My goal is to compute the n-fold self-convolution of a function rho(eta) where eta > 0, using MuPAD. (The background are energy densities of systems composed of many identical subsystems.) I tried to start with a simple case, but I'm already getting stuck there:
I define rho(eta) to be constantly 1 for eta > 0, so it is a Heaviside function:
rho := eta -> heaviside(eta)
and I implement the 2-fold self-convolution using a double integral and a Dirac delta function:
int(int(rho(etaA) * rho(etaB) * dirac(etaA + etaB - energy), etaB = 0..infinity), etaA=0..infinity)
with the result
so MuPAD wasn't even able to simplify the integral over a delta function and obtain a normal convolution expression; no idea what's going on with the limit here.
If I just directly enter the normal convolution expression of the function with itself
int(rho(etaA) * rho(energy - etaA), etaA = 0..infinity)
I get
again with a limit (which could be simplified to 0, or couldn't it?). The second term comes actually close to the correct answer, the heaviside
just accounts for the possibility that energy
may be negative. Ok, so I tell MuPAD that energy
is positive:
int(rho(etaA) * rho(energy - etaA), etaA = 0..infinity) assuming energy > 0
and now MuPAD just gives me back the original unchanged integral:
Well, maybe using heaviside
is the problem, and it is not strictly necessary anyway since I implement the constraint to eta > 0 through the integration limits. So I redefine
rho := eta -> 1
and use the formula with the delta function, plus the information that energy
is positive:
int(int(rho(etaA) * rho(etaB) * dirac(etaA + etaB - energy), etaB = 0..infinity), etaA=0..infinity) assuming energy > 0
Guess what? Now MuPAD returns a heaviside by itself:
which is correct – but why doesn't it evaluate this integral? It's not that hard, is it?
So please anyone tell me: Why is all this happening? And how can I make it work?