Large language model-enhanced ant colony optimization for multi-solution traveling salesman problems

doi:10.11772/j.issn.1001-9081.2025050646

Journal of Computer Applications ›› 2026, Vol. 46 ›› Issue (6): 1712-1720.DOI: 10.11772/j.issn.1001-9081.2025050646

• Artificial intelligence • Previous Articles

Large language model-enhanced ant colony optimization for multi-solution traveling salesman problems

Taixin CAI, Fengfeng WEI()

School of Computer Science and Engineering，South China University of Technology，Guangzhou Guangdong 510006，China

Received:2025-06-12 Revised:2025-09-11 Accepted:2025-09-19 Online:2025-10-17 Published:2026-06-10
Contact: Fengfeng WEI
About author:CAI Taixin， born in 2004. His research interests include swarm intelligence， evolutionary computation.
First author contact:WEI Fengfeng， born in 1996， Ph. D.， associate professor. Her research interests include swarm intelligence， evolutionary computation， distributed optimization， data-driven optimization.
Supported by:
Youth Program of National Natural Science Foundation of China(62406113);Guangdong Natural Science Foundation(2025A1515012028)

面向多解旅行商问题的大语言模型增强蚁群优化算法

蔡泰鑫, 魏凤凤()

华南理工大学计算机科学与工程学院，广州 510006

通讯作者: 魏凤凤
作者简介:蔡泰鑫（2004—），男，广东东莞人，主要研究方向：群体智能、演化计算
第一联系人：魏凤凤（1996—），女，山东青岛人，副教授，博士，CCF会员，主要研究方向：群体智能、演化计算、分布式优化、数据驱动优化。
基金资助:
国家自然科学基金青年基金资助项目(62406113);广东省基础与应用基础研究基金资助项目(2025A1515012028);广东省基础与应用基础研究基金资助项目(2023A1515012896)

Abstract

Abstract:

In Combinatorial Optimization （CO） problems， Multi-Solution Traveling Salesman Problem （MSTSP） aims to acquire a set of distinct globally optimal paths， and plays a critical role in scenarios such as logistics scheduling and tour route planning. As a traditional approach for solving path optimization problems， ACO （Ant Colony Optimization） suffers from bottlenecks including pheromone premature convergence and imbalance between solution quality and diversity. To address these challenges， a Large Language Model （LLM）-enhanced ACO for MSTSP （L-ACO） was proposed to integrate LLMs into traditional ACO through a multi-layer prompt engineering strategy： during the solution construction stage， the city topological features were parsed， so as to construct high-quality diverse initial paths； in the perturbation optimization stage， new paths were generated on the basis of the paths in solution pool and their statistical information， so as to escape from the local optimum. Additionally， a multi-dimensional evaluation system was developed to assess solution quality， diversity， and LLM effectiveness comprehensively. Experimental results on 25 MSTSP benchmark instances demonstrate that compared to traditional ACO， L-ACO improves the Structural Diversity Index （SDI） by 0.08 and the Quality-Quantity Composite Index （QQCI） by 13% relatively， indicating that L-ACO effectively optimize the convergence in multi-solution scenarios compared to traditional ACO.

Key words: Combinatorial Optimization (CO), Multi-Solution Traveling Salesman Problem (MSTSP), Ant Colony Optimization (ACO), Large Language Model (LLM), prompt engineering

摘要：

在组合优化（CO）问题中，多解旅行商问题（MSTSP）的目标是获取一组互异的全局最优路径，在物流调度、旅游线路规划等场景具有关键价值。作为求解路径优化问题的传统方法，蚁群优化算法（ACO）存在信息素早熟收敛、质量与多样性失衡的瓶颈。针对上述挑战，提出一种面向MSTSP的大语言模型（LLM）增强蚁群优化算法（L-ACO），采用多层提示工程策略将LLM双阶段集成于传统ACO：在种子生成阶段，解析城市拓扑特征构建高质量多样化初始路径；在扰动优化阶段，针对解池路径及其统计信息生成新路径，跳出局部最优。此外，构建多维评价体系综合检验求解质量、多样性和LLM有效性。25项MSTSP基准实例上的测试结果表明，相较于传统ACO，L-ACO的结构多样性指标（SDI）提升了0.08，质量-数量综合指标（QQCI）相对提升了13%，表明L-ACO改善了传统ACO在多解场景下的收敛性。

