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基于 Agent的Python是怎么实现隔离仿真

发布时间:2021-12-18 17:23:05 来源:亿速云 阅读:175 作者:柒染 栏目:互联网科技

这篇文章给大家介绍基于 Agent的Python是怎么实现隔离仿真,内容非常详细,感兴趣的小伙伴们可以参考借鉴,希望对大家能有所帮助。

我会向你介绍用基于 Agent 的模型理解复杂现象的威力。为此,我们会用到一些 Python,社会学的案例分析和 Schelling 模型。

1. 案例分析

如果你观察多民族(multi-ethnic)混居城市的种族(racial)分布,你会对不可思议的种族隔离感到惊讶。举个例子,下面是美国人口普查局(US Census)用种族和颜色对应标记的纽约市地图。种族隔离清晰可见。

许多人会从这个现象中认定人是偏隘的(intolerant),不愿与其它种族比邻而居。然而进一步看,会发现细微的差别。2005 年的诺贝尔经济学奖得主托马斯·谢林(Thomas Schelling)在上世纪七十年代,就对这方面非常感兴趣,并建立了一个基于 Agent 的模型——“Schelling 隔离模型”的来解释这种现象。借助这个极其简单的模型,Schelling 会告诉我们,宏观所见并非微观所为(What’s going down)。

我们会借助 Schelling 模型模拟一些仿真来深刻理解隔离现象。

2. Schelling 隔离模型:设置和定义

基于 Agent 的模型需要三个参数:1)Agents,2)行为(规则)和 3)总体层面(aggregate level)的评估。在 Schelling 模型中,Agents 是市民,行为则是基于相似比(similarity ratio )的搬迁,而总体评估评估就是相似比。

假设城市有 n 个种族。我们用唯一的颜色来标识他们,并用网格来代表城市,每个单元格则是一间房。要么是空房子,要么有居民,且数量为 1。如果房子是空的,我们用白色标识。如果有居民,我们用此人的种群颜色来标识。我们把每个人周边房屋(上下左右、左上右上、左下右下)定义为邻居。

Schelling 的目的是想测试当居民更倾向于选择同种族的邻居(甚至多种族)时会如果发生什么。如果同种族邻居的比例上升到确定阈值(称之为相似性阈值(Similarity Threshold)),那么我们认为这个人已经满意(satisfied)了。如果还没有,就是不满意。

Schelling 的仿真如下。首先我们将人随机分配到城里并留空一些房子。对于每个居民,我们都会检查他(她)是否满意。如果满意,我们什么也不做。但如果不满意,我们把他分配到空房子。仿真经过几次迭代后,我们会观察最终的种族分布。

3. Schelling 模型的 Python 实现

早在上世纪 70 年代,Schelling 就用铅笔和硬币在纸上完成了他的仿真。我们现在则用 Python 来完成相同的仿真。

为了模拟仿真,我们首先导入一些必要的库。除了 Matplotlib 以外,其它库都是 Python 默认安装的。

Python

import matplotlib.pyplot as plt

import itertools

import random

import copy

 

接下来,定义名为 Schelling 的类,涉及到 6 个参数:城市的宽和高,空房子的比例,相似性阈值,迭代数和种族数。我们在这个类中定义了 4 个方法:populate,is_unsatisfied,update,move_to_empty, 还有 plot)。

Python

class Schelling:

    def __init__(self, width, height, empty_ratio, similarity_threshold, n_iterations, races = 2):

        self.width = width

        self.height = height

        self.races = races

        self.empty_ratio = empty_ratio

        self.similarity_threshold = similarity_threshold

        self.n_iterations = n_iterations

        self.empty_houses = []

        self.agents = {}

 

    def populate(self):

        ....

 

    def is_unsatisfied(self, x, y):

        ....

 

    def update(self):        

        ....

 

    def move_to_empty(self, x, y):

        ....

 

    def plot(self):

        ....

 

poplate 方法被用在仿真的开头,这个方法将居民随机分配在网格上。

Python

def populate(self):

    self.all_houses = list(itertools.product(range(self.width),range(self.height)))

    random.shuffle(self.all_houses)

 

    self.n_empty = int( self.empty_ratio * len(self.all_houses) )

    self.empty_houses = self.all_houses[:self.n_empty]

 

    self.remaining_houses = self.all_houses[self.n_empty:]

    houses_by_race = [self.remaining_houses[i::self.races] for i in range(self.races)]

    for i in range(self.races):

        # 为每个种族创建 agent

        self.agents = dict(

                            self.agents.items() +

                            dict(zip(houses_by_race[i], [i+1]*len(houses_by_race[i]))).items()

