[PyTorch][chapter 62][强化学习-基本概念]
前言:
目录:
- 强化学习概念
- 马尔科夫决策
- Bellman 方程
- 格子世界例子
一 强化学习
强化学习 必须在尝试之后,才能发现哪些行为会导致奖励的最大化。
当前的行为可能不仅仅会影响即时奖赏,还有影响下一步奖赏和所有奖赏
强化学习五要素如下:
![[PyTorch][chapter 62][强化学习-基本概念]_第1张图片](http://img.e-com-net.com/image/info8/b5688a1db71849318ceddfbaf8886dc1.jpg)
1.2 强化学习流程
![[PyTorch][chapter 62][强化学习-基本概念]_第2张图片](http://img.e-com-net.com/image/info8/02157bbce51e46b2923f59247b2732de.jpg)
1: 产生轨迹(trajectory)
2: 策略评估(policy-evaluate)
3: 策略提升(policy-improve)
这里重点讲一下 产生轨迹:
当前处于某个state 下面,
按照策略选择 action =
根据新的state 给出 reward:
最后产生了轨迹链
![[PyTorch][chapter 62][强化学习-基本概念]_第3张图片](http://img.e-com-net.com/image/info8/0b7e3c4094684b3cbfb0a11b0f2e88d0.jpg)
二 马尔科夫决策
2.1 马尔科夫决策要求:
1: 能够检测到理想的状态
2: 可以多次尝试
3: 系统的下个状态只与当前信息有关,与更早的状态无关。
决策过程中还可和当前采取的动作有关.
2.2 马尔科夫决策五要素
S: 状态集合 states
A: 动作集合 actions
P: 状态转移概率 
R: 奖励函数(reward function) ,agent 采取某个动作后的及时奖励
r: 折扣系数意味当下的reward 比未来反馈更重要
![r \in (0,1]](http://img.e-com-net.com/image/info8/809e267145554046867f77a54aadc3f3.png){kind=small}
2.3 主要流程
1: Agent 处于状态
2: 按照策略 选择动作 
3:执行该动作后,有一定的概率转移到新的状态 
![[PyTorch][chapter 62][强化学习-基本概念]_第4张图片](http://img.e-com-net.com/image/info8/1b0ebd46a34844478e20f8c380b53c18.jpg)
2.4 价值函数
当前时刻处于状态s,未来获得期望的累积奖赏
分为两种: state 价值函数 state-action 价值函数
最优价值函数:
不同策略下, 累积奖赏最大的 
2.5 策略 policy
当前状态s 下,按照策略,要采用的动作
三 Bellman 方程
4.1 状态值函数为:
![V_{T}^{\pi}(x)=E_{\pi}[\frac{1}{T}\sum_{t=1}^Tr_t|x_0=x]](http://img.e-com-net.com/image/info8/d8d27ff52b204bd290791c803085e541.png)
: T 步累积奖赏
![V_{\gamma}^{T}(x)=E_{\pi}[\frac{1}{T}\sum_{t=0}^T \gamma^tr_{t+1}|x_0=x]](http://img.e-com-net.com/image/info8/587301eeae174cc4ac7456f929bfef29.png)
:
折扣累积奖赏,![\gamma \in (0,1]](http://img.e-com-net.com/image/info8/9398c11fc91245ac875f5f417f1e406b.png)
4.2 Bellman 方程
证明:
![V_{T}^{\pi}(x)=E_{\pi}[\frac{1}{T}\sum_{t=1}^T r_t|x_0=x]](http://img.e-com-net.com/image/info8/bae4dcaa62ad4537ad73352f4fbb36e6.png)
![=E_{\pi}[\frac{1}{T}r_1+\frac{T-1}{T}\frac{1}{T-1}\sum_{t=2}^T r_t|x_0=x]](http://img.e-com-net.com/image/info8/95e449c27a164edebd59c59a0ebdbee6.png)
![=\sum_{a \in A} \pi(x,a) \sum _{x^{'} \in X}P_{x\rightarrow x^{'}}^a (\frac{1}{T}R_{x\rightarrow x^{'}}^{a}+\frac{T-1}{T}E_{\pi}[\frac{1}{T-1}\sum_{t=1}^{T-1}r_t|x_0=x^{'}])](http://img.e-com-net.com/image/info8/8d63e016f5a64a58a76037e49a5819ea.png)
r折扣奖赏bellman 方程
四 格子世界例子
在某个格子,执行上下左右步骤,其中步骤最短的
为最优路径
![[PyTorch][chapter 62][强化学习-基本概念]_第5张图片](http://img.e-com-net.com/image/info8/ac3be6d2e6714426a2fb7b1ecf1a41ab.jpg)
5.1:gridword.py
import numpy as np
#手动输入格子的大小
WORLD_SIZE = 4
START_POS = [0,0]
END_POS = [WORLD_SIZE-1, WORLD_SIZE-1]
prob = 1.0
#折扣因子
DISCOUNT = 0.9
# 动作集={上,下,左,右}
ACTIONS = [np.array([0, -1]), #left
