. For example:

MM = 3
LL = 2
NN = 3
AA = Table[Subscript[a, i, j], {i, 1, MM}, {j, 1, LL}]
BB = Table[Subscript[b, i, j], {i, 1, LL}, {j, 1, NN}]

will define symbolic matrices AA and BB with noncommutative entries $a_{i,j}$ and $b_{i,j}$. These can get manipulated and produce the results you're looking for. For example:

NCDot[AA, BB]

will multiply the two matrices using **,

AA ** BB // NCMatrixExpand

will do the same, and

tp[AA ** BB] // NCMatrixExpand

will transpose using tp.

0

I use this approach:

SymbolicMatrix[symbol_String, m_Integer, n_Integer] := Table[
  ToExpression[symbol <> ToString[i] <> ToString[j]],
  {i, 1, m}, {j, 1, n}
];
SymbolicMatrix[symbol_Symbol, m_Integer, n_Integer] := SymbolicMatrix[ToString[symbol], m, n];
SymbolicMatrix[symbol_, m_Integer] := SymbolicMatrix[symbol, m, 1];

When invoked as A = SymbolicMatrix["a", 2, 3]; or A = SymbolicMatrix[a, 2, 3];, it creates a matrix

{{a11, a12, a13}, {a21, a22, a23}}

So, it creates mxn symbols, but I find them descriptive, and the whole thing is easy to use (at least for my purposes).

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