Journal of Frontiers of Computer Science and Technology ›› 2022, Vol. 16 ›› Issue (2): 261-279.DOI: 10.3778/j.issn.1673-9418.2107040
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WANG Yang, CHEN Zhibin+(), WU Zhaorui, GAO Yuan
Received:
2021-07-12
Revised:
2021-09-16
Online:
2022-02-01
Published:
2021-09-24
About author:
WANG Yang, born in 1997, M.S. candidate. His research interests include combinatorial optimization, reinforcement learning, deep reinforcement learning, etc.Supported by:
通讯作者:
+ E-mail: chenzhibin311@126.com作者简介:
王扬(1997—),男,山东烟台人,硕士研究生,主要研究方向为组合最优化、强化学习、深度强化学习等。基金资助:
CLC Number:
WANG Yang, CHEN Zhibin, WU Zhaorui, GAO Yuan. Review of Reinforcement Learning for Combinatorial Optimization Problem[J]. Journal of Frontiers of Computer Science and Technology, 2022, 16(2): 261-279.
王扬, 陈智斌, 吴兆蕊, 高远. 强化学习求解组合最优化问题的研究综述[J]. 计算机科学与探索, 2022, 16(2): 261-279.
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研究方法 | 作者 | 年份 | 研究问题 | 模型和算法 | 优化效果 |
---|---|---|---|---|---|
基于神经组合最优化模型的求解方法 | Bello等人[ | 2016年 | TSP+KP | PN+REINFORCE、A3C、 主动搜索算法 | TSP:优于文献[ KP:达到最优解 |
Chen等人[ | 2019年 | CVRP+JSP+表达简化 | PN、NeuRewriter框架+ Q-AC | 20-VRP:达到最优解 JSP:优于OR-Tools、DeepRM | |
Joshi等人[ | 2019年 | TSP | PN+GCN、波束搜索、采样、贪婪搜索 | 20,50,100-TSP:优于文献[ | |
Li等人[ | 2021年 | CSP | PN+REINFORCE、MHA、自注意力机制 | 优于目前基于深度学习的方法,求解时间快于LS1、LS2算法(20倍) | |
基于动态输入的组合最优化模型的求解方法 | Nazari等人[ | 2018年 | TSP+VRP+CVRP+SVRP | REINFORCE+A3C+ Rollout+PN | 优化效果与文献[ |
Emami等人[ | 2018年 | TSP+Matching+Sorting | RL框架+PN-AC、 SPG算法、AC | TSP:优于文献[ Matching:最优间隙可达0.003% | |
Kool等人[ | 2018年 | TSP+OP+VRP+PCTSP | Transformer+Attention、 REINFORCE、Rollout | 20,50,100-TSP:优于文献[ 20,50,100-CVRP:接近Gurobi | |
Oren等人[ | 2021年 | PMSP+CVRP | SOLO框架+MCTS、DQN | 优于OR-Tools、CPLEX,降低了在线求解的时间,减少解空间的搜索范围 | |
基于图结构模型的求解方法 | Dai等人[ | 2017年 | MVC+TSP+Max-cut+SCP | S2V-DQN框架+Q-学习、 贪婪算法 | MVC、TSP、Max-cut接近最优解,扩大求解范围,提高模型的泛化能力 |
Abe等人[ | 2019年 | MVC+MC+Max-cut | CombOpt Zero框架+GNNs、MCTS | 优于文献[ | |
Mittal等人[ | 2019年 | MF+MVC+MCP | GCOMB框架+GCN、DQN | MF:求解时间相比SOTA算法提高100倍 MVC、MCP:优于文献[ | |
