2024-heraklion-scientific-p.../notebooks/walker/Step_6_loading_parameters_from_file/walker.py

import numpy as np


class Walker:
    """ The Walker knows how to walk at random on a context map. """

    def __init__(self, sigma_i, sigma_j, context_map):
        self.sigma_i = sigma_i
        self.sigma_j = sigma_j
        self.size = context_map.shape[0]
        # Make sure that the context map is normalized
        context_map /= context_map.sum()
        self.context_map = context_map

        # Pre-compute a 2D grid of coordinates for efficiency
        self._grid_ii, self._grid_jj = np.mgrid[0:self.size, 0:self.size]

    # --- Walker public interface

    def sample_next_step(self, current_i, current_j, random_state=np.random):
        """ Sample a new position for the walker. """

        # Combine the next-step proposal with the context map to get a
        # next-step probability map
        next_step_map = self._next_step_proposal(current_i, current_j)
        selection_map = self._compute_next_step_probability(next_step_map)

        # Draw a new position from the next-step probability map
        r = random_state.rand()
        cumulative_map = np.cumsum(selection_map)
        cumulative_map = cumulative_map.reshape(selection_map.shape)
        i_next, j_next = np.argwhere(cumulative_map >= r)[0]

        return i_next, j_next

    # --- Walker non-public interface

    def _next_step_proposal(self, current_i, current_j):
        """ Create the 2D proposal map for the next step of the walker. """

        # 2D Gaussian distribution , centered at current position,
        # and with different standard deviations for i and j
        grid_ii, grid_jj = self._grid_ii, self._grid_jj
        sigma_i, sigma_j = self.sigma_i, self.sigma_j

        rad = (
            (((grid_ii - current_i) ** 2) / (sigma_i ** 2))
            + (((grid_jj - current_j) ** 2) / (sigma_j ** 2))
        )

        p_next_step = np.exp(-(rad / 2.0)) / (2.0 * np.pi * sigma_i * sigma_j)
        return p_next_step / p_next_step.sum()

    def _compute_next_step_probability(self, next_step_map):
        """ Compute the next step probability map from next step proposal and
        context map. """
        next_step_probability = next_step_map * self.context_map
        next_step_probability /= next_step_probability.sum()
        return next_step_probability
Material for ASPP 2024 2024-08-27 14:52:41 +02:00			`import numpy as np`


			`class Walker:`
			`""" The Walker knows how to walk at random on a context map. """`

			`def __init__(self, sigma_i, sigma_j, context_map):`
			`self.sigma_i = sigma_i`
			`self.sigma_j = sigma_j`
			`self.size = context_map.shape[0]`
			`# Make sure that the context map is normalized`
			`context_map /= context_map.sum()`
			`self.context_map = context_map`

			`# Pre-compute a 2D grid of coordinates for efficiency`
			`self._grid_ii, self._grid_jj = np.mgrid[0:self.size, 0:self.size]`

			`# --- Walker public interface`

			`def sample_next_step(self, current_i, current_j, random_state=np.random):`
			`""" Sample a new position for the walker. """`

			`# Combine the next-step proposal with the context map to get a`
			`# next-step probability map`
			`next_step_map = self._next_step_proposal(current_i, current_j)`
			`selection_map = self._compute_next_step_probability(next_step_map)`

			`# Draw a new position from the next-step probability map`
			`r = random_state.rand()`
			`cumulative_map = np.cumsum(selection_map)`
			`cumulative_map = cumulative_map.reshape(selection_map.shape)`
			`i_next, j_next = np.argwhere(cumulative_map >= r)[0]`

			`return i_next, j_next`

			`# --- Walker non-public interface`

			`def _next_step_proposal(self, current_i, current_j):`
			`""" Create the 2D proposal map for the next step of the walker. """`

			`# 2D Gaussian distribution , centered at current position,`
			`# and with different standard deviations for i and j`
			`grid_ii, grid_jj = self._grid_ii, self._grid_jj`
			`sigma_i, sigma_j = self.sigma_i, self.sigma_j`

			`rad = (`
			`(((grid_ii - current_i) 2) / (sigma_i 2))`
			`+ (((grid_jj - current_j) 2) / (sigma_j 2))`
			`)`

			`p_next_step = np.exp(-(rad / 2.0)) / (2.0 * np.pi * sigma_i * sigma_j)`
			`return p_next_step / p_next_step.sum()`

			`def _compute_next_step_probability(self, next_step_map):`
			`""" Compute the next step probability map from next step proposal and`
			`context map. """`
			`next_step_probability = next_step_map * self.context_map`
			`next_step_probability /= next_step_probability.sum()`
			`return next_step_probability`