I'm modeling a disease problem where each individual in a 2D landscape has a transmissibility described by a (radial basis) kernel function. My goal is to convolve the kernel with the population density such that the output captures the transmission risks across the landscape.
I performed the convolution using NumPy's 2D FFT and inverse-FFT functions. However, this forces a periodic/wrapped boundary condition in the result, which is unsuited for my model. Is there a way to convolve within the context of the original, fixed boundaries?
import numpy as np import random from math import * import matplotlib.pyplot as plt ''' Landscape parameters ''' L = 10. nx = 100 dx = L/nx hs = .5 * dx # half-step ulist = np.linspace(hs, L-hs, nx) ''' Radial Basis Function Kernel ''' alpha = 1. i, j = ulist.reshape(nx,1), ulist.reshape(1,nx) r = np.minimum(i-ulist, L-i+ulist)**2 + np.minimum(j-ulist, L-j+ulist)**2 rbf = sqrt(1 / (2 * alpha ** 2)) ker = np.exp(-(rbf * r) ** 2) ker = ker/np.sum(ker) ''' Population Density ''' ido = np.random.randint(nx, size=(1000,2)).astype(np.int) og = np.zeros((nx,nx)) np.add.at(og, (ido[:,0], ido[:,1]), 1) ''' Convolution via FFT and inverse-FFT ''' v1 = np.fft.fft2(ker) v2 = np.fft.fft2(og) v0 = np.fft.ifft2(v1*v2) dd = np.abs(v0) plt.plot(ido[:,1], ido[:,0], 'ko', alpha=.5) plt.imshow(dd, origin='origin') plt.show()