Drori等人[ | 2020年 | TSP+VRP+MST+SSP | Model-free RL框架、 GNNs+GAT、Attention | TSP:优于文献[ MST、SSP:求解时间快于文献[ | |
Bresson等人[ | 2021年 | TSP | Transformer+MHA、BFS算法 | 优于Concorde、LKH3,TSP50最优间隙达到0.004%,TSP100最优间隙达到0.39% | |
基于强化学习结合传统算法的求解方法 | Deudon等人[ | 2018年 | TSP、VRP | Transformer+LKH3、 REINFORCE、MHA | 20,50,100-TSP:加入2-opt操作后,优于文献[ |
Cappart等人[ | 2020年 | TSP+TSPTW+PORT | Transformer+GAT+PPO、BaB-DQN搜索算法 | 优于单个RL算法和CP算法,与Non-linear 求解器优化效果相当 | |
Gao等人[ | 2020年 | VRP+CVRP+CVRPTW | GAT+AC、PPO、VLNS算法 | VRP:优于多个启发式算法 CVRP:最优间隙为0.58%,扩大求解范围 | |
Zheng等人[ | 2020年 | TSP、111个TSP数据集 | VSR-LKH3框架+Q-学习、Sarsa、蒙特卡罗 | 结合3个RL算法,优于文献[ | |
基于改进强化学习模型的求解方法 | Silva等人[ | 2019年 | VRPTW+UPMS-ST | AMAM+Q-学习、ILS-LA、ILS-Q、VND | 优于其他传统算法和单智能体的优化效果 |
Ma等人[ | 2019年 | TSP+TSPTW | GPNS+逐层策略优化算法、分层算法、2-opt | 优于OR-Tools和蚁群算法,GPN模型可以有效求解大范围TSP问题 | |
Lu等人[ | 2020年 | CVRP | Transformer+Attention、 REINFORCE、Rollout | 100-CVRP:优于LKH3,达到目前最优的结果(15.57),求解速度超过OR-Tools | |
Li等人[ | 2020年 | TSP、MOTSP | DRL-MOA框架+AC | 优于NSGA-Ⅱ、MOEA/D、MOGLS,相比传统算法有更快的求解速度和泛化能力 |
Table 1 Analysis and summary of research methods, solving problems and models
研究方法 | 作者 | 年份 | 研究问题 | 模型和算法 | 优化效果 |
---|---|---|---|---|---|
基于神经组合最优化模型的求解方法 | Bello等人[ | 2016年 | TSP+KP | PN+REINFORCE、A3C、 主动搜索算法 | TSP:优于文献[ KP:达到最优解 |
Chen等人[ | 2019年 | CVRP+JSP+表达简化 | PN、NeuRewriter框架+ Q-AC | 20-VRP:达到最优解 JSP:优于OR-Tools、DeepRM | |
Joshi等人[ | 2019年 | TSP | PN+GCN、波束搜索、采样、贪婪搜索 | 20,50,100-TSP:优于文献[ | |
Li等人[ | 2021年 | CSP | PN+REINFORCE、MHA、自注意力机制 | 优于目前基于深度学习的方法,求解时间快于LS1、LS2算法(20倍) | |
基于动态输入的组合最优化模型的求解方法 | Nazari等人[ | 2018年 | TSP+VRP+CVRP+SVRP | REINFORCE+A3C+ Rollout+PN | 优化效果与文献[ |
Emami等人[ | 2018年 | TSP+Matching+Sorting | RL框架+PN-AC、 SPG算法、AC | TSP:优于文献[ Matching:最优间隙可达0.003% | |
Kool等人[ | 2018年 | TSP+OP+VRP+PCTSP | Transformer+Attention、 REINFORCE、Rollout | 20,50,100-TSP:优于文献[ 20,50,100-CVRP:接近Gurobi | |
Oren等人[ | 2021年 | PMSP+CVRP | SOLO框架+MCTS、DQN | 优于OR-Tools、CPLEX,降低了在线求解的时间,减少解空间的搜索范围 | |
基于图结构模型的求解方法 | Dai等人[ | 2017年 | MVC+TSP+Max-cut+SCP | S2V-DQN框架+Q-学习、 贪婪算法 | MVC、TSP、Max-cut接近最优解,扩大求解范围,提高模型的泛化能力 |
