Classical Monte Carlo Integration
## estimate pi
##
## I = \int H(x, y)dxdy
## where H(x, y) = 1 when x^2+y^2 <= 1;
## otherwise H(x, y) = 0
## volume
V = 4
n = 100000
x = runif(n, -1, 1)
y = runif(n, -1, 1)
H = x^2+y^2
H[H<=1] = 1
H[H>1] = 0
I = V* mean(H)
cat("I = ", I, "\n")
## n = 100, I = 2.96
## n = 1000, I = 3.22
## n = 10000, I = 3.1536
## n = 100000, I = 3.14504
The following Julia program can be used to do polar simulation.
using Statistics
function polarsim(x::Array)
while true
phi1 = rand()*2*pi
phi2 = rand()*pi - pi/2
u = rand()
xdotxi = x[1]*cos(phi1) + x[2]*sin(phi1)*cos(phi2) + x[3]*sin(phi1)*sin(phi2)
if u <= exp(xdotxi - sum(x.^2)/2)
return(randn() + xdotxi)
end
end
end
# approximate E^pi
function Epi(m, x = [0.1, 1.2, -0.7])
rhos = ones(m)
for i = 1:m
rhos[i] = 1/(2*polarsim(x)^2+3)
end
return(mean(rhos))
end
# example
Epi(10)