关键词: 组合优化, 多解旅行商问题, 蚁群优化算法, 大语言模型, 提示工程

CLC Number:

TP301.6

Taixin CAI, Fengfeng WEI. Large language model-enhanced ant colony optimization for multi-solution traveling salesman problems[J]. Journal of Computer Applications, 2026, 46(6): 1712-1720.

蔡泰鑫, 魏凤凤. 面向多解旅行商问题的大语言模型增强蚁群优化算法[J]. 《计算机应用》唯一官方网站, 2026, 46(6): 1712-1720.

Figures/Tables 9

Fig. 1 Overall framework of L-ACO

Fig. 2 Optimization flow of L-ACO

Fig. 3 Schematic diagram of prompt engineering

Tab. 1 Overall performance comparison

实例	Length↓			Quantity↑			SDI↑			QQCI↑
实例	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA
Sinple1_9	680	680	680	3.00	3.00	2.00	0.630	0.630	0.444	1.552	1.552	1.320
Sinple2_10	1265	1 297	1 265	2.10	1.05	1.40	0.238	0.040	0.120	1.317	1.001	1.128
Sinple3_10	832	832	832	5.30	3.70	2.80	0.455	0.428	0.360	1.947	1.678	1.497
Sinple4_11	804	811	803	1.70	1.05	1.05	0.271	0.014	0.009	1.214	1.010	1.020
Sinple5_12	763	771	765	1.30	1.05	1.00	0.225	0.038	0.000	1.088	1.003	0.991
Sinple6_12	845	854	845	1.70	1.10	1.05	0.444	0.083	0.006	1.215	1.025	1.020
Geometry1_10	130	130	130	10.20	7.20	4.00	0.734	0.711	0.701	2.523	2.192	1.736
Geometry2_12	1 344	1 344	1 344	9.00	4.70	4.80	0.746	0.697	0.660	2.401	1.853	1.838
Geometry3_10	72	72	72	2.10	1.00	1.40	0.453	0.000	0.160	1.321	1.000	1.126
Geometry4_10	72	72	72	4.00	3.70	1.70	0.642	0.640	0.689	1.741	1.682	1.236
Geometry5_10	78	78	78	10.30	5.35	4.40	0.661	0.622	0.677	2.534	1.934	1.792
Geometry6_15	130	131	130	4.50	4.15	2.40	0.844	0.778	0.582	1.803	1.737	1.392
Composite1_28	3 067	3 089	3 152	1.30	1.10	1.00	0.066	0.030	0.000	1.093	1.025	0.981
Composite2_34	3 671	3 705	3 731	1.05	1.05	1.00	0.006	0.003	0.000	1.000	0.994	0.975
Composite3_22	9 674	9 780	11 175	1.60	1.00	1.60	0.043	0.000	0.023	1.163	0.985	1.098
Composite4_33	8 811	8 821	8 851	2.80	1.15	1.20	0.104	0.017	0.061	1.428	1.044	1.069
Composite5_35	9 178	9 201	9 369	1.55	1.05	1.50	0.022	0.004	0.029	1.182	1.007	1.153
Composite6_39	23 956	24 013	24 475	1.35	1.05	1.10	0.031	0.005	0.007	1.106	1.010	1.021
Composite7_42	14 534	14 590	14 793	1.10	1.05	1.00	0.006	0.020	0.000	1.022	1.008	0.977
Composite8_45	11 097	11 131	11 340	1.10	1.05	1.80	0.010	0.008	0.033	1.025	1.007	1.214
Composite9_48	6 944	6 995	7 103	1.00	1.00	1.00	0.000	0.000	0.000	0.985	0.980	0.971
Composite10_55	10 561	10 585	13 973	1.25	1.05	1.05	0.009	0.002	0.003	1.073	1.008	0.846
Composite11_59	24 662	24 699	25 125	1.20	1.05	1.20	0.025	0.025	0.013	1.054	1.010	1.062
Composite12_60	9 793	9 825	10 418	1.10	1.05	1.00	0.075	0.021	0.000	1.021	1.003	0.953
Composite13_66	9 737	9 757	10 214	1.05	1.00	1.20	0.002	0.000	0.008	1.002	0.985	1.035
（ $+$ ， $-$ ， $≈$ ）		（0，17，8）	（1，13，11）		（0，14，11）	（2，12，11）		（0，11，14）	（2，10，13）		（0，22，3）	（3，17，5）

