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For example, I want mma to expand out the following differential operator

(1+d/dx+x*d2/dy2)^2*(1+y*d/dy)^2

I found Nest is not good enough to do this sort of things.

Please let me know your thoughts and many thanks.

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Sorry ... what is d2/dy2 ? –  belisarius Feb 11 '11 at 21:36
    
@belisarius: It is the second partial derivative with respect to y. –  Qiang Li Feb 11 '11 at 21:43
    
@belisarius, @Simon: I am wondering if you know the answer to this very simple question: D[f[x, y], x] /. {f[x, y] -> x*y} why here the substitution is not working? Thanks! –  Qiang Li Feb 11 '11 at 23:00
1  
@ Qiang Li Have a look at the FullForm of the derivative. But, why don't you make this a new question. –  Leonid Shifrin Feb 11 '11 at 23:12
1  
@Qiang Li I do know the answer, but wouldn't encourage this exchange further within comments. Please formulate a new question, with a problem and everything you'd like to get at the end, and somebody will answer. Thanks. –  Leonid Shifrin Feb 11 '11 at 23:22

1 Answer 1

up vote 2 down vote accepted

A bit dated, but see

http://library.wolfram.com/infocenter/Conferences/325/

The section "Some noncommutative algebraic manipulation" gives a few ways to go about this. The first example, defining a function called differentialOperate, is probably best suited for your purposes.

---edit, reedited---

Here is the code I use. Probably it is (still) missing a few refinements. It is taken from a couple of examples in the notebook mentioned above.

I will define and use an auxiliary predicate, scalarQ. This gives the flexibility of declaring entities other than explicit numerical values to be scalar.

I define a noncommutative multiplication, called ncTimes. Ideally I would just use NonCommutativeMultiply, but Iwas not able to get the pattern matching to behave the way I wanted with respect to zero or one argument forms, or pulling out scalars. (Less technical explanation: it's mojo was more powerful than mine.)

scalarQ[a_?NumericQ] := True scalarQ[_] := False

ncTimes[] := 1 ncTimes[a_] := a ncTimes[a_, ncTimes[b_, c], d_] := ncTimes[a, b, c, d] ncTimes[a_, x_ + y_, b_] := ncTimes[a, x, b] + ncTimes[a, y, b] ncTimes[a_, i_?scalarQ*c_, b_] := i*ncTimes[a, c, b] ncTimes[a_, i_?scalarQ, b___] := i*ncTimes[a, b]

differentialOperate[a_, expr_] /; FreeQ[a, D] := a*expr differentialOperate[L1_ + L2_, expr_] := differentialOperate[L1, expr] + differentialOperate[L2, expr] differentialOperate[a_*L_, expr_] /; FreeQ[a, D] := a*differentialOperate[L, expr] differentialOperate[a : HoldPattern[D[] &], expr_] := a[expr] differentialOperate[ncTimes[L1, L2_], expr_] := Expand[differentialOperate[L1, differentialOperate[L2, expr]]] differentialOperate[L1_^n_Integer, expr_] /; n > 1 := Nest[Expand[differentialOperate[L1, #]] &, expr, n]

In[15]:= ddvar[x_, n_: 1] := D[#, {x, n}] &

Here are some of your examples, both from post and comments.

In[17]:= diffop = ncTimes[(1 + ddvar[x] + ncTimes[x, ddvar[y, 2]])^2, (1 + ncTimes[y, ddvar[y]])^2]

Out[17]= ncTimes[(1 + (D[#1, {x, 1}] & ) + ncTimes[x, D[#1, {y, 2}] & ])^2, (1 + ncTimes[y, D[#1, {y, 1}] & ])^2]

Apply this operator to f[x,y].

In[25]:= differentialOperate[diffop, f[x, y]]

Out[25]= f[x, y] + 3*y*Derivative[0, 1][f][x, y] + 9*Derivative[0, 2][f][x, y] + 18*x*Derivative[0, 2][f][x, y] + y^2*Derivative[0, 2][f][x, y] + 7*y*Derivative[0, 3][f][x, y] + 14*x*y*Derivative[0, 3][f][x, y] + 25*x^2*Derivative[0, 4][f][x, y] + y^2*Derivative[0, 4][f][x, y] + 2*x*y^2*Derivative[0, 4][f][x, y] + 11*x^2*y*Derivative[0, 5][f][x, y] + x^2*y^2*Derivative[0, 6][f][x, y] + 2*Derivative[1, 0][f][x, y] + 6*y*Derivative[1, 1][f][x, y] + 18*x*Derivative[1, 2][f][x, y] + 2*y^2*Derivative[1, 2][f][x, y] + 14*x*y*Derivative[1, 3][f][x, y] + 2*x*y^2*Derivative[1, 4][f][x, y] + Derivative[2, 0][f][x, y] + 3*y*Derivative[2, 1][f][x, y] + y^2*Derivative[2, 2][f][x, y]

Those edge cases.

In[26]:= differentialOperate[ncTimes[1, 1], f[t]]

Out[26]= f[t]

We can declare a symbol to be scalar.

In[28]:= scalarQ[a] ^= True;

Now it will get pulled out as a simple multiplier.

In[29]:= differentialOperate[ncTimes[a, b], f[t]]

Out[29]= a b f[t]

---end edit---

Daniel Lichtblau Wolfram Research

share|improve this answer
    
@Daniel Usually is better to paste the crucial content with proper attribution. That way, if the referred link comes down, some knowledge is preserved here. The copyright restrictions usually don't get affected by a couple of attributed lines. –  belisarius Feb 11 '11 at 21:56
    
@Belisarius I beliee that link has remained intact since the conference in 1998. There is no problem with attribution or copyright (the author is unconcerned...). But yes, I'll post the code with application to the poster's example, when I get a chance. Today, I hope. –  Daniel Lichtblau Feb 11 '11 at 22:18
    
@Daniel, this is great! –  Qiang Li Feb 11 '11 at 22:29
    
@Daniel, your differentialOperate does not work in the simplest case differentialOperate[1 ** 1, f[t]]. What if I want to define this in the most non-disruptive way? –  Qiang Li Feb 11 '11 at 23:16
    
See edited response for actual code and example. –  Daniel Lichtblau Feb 11 '11 at 23:28

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