Abe等人[ | 2019年 | MVC+MC+Max-cut | CombOpt Zero框架+GNNs、MCTS | 优于文献[ | |
Mittal等人[ | 2019年 | MF+MVC+MCP | GCOMB框架+GCN、DQN | MF:求解时间相比SOTA算法提高100倍 MVC、MCP:优于文献[ | |
Drori等人[ | 2020年 | TSP+VRP+MST+SSP | Model-free RL框架、 GNNs+GAT、Attention | TSP:优于文献[ MST、SSP:求解时间快于文献[ | |
Bresson等人[ | 2021年 | TSP | Transformer+MHA、BFS算法 | 优于Concorde、LKH3,TSP50最优间隙达到0.004%,TSP100最优间隙达到0.39% | |
基于强化学习结合传统算法的求解方法 | Deudon等人[ | 2018年 | TSP、VRP | Transformer+LKH3、 REINFORCE、MHA | 20,50,100-TSP:加入2-opt操作后,优于文献[ |
Cappart等人[ | 2020年 | TSP+TSPTW+PORT | Transformer+GAT+PPO、BaB-DQN搜索算法 | 优于单个RL算法和CP算法,与Non-linear 求解器优化效果相当 | |
Gao等人[ | 2020年 | VRP+CVRP+CVRPTW | GAT+AC、PPO、VLNS算法 | VRP:优于多个启发式算法 CVRP:最优间隙为0.58%,扩大求解范围 | |
Zheng等人[ | 2020年 | TSP、111个TSP数据集 | VSR-LKH3框架+Q-学习、Sarsa、蒙特卡罗 | 结合3个RL算法,优于文献[ | |
基于改进强化学习模型的求解方法 | Silva等人[ | 2019年 | VRPTW+UPMS-ST | AMAM+Q-学习、ILS-LA、ILS-Q、VND | 优于其他传统算法和单智能体的优化效果 |
Ma等人[ | 2019年 | TSP+TSPTW | GPNS+逐层策略优化算法、分层算法、2-opt | 优于OR-Tools和蚁群算法,GPN模型可以有效求解大范围TSP问题 | |
Lu等人[ | 2020年 | CVRP | Transformer+Attention、 REINFORCE、Rollout | 100-CVRP:优于LKH3,达到目前最优的结果(15.57),求解速度超过OR-Tools | |
Li等人[ | 2020年 | TSP、MOTSP | DRL-MOA框架+AC | 优于NSGA-Ⅱ、MOEA/D、MOGLS,相比传统算法有更快的求解速度和泛化能力 |
作者 | 模型局限性分析 |
---|---|
Bello等人[ | 限于求解100个节点的TSP和200个物品的KP,输出解的质量较差,泛化能力差 |
Chen等人[ | 限于求解100个节点的VRP,可以处理100 000 工件 |
Joshi等人[ | 训练限于100个节点TSP的固定图,测试限于500个节点TSP的动态图 |
Miki等人[ | 数据标签不易获得,依赖图片信息的质量,具有DNN网络的局限性 |
Li等人[ | 限于求解300个节点的CSP,无法处理动态节点的输入 |
Table 2 Limitation analysis of NCO model
作者 | 模型局限性分析 |
---|---|
Bello等人[ | 限于求解100个节点的TSP和200个物品的KP,输出解的质量较差,泛化能力差 |
Chen等人[ | 限于求解100个节点的VRP,可以处理100 000 工件 |
Joshi等人[ | 训练限于100个节点TSP的固定图,测试限于500个节点TSP的动态图 |
Miki等人[ | 数据标签不易获得,依赖图片信息的质量,具有DNN网络的局限性 |
Li等人[ | 限于求解300个节点的CSP,无法处理动态节点的输入 |
作者 | 模型局限性分析 |
---|---|
Nazari等人[ | 限于求解100个节点的TSP和100个节点的VRP和CVRP |
Kool等人[ | 限于求解100个节点的TSP、CVRP、OP、 SDVRP、PCTSP、SPCTSP,训练模型时间较慢,网络参数过多 |
Emami等人[ | 限于求解50个节点的sorting、25个节点的MWM、20个节点的TSP,模型泛化能力差 |
Oren等人[ | 限于求解100个节点的CVRP,求解PMSP限于80个工件集,线下算法收敛性差 |
Bo等人[ | 限于求解100个节点的VRP,模型训练时间长(250 h) |