 

is_unsatisfied 方法把房屋的 (x, y) 坐标作为传入参数,查看同种群邻居的比例,如果比理想阈值(happiness threshold)高则返回 True,否则返回 False。

Python

def is_unsatisfied(self, x, y):

 

    race = self.agents[(x,y)]

    count_similar = 0

    count_different = 0

 

    if x > 0 and y > 0 and (x-1, y-1) not in self.empty_houses:

        if self.agents[(x-1, y-1)] == race:

            count_similar += 1

        else:

            count_different += 1

    if y > 0 and (x,y-1) not in self.empty_houses:

        if self.agents[(x,y-1)] == race:

            count_similar += 1

        else:

            count_different += 1

    if x < (self.width-1) and y > 0 and (x+1,y-1) not in self.empty_houses:

        if self.agents[(x+1,y-1)] == race:

            count_similar += 1

        else:

            count_different += 1

    if x > 0 and (x-1,y) not in self.empty_houses:

        if self.agents[(x-1,y)] == race:

            count_similar += 1

        else:

            count_different += 1        

    if x < (self.width-1) and (x+1,y) not in self.empty_houses:

        if self.agents[(x+1,y)] == race:

            count_similar += 1

        else:

            count_different += 1

    if x > 0 and y < (self.height-1) and (x-1,y+1) not in self.empty_houses:

        if self.agents[(x-1,y+1)] == race:

            count_similar += 1

        else:

            count_different += 1        

    if x > 0 and y < (self.height-1) and (x,y+1) not in self.empty_houses:

        if self.agents[(x,y+1)] == race:

            count_similar += 1

        else:

            count_different += 1        

    if x < (self.width-1) and y < (self.height-1) and (x+1,y+1) not in self.empty_houses:

        if self.agents[(x+1,y+1)] == race:

            count_similar += 1

        else:

            count_different += 1

 

    if (count_similar+count_different) == 0:

        return False

    else:

        return float(count_similar)/(count_similar+count_different) < self.happy_threshold

 

update 方法将查看网格上的居民是否尚未满意,如果尚未满意,将随机把此人分配到空房子中。并模拟 n_iterations 次。

Python

def update(self):

    for i in range(self.n_iterations):

        self.old_agents = copy.deepcopy(self.agents)

        n_changes = 0

        for agent in self.old_agents:

            if self.is_unhappy(agent[0], agent[1]):

                agent_race = self.agents[agent]

                empty_house = random.choice(self.empty_houses)

                self.agents[empty_house] = agent_race

                del self.agents[agent]

                self.empty_houses.remove(empty_house)

                self.empty_houses.append(agent)

                n_changes += 1

        print n_changes

        if n_changes == 0:

            break

 

move_to_empty 方法把房子坐标(x, y)作为传入参数,并将 (x, y) 房间内的居民迁入空房子。这个方法被 update 方法调用,会把尚不满意的人迁入空房子。

Python

def move_to_empty(self, x, y):

    race = self.agents[(x,y)]

    empty_house = random.choice(self.empty_houses)

    self.updated_agents[empty_house] = race

    del self.updated_agents[(x, y)]

    self.empty_houses.remove(empty_house)

    self.empty_houses.append((x, y))

 

plot 方法用来绘制整个城市和居民。我们随时可以调用这个方法来了解城市的居民分布。这个方法有两个传入参数:title 和 file_name。

Python

def plot(self, title, file_name):

    fig, ax = plt.subplots()

    # 如果要进行超过 7 种颜色的仿真,你应该相应地进行设置

    agent_colors = {1:'b', 2:'r', 3:'g', 4:'c', 5:'m', 6:'y', 7:'k'}

    for agent in self.agents:

        ax.scatter(agent[0]+0.5, agent[1]+0.5, color=agent_colors[self.agents[agent]])

 

    ax.set_title(title, fontsize=10, fontweight='bold')

    ax.set_xlim([0, self.width])

    ax.set_ylim([0, self.height])

    ax.set_xticks([])

    ax.set_yticks([])

    plt.savefig(file_name)

 

4. 仿真

现在我们实现了 Schelling 类,可以模拟仿真并绘制结果。我们会按照下面的需求(characteristics)进行三次仿真:

  • 宽 = 50,而高 = 50(包含 2500 间房子)

  • 30% 的空房子

  • 相似性阈值 = 30%(针对仿真 1),相似性阈值 = 50%(针对仿真 2),相似性阈值 = 80%(针对仿真 3)

  • 最大迭代数 = 500

  • 种族数量 = 2

创建并“填充”城市。

Python

schelling_1 = Schelling(50, 50, 0.3, 0.3, 500, 2)

schelling_1.populate()