np.array([-1, 0]), # up
np.array([0, 1]), # right
np.array([1, 0])] # down
class GridwordEnv():
def action_name(self, action):
if action ==0:
name = "左"
elif action ==1:
name = "上"
elif action ==2:
name = "右"
else:
name = "上"
return name
def __init__(self):
self.nA = 4 #action:上下左右
self.nS = 16 #state: 16个状态
self.S = []
for i in range(WORLD_SIZE):
for j in range(WORLD_SIZE):
state =[i,j]
self.S.append(state)
def step(self, s, a):
action = ACTIONS[a]
state = self.S[s]
done = False
reward = 0.0
next_state = (np.array(state) + action).tolist()
if (next_state == START_POS) or (state == START_POS):
next_state = START_POS
done = True
elif (next_state == END_POS) or (state == START_POS):
next_state = END_POS
done = True
else:
x, y = next_state
# 判断是否出界
if x < 0 or x >= WORLD_SIZE or y < 0 or y >= WORLD_SIZE:
reward = -1.0
next_state = state
else:
reward = -1.0
return prob, next_state, reward,done
5.2 main.py
# -*- coding: utf-8 -*-
"""
Created on Mon Nov 13 09:39:37 2023
@author: chengxf2
"""
import numpy as np
def init_state(WORLD_SIZE):
S =[]
for i in range(WORLD_SIZE):
for j in range(WORLD_SIZE):
state =[i,j]
S.append(state)
print(S)
# -*- coding: utf-8 -*-
"""
Created on Fri Nov 10 16:48:16 2023
@author: chengxf2
"""
import numpy as np
import sys
from gym.envs.toy_text import discrete #环境
from enum import Enum
from gridworld import GridwordEnv
class Agent():
def __init__(self,env):
self.discount_factor = 1.0 #折扣率
self.theta = 1e-3 #最大偏差
self.S = []
self.env = env
#当前处于的位置,V 累积奖赏
def one_step_lookahead(self,s, v):
R = np.zeros((env.nA)) #不同action的累积奖赏
for action in range(env.nA):
prob, next_state,reward, done = env.step(s, action) #只有一个
next_state_index = self.env.S.index(next_state)
#print("\n state",s ,"\t action ",action, "\t new_state ", next_state,"\t next_state_index ", next_state_index,"\t r: ",reward)
r= prob*(reward + self.discount_factor*v[next_state_index])
R[action] +=r
#print("\n state ",s, "\t",R)
return R
def value_iteration(self, env, theta= 1e-3, discount_factor =1.0):
v = np.zeros((env.nS)) #不同状态下面的累积奖赏,16个状态
iterNum = 0
while True:
delta = 0.0
for s in range(env.nS):
R = self.one_step_lookahead(s,v)#在4个方向上面得到的累积奖赏
best_action_value = np.max(R)
#print("\n state ",s, "\t R ",R, "\t best_action_value ",best_action_value)
bias = max(delta, np.abs(best_action_value-v[s]))
v[s] =best_action_value
#if (s+1)%4 == 0:
#print("\n -----s ------------",s)
iterNum +=1
if bias参考:
【强化学习玩游戏】1小时竟然就学会了强化学习dqn算法原理及实战(人工智能自动驾驶/深度强化学习/强化学习算法/强化学习入门/多智能体强化学习)_哔哩哔哩_bilibili
2-强化学习基本概念_哔哩哔哩_bilibili
3-马尔科夫决策过程_哔哩哔哩_bilibili
4-Bellman方程_哔哩哔哩_bilibili
5-值迭代求解_哔哩哔哩_bilibili