Table 3 Analysis of limitation of dynamic model
作者 | 模型局限性分析 |
---|---|
Nazari等人[ | 限于求解100个节点的TSP和100个节点的VRP和CVRP |
Kool等人[ | 限于求解100个节点的TSP、CVRP、OP、 SDVRP、PCTSP、SPCTSP,训练模型时间较慢,网络参数过多 |
Emami等人[ | 限于求解50个节点的sorting、25个节点的MWM、20个节点的TSP,模型泛化能力差 |
Oren等人[ | 限于求解100个节点的CVRP,求解PMSP限于80个工件集,线下算法收敛性差 |
Bo等人[ | 限于求解100个节点的VRP,模型训练时间长(250 h) |
作者 | 模型局限性分析 |
---|---|
Dai等人[ | 可泛化求解1 200个节点的MVC、Max-cut、TSP,范围增大的过程中,模型收敛性差 |
Drori等人[ | 训练在100个节点,可泛化求解1 000节点的MST、SSP、TSP |
Mittal等人[ | 训练在1 000个节点,可泛化求解2 000个节点的MF、MVC、MCP,模型训练时间较慢,完成后求解时间较快 |
Barrett等人[ | 训练在200个节点,可泛化求解2 000个节点的Max-cut |
Abe等人[ | 训练在200个节点,可求解任意人造数据集的Max-cut,模型难以反映问题的根本属性 |
Bresson等人[ | 限于求解100个节点的TSP,无法判别模型构建的合理性 |
Table 4 Limitation analysis of graph structure model
作者 | 模型局限性分析 |
---|---|
Dai等人[ | 可泛化求解1 200个节点的MVC、Max-cut、TSP,范围增大的过程中,模型收敛性差 |
Drori等人[ | 训练在100个节点,可泛化求解1 000节点的MST、SSP、TSP |
Mittal等人[ | 训练在1 000个节点,可泛化求解2 000个节点的MF、MVC、MCP,模型训练时间较慢,完成后求解时间较快 |
Barrett等人[ | 训练在200个节点,可泛化求解2 000个节点的Max-cut |
Abe等人[ | 训练在200个节点,可求解任意人造数据集的Max-cut,模型难以反映问题的根本属性 |
Bresson等人[ | 限于求解100个节点的TSP,无法判别模型构建的合理性 |
作者 | 模型局限性分析 |
---|---|
Deudon等人[ | 限于求解100个节点的TSP,模型泛化能力和收敛性差,最优解可能是局部最优解 |
Cappart等人[ | 限于求解100个节点的TSPTW,模型训练时间长,受CP的限制,模型泛化能力差 |
Gao等人[ | 限于求解400个节点的CVRP、CVRPTW |
Costa等人[ | 限于求解100个节点的TSP,模型训练时间较慢,求解速度优势不明显 |
Zheng等人[ | 限于求解TSBLIB上111个对称TSP(达到1 000个节点) |
Table 5 Limitation analysis of RL combined with traditional algorithm model
作者 | 模型局限性分析 |
---|---|
Deudon等人[ | 限于求解100个节点的TSP,模型泛化能力和收敛性差,最优解可能是局部最优解 |
Cappart等人[ | 限于求解100个节点的TSPTW,模型训练时间长,受CP的限制,模型泛化能力差 |
Gao等人[ | 限于求解400个节点的CVRP、CVRPTW |
Costa等人[ | 限于求解100个节点的TSP,模型训练时间较慢,求解速度优势不明显 |
Zheng等人[ | 限于求解TSBLIB上111个对称TSP(达到1 000个节点) |
作者 | 模型局限性分析 |
---|---|
Lu等人[ | 限于求解100个节点的VRP,模型泛化能力差,初始解的随机性大,解的收敛性较差 |
Li等人[ | 求解kroAB100/150/200数据集,限于求解200个节点的混合双目标TSP |
Silva等人[ | 限于8个智能体协同工作,求解100个节点的CVRP,求解100个工件在25台机器加工,模型泛化能力差 |
Tassel等人[ | 限于求解30个工件在20台机器加工,模型输出的解会陷入局部最优解,泛化能力差 |
Ma等人[ | 限于求解1 000个节点的TSP、TSPW,模型训练时间较长 |
Delarue等人[ | 限于求解78个节点的VRP、CVRP,解的最优性无法保证 |
Table 6 Limitation analysis of improved RL model