 

schelling_2 = Schelling(50, 50, 0.3, 0.5, 500, 2)

schelling_2.populate()

 

schelling_3 = Schelling(50, 50, 0.3, 0.8, 500, 2)

schelling_3.populate()

 

接下来,我们绘制初始阶段的城市。注意,相似性阈值在城市的初始状态不起作用。

Python

schelling_1_1.plot('Schelling Model with 2 colors: Initial State', 'schelling_2_initial.png')

 

下面我们运行 update 方法,绘制每个相似性阈值的最终分布。

Python

schelling_1.update()

schelling_2.update()

schelling_3.update()

 

schelling_1.plot('Schelling Model with 2 colors: Final State with Similarity Threshold 30%', 'schelling_2_30_final.png')

schelling_2.plot('Schelling Model with 2 colors: Final State with Similarity Threshold 50%', 'schelling_2_50_final.png')

schelling_3.plot('Schelling Model with 2 colors: Final State with Similarity Threshold 80%', 'schelling_2_80_final.png')

 

我们发现相似性阈值越高,城市的隔离度就越高。此外,我们还会发现即便相似性阈值很小,城市依旧会产生隔离。换言之,即使居民非常包容(tolerant)(相当于相似性阈值很小),还是会以隔离告终。我们可以总结出:宏观所见并非微观所为。

5. 测量隔离

以上仿真,我们只通过可视化来确认隔离发生。然而,我们却没有对隔离的计算进行定量评估。本节我们会定义这个评估标准,我们也会模拟一些仿真来确定理想阈值和隔离程度的关系。

首先在 Schelling 类中添加 calculate_similarity 方法。这个方法会计算每个 Agent 的相似性并得出均值。我们会用平均相似比评估隔离程度。

Python

def calculate_similarity(self):

    similarity = []

    for agent in self.agents:

        count_similar = 0

        count_different = 0

        x = agent[0]

        y = agent[1]

        race = self.agents[(x,y)]

        if x > 0 and y > 0 and (x-1, y-1) not in self.empty_houses:

            if self.agents[(x-1, y-1)] == race:

                count_similar += 1

            else:

                count_different += 1

        if y > 0 and (x,y-1) not in self.empty_houses:

            if self.agents[(x,y-1)] == race:

                count_similar += 1

            else:

                count_different += 1

        if x < (self.width-1) and y > 0 and (x+1,y-1) not in self.empty_houses:

            if self.agents[(x+1,y-1)] == race:

                count_similar += 1

            else:

                count_different += 1

        if x > 0 and (x-1,y) not in self.empty_houses:

            if self.agents[(x-1,y)] == race:

                count_similar += 1

            else:

                count_different += 1        

        if x < (self.width-1) and (x+1,y) not in self.empty_houses:

            if self.agents[(x+1,y)] == race:

                count_similar += 1

            else:

                count_different += 1

        if x > 0 and y < (self.height-1) and (x-1,y+1) not in self.empty_houses:

            if self.agents[(x-1,y+1)] == race:

                count_similar += 1

            else:

                count_different += 1        

        if x > 0 and y < (self.height-1) and (x,y+1) not in self.empty_houses:

            if self.agents[(x,y+1)] == race:

                count_similar += 1

            else:

                count_different += 1        

        if x < (self.width-1) and y < (self.height-1) and (x+1,y+1) not in self.empty_houses:

            if self.agents[(x+1,y+1)] == race:

                count_similar += 1

            else:

                count_different += 1

        try:

            similarity.append(float(count_similar)/(count_similar+count_different))

        except:

            similarity.append(1)

    return sum(similarity)/len(similarity)

 

接下去,我们算出每个相似性阈值的平均相似比,并绘制出相似性阈值和相似比之间的关系。

Python

similarity_threshold_ratio = {}

for i in [0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7]:

    schelling = Schelling(50, 50, 0.3, i, 500, 2)

    schelling.populate()

    schelling.update()

    similarity_threshold_ratio[i] = schelling.calculate_similarity()

 

fig, ax = plt.subplots()

plt.plot(similarity_threshold_ratio.keys(), similarity_threshold_ratio.values(), 'ro')

ax.set_title('Similarity Threshold vs. Mean Similarity Ratio', fontsize=15, fontweight='bold')

ax.set_xlim([0, 1])

ax.set_ylim([0, 1.1])

ax.set_xlabel("Similarity Threshold")

ax.set_ylabel("Mean Similarity Ratio")

plt.savefig('schelling_segregation_measure.png')

 

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