#!/bin/python """ main.py - Part of ants project execute via `python main.py` in terminal or only UNIX: `./main.py` License: AGPL 3 (see end of file) (C) Alexander Bocken, Viviane Fahrni, Grace Kagho """ from model import ActiveWalkerModel from agent import RandomWalkerAnt import numpy as np import matplotlib.pyplot as plt from mesa.space import Coordinate def main(): check_pheromone_exponential_decay() check_ant_sensitivity_linear_decay() check_ant_pheromone_exponential_decay() def check_pheromone_exponential_decay(): """ Check whether wanted exponential decay of pheromones on grid is done correctly shows plot of pheromone placed on grid vs. equivalent exponential decay function """ from mesa.datacollection import DataCollector width = 21 height = width num_initial_roamers = 0 num_max_agents = 100 nest_position : Coordinate = (width //2, height //2) max_steps = 1000 model = ActiveWalkerModel(width=width, height=height, num_initial_roamers=num_initial_roamers, nest_position=nest_position, num_max_agents=num_max_agents, max_steps=max_steps) model.grid.fields["A"][5,5] = 10 model.datacollector = DataCollector( model_reporters={"pheromone_a": lambda m: m.grid.fields["A"][5,5] }, agent_reporters={} ) model.run_model() a_test = model.datacollector.get_model_vars_dataframe()["pheromone_a"] import matplotlib.pyplot as plt import numpy as np plt.figure() xx = np.linspace(0,1000, 10000) yy = a_test[0]*np.exp(-model.decay_rates["A"]*xx) plt.plot(xx, yy, label="correct exponential function") plt.scatter(range(len(a_test)), a_test, label="modeled decay", marker='o') plt.title("Exponential grid pheromone decay test") plt.legend(loc='best') plt.show() def check_ant_sensitivity_linear_decay(): """ Check whether wanted linear decay of ant sensitivity is done correctly shows plot of ant sensitivity placed on grid vs. equivalent linear decay function not food sources are on the grid for this run to not reset sensitivities """ from mesa.datacollection import DataCollector width = 50 height = width num_initial_roamers = 1 num_max_agents = 100 nest_position : Coordinate = (width //2, height //2) max_steps = 1000 num_food_sources = 0 model = ActiveWalkerModel(width=width, height=height, num_initial_roamers=num_initial_roamers, nest_position=nest_position, num_max_agents=num_max_agents, num_food_sources=num_food_sources, max_steps=max_steps) model.datacollector = DataCollector( model_reporters={}, agent_reporters={"sensitivity": lambda a: a.sensitivity} ) start = model.schedule.agents[0].sensitivity_decay_rate model.run_model() a_test = model.datacollector.get_agent_vars_dataframe().reset_index()["sensitivity"] import matplotlib.pyplot as plt import numpy as np plt.figure() xx = np.linspace(0,1000, 10000) yy = a_test[0] - start*xx plt.title("Linear Ant Sensitivity decay test") plt.plot(xx, yy, label="correct linear function") plt.scatter(range(len(a_test)), a_test, label="modeled decay", marker='o') plt.legend(loc='best') plt.show() def check_ant_pheromone_exponential_decay(): """ Check whether wanted exponential decay of pheromone drop rate for ants is correctly modeled shows plot of pheromone placed on grid vs. equivalent exponential decay function """ from mesa.datacollection import DataCollector width = 50 height = width num_initial_roamers = 1 num_max_agents = 100 nest_position : Coordinate = (width //2, height //2) max_steps = 1000 model = ActiveWalkerModel(width=width, height=height, num_initial_roamers=num_initial_roamers, nest_position=nest_position, num_max_agents=num_max_agents, max_steps=max_steps) model.datacollector = DataCollector( model_reporters={}, agent_reporters={"pheromone_drop_rate": lambda a: a.pheromone_drop_rate["A"]} ) start = model.schedule.agents[0].pheromone_drop_rate["A"] model.run_model() a_test = model.datacollector.get_agent_vars_dataframe().reset_index()["pheromone_drop_rate"] import matplotlib.pyplot as plt import numpy as np plt.figure() xx = np.linspace(0,1000, 10000) yy = a_test[0]*np.exp(-model.schedule.agents[0].betas["A"]*xx) plt.plot(xx, yy, label="correct exponential function") plt.scatter(range(len(a_test)), a_test, label="modeled decay", marker='o') plt.title("Exponential pheromone drop rate decay test") plt.legend(loc='best') plt.show() if __name__ == "__main__": main() """ This program is free software: you can redistribute it and/or modify it under the terms of the GNU Affero General Public License as published by the Free Software Foundation, version 3. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for more details. You should have received a copy of the GNU Affero General Public License along with this program. If not, see """