You shouldn't be ignoring the noise, but rather including it in the calculations. One solution is to try to put a bound on the noise, call it k. The problem can thus be thought of as:
x_B' = x_A + p + x, where -k <= x <= k
y_B' = y_A + q + x, where -k <= x <= k
The issue of course is that the actual value of p and q are obscured by the noise, for that reason I'm thinking you can only approximate what the value of p and q are. The goal is then to find the values for p and q where k is minimized. An extension of Sundar Nataraj's answer leads to the following O(N log N) solution in Python.
x_b = sorted(x_b) # Ensure x_b is in sorted order
y_b = sorted(y_b) # Ensure y_b is in sorted order
dx = [x_b[i] - x_a[i] for i in range(len(x_b)] # Obtain the x differences
dy = [y_b[i] - y_a[i] for i in range(len(y_b)] # Obtain the y differences
dx_range = (min(dx), max(dx)) # Find the x difference range
dy_range = (min(dy), max(dy)) # Find the y difference range
p = sum(dx_range) / 2.0 # Minimize k_x by making p the middle of the x range
q = sum(dy_range) / 2.0 # Minimize k_y by making q the middle of the y range
# Optionally, the k values can be calculated as well:
k_x = dx_max - p # Calculate k for x values
k_y = dy_max - q # Calculate k for y values
k = max(k_x,k_y) # Max of the dimensional k values is the actual k value
This appears to be an optimal solution for minimizing k_x and k_y. However, note that p and q are actually within the below ranges:
dx_min <= p <= dx_max
dy_min <= q <= dy_max
That being said, I'm thinking that statistically speaking, p and q should be rather close to the calculated values with fairly high probability.
Another look at Sundar Nataraj's answer got me thinking and it seemed like another way to estimate p and q would be to simply set them as the mean of the differences (extended from the original Python code). It doesn't change the range of values for p and q, but I think it leads to a more accurate estimation of p and q, since the actual min and max differences may be excessively high or low biasing excessively towards one side or the other.
p = sum(dx) / len(dx)
q = sum(dy) / len(dy)