作者 | 模型局限性分析 |
---|---|
Lu等人[ | 限于求解100个节点的VRP,模型泛化能力差,初始解的随机性大,解的收敛性较差 |
Li等人[ | 求解kroAB100/150/200数据集,限于求解200个节点的混合双目标TSP |
Silva等人[ | 限于8个智能体协同工作,求解100个节点的CVRP,求解100个工件在25台机器加工,模型泛化能力差 |
Tassel等人[ | 限于求解30个工件在20台机器加工,模型输出的解会陷入局部最优解,泛化能力差 |
Ma等人[ | 限于求解1 000个节点的TSP、TSPW,模型训练时间较长 |
Delarue等人[ | 限于求解78个节点的VRP、CVRP,解的最优性无法保证 |
模型 | 20-TSP | 50-TSP | 100-TSP | ||||||
---|---|---|---|---|---|---|---|---|---|
花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | |
Concorde[ | 3.84 | 0.00 | 60 | 5.70 | 0.00 | 120 | 7.76 | 0.00 | 180 |
LKH3[ | 3.84 | 0.00 | 18 | 5.70 | 0.00 | 300 | 7.76 | 0.00 | 1 260 |
Gurobi[ | 3.84 | 0.00 | 7 | 5.70 | 0.00 | 120 | 7.76 | 0.00 | 1 020 |
OR-Tools[ | 3.85 | 0.37 | 60 | 5.80 | 1.83 | 300 | 7.99 | 2.90 | 1 380 |
Bello[ | 3.89 | 1.42 | — | 5.95 | 4.46 | — | 8.30 | 6.90 | — |
Joshi(GS)[ | 3.86 | 0.60 | 6 | 5.87 | 3.10 | 55 | 8.41 | 8.38 | 180 |
Joshi(BS)[ | 3.84 | 0.01 | 720 | 5.70 | 0.01 | 1 080 | 7.78 | 1.39 | 2 400 |
Nazari[ | 3.97 | 3.27 | — | 6.08 | 6.25 | — | 8.44 | 7.93 | — |
Kool(GS)[ | 3.85 | 0.34 | 1 | 5.80 | 1.76 | 2 | 8.12 | 4.53 | 6 |
Dai[ | 3.89 | 1.42 | — | 5.99 | 5.16 | — | 8.31 | 7.03 | — |
Bresson[ | 3.84 | 0.00 | 1 | 5.70 | 0.20 | 1 | 7.79 | 0.39 | 1 |
Deudon[ | 3.84 | 0.09 | 360 | 5.75 | 1.00 | 1 920 | 8.12 | 4.46 | — |
Costa[ | 3.84 | 0.00 | — | 5.71 | 0.12 | — | 7.83 | 0.87 | — |
Table 7 Comparison of optimization effects of different models on TSP
模型 | 20-TSP | 50-TSP | 100-TSP | ||||||
---|---|---|---|---|---|---|---|---|---|
花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | |
Concorde[ | 3.84 | 0.00 | 60 | 5.70 | 0.00 | 120 | 7.76 | 0.00 | 180 |
LKH3[ | 3.84 | 0.00 | 18 | 5.70 | 0.00 | 300 | 7.76 | 0.00 | 1 260 |
Gurobi[ | 3.84 | 0.00 | 7 | 5.70 | 0.00 | 120 | 7.76 | 0.00 | 1 020 |
OR-Tools[ | 3.85 | 0.37 | 60 | 5.80 | 1.83 | 300 | 7.99 | 2.90 | 1 380 |
Bello[ | 3.89 | 1.42 | — | 5.95 | 4.46 | — | 8.30 | 6.90 | — |
Joshi(GS)[ | 3.86 | 0.60 | 6 | 5.87 | 3.10 | 55 | 8.41 | 8.38 | 180 |
Joshi(BS)[ | 3.84 | 0.01 | 720 | 5.70 | 0.01 | 1 080 | 7.78 | 1.39 | 2 400 |
Nazari[ | 3.97 | 3.27 | — | 6.08 | 6.25 | — | 8.44 | 7.93 | — |
Kool(GS)[ | 3.85 | 0.34 | 1 | 5.80 | 1.76 | 2 | 8.12 | 4.53 | 6 |
Dai[ | 3.89 | 1.42 | — | 5.99 | 5.16 | — | 8.31 | 7.03 | — |
Bresson[ | 3.84 | 0.00 | 1 | 5.70 | 0.20 | 1 | 7.79 | 0.39 | 1 |
Deudon[ | 3.84 | 0.09 | 360 | 5.75 | 1.00 | 1 920 | 8.12 | 4.46 | — |
Costa[ | 3.84 | 0.00 | — | 5.71 | 0.12 | — | 7.83 | 0.87 | — |
模型 | 20-VRP | 50-VRP | 100-VRP | ||||||
---|---|---|---|---|---|---|---|---|---|
花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | |
LKH3[ | 6.12 | 0.00 | 7 200 | 10.38 | 0.00 | 25 200 | 15.65 | 0.00 | 46 800 |
OR-Tools[ | 6.42 | 4.84 | 120 | 11.22 | 8.12 | 720 | 17.14 | 9.34 | 3 600 |
Nazari[ | 6.40 | 4.39 | 1 620 | 11.15 | 7.46 | 2 340 | 16.96 | 8.39 | 4 440 |
Kool(Sampling)[ | 6.25 | 2.49 | 360 | 10.62 | 2.40 | 1 680 | 16.23 | 3.72 | 7 200 |
Kool(Greedy) [ | 6.40 | 4.97 | 1 | 10.98 | 5.86 | 3 | 16.80 | 7.34 | 8 |
Bo(Greedy)[ | 6.28 | 2.95 | 1 | 10.78 | 3.85 | 1 | 16.40 | 4.79 | 3 |
Chen[ | 6.12 | 0.48 | 1 320 | 10.51 | 1.25 | 2 100 | 16.10 | 2.88 | 3 960 |
Lu[ | 6.12 | — | 720 | 10.35 | — | 1 020 | 15.57 | — | 1 400 |
Table 8 Comparison of optimization effects of different models on VRP
模型 | 20-VRP | 50-VRP | 100-VRP | ||||||
---|---|---|---|---|---|---|---|---|---|
花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | 花费 | 间隙/% | 时间/s | |
LKH3[ | 6.12 | 0.00 | 7 200 | 10.38 | 0.00 | 25 200 | 15.65 | 0.00 | 46 800 |
OR-Tools[ | 6.42 | 4.84 | 120 | 11.22 | 8.12 | 720 | 17.14 | 9.34 | 3 600 |
Nazari[ | 6.40 | 4.39 | 1 620 | 11.15 | 7.46 | 2 340 | 16.96 | 8.39 | 4 440 |
Kool(Sampling)[ | 6.25 | 2.49 | 360 | 10.62 | 2.40 | 1 680 | 16.23 | 3.72 | 7 200 |
Kool(Greedy) [ | 6.40 | 4.97 | 1 | 10.98 | 5.86 | 3 | 16.80 | 7.34 | 8 |
Bo(Greedy)[ | 6.28 | 2.95 | 1 | 10.78 | 3.85 | 1 | 16.40 | 4.79 | 3 |
Chen[ | 6.12 | 0.48 | 1 320 | 10.51 | 1.25 | 2 100 | 16.10 | 2.88 | 3 960 |
Lu[ | 6.12 | — | 720 | 10.35 | — | 1 020 | 15.57 | — | 1 400 |
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