Tab. 1 Overall performance comparison

实例	Length↓			Quantity↑			SDI↑			QQCI↑
实例	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA	L-ACO	ACO	M-LMEA
Sinple1_9	680	680	680	3.00	3.00	2.00	0.630	0.630	0.444	1.552	1.552	1.320
Sinple2_10	1265	1 297	1 265	2.10	1.05	1.40	0.238	0.040	0.120	1.317	1.001	1.128
Sinple3_10	832	832	832	5.30	3.70	2.80	0.455	0.428	0.360	1.947	1.678	1.497
Sinple4_11	804	811	803	1.70	1.05	1.05	0.271	0.014	0.009	1.214	1.010	1.020
Sinple5_12	763	771	765	1.30	1.05	1.00	0.225	0.038	0.000	1.088	1.003	0.991
Sinple6_12	845	854	845	1.70	1.10	1.05	0.444	0.083	0.006	1.215	1.025	1.020
Geometry1_10	130	130	130	10.20	7.20	4.00	0.734	0.711	0.701	2.523	2.192	1.736
Geometry2_12	1 344	1 344	1 344	9.00	4.70	4.80	0.746	0.697	0.660	2.401	1.853	1.838
Geometry3_10	72	72	72	2.10	1.00	1.40	0.453	0.000	0.160	1.321	1.000	1.126
Geometry4_10	72	72	72	4.00	3.70	1.70	0.642	0.640	0.689	1.741	1.682	1.236
Geometry5_10	78	78	78	10.30	5.35	4.40	0.661	0.622	0.677	2.534	1.934	1.792
Geometry6_15	130	131	130	4.50	4.15	2.40	0.844	0.778	0.582	1.803	1.737	1.392
Composite1_28	3 067	3 089	3 152	1.30	1.10	1.00	0.066	0.030	0.000	1.093	1.025	0.981
Composite2_34	3 671	3 705	3 731	1.05	1.05	1.00	0.006	0.003	0.000	1.000	0.994	0.975
Composite3_22	9 674	9 780	11 175	1.60	1.00	1.60	0.043	0.000	0.023	1.163	0.985	1.098
Composite4_33	8 811	8 821	8 851	2.80	1.15	1.20	0.104	0.017	0.061	1.428	1.044	1.069
Composite5_35	9 178	9 201	9 369	1.55	1.05	1.50	0.022	0.004	0.029	1.182	1.007	1.153
Composite6_39	23 956	24 013	24 475	1.35	1.05	1.10	0.031	0.005	0.007	1.106	1.010	1.021
Composite7_42	14 534	14 590	14 793	1.10	1.05	1.00	0.006	0.020	0.000	1.022	1.008	0.977
Composite8_45	11 097	11 131	11 340	1.10	1.05	1.80	0.010	0.008	0.033	1.025	1.007	1.214
Composite9_48	6 944	6 995	7 103	1.00	1.00	1.00	0.000	0.000	0.000	0.985	0.980	0.971
Composite10_55	10 561	10 585	13 973	1.25	1.05	1.05	0.009	0.002	0.003	1.073	1.008	0.846
Composite11_59	24 662	24 699	25 125	1.20	1.05	1.20	0.025	0.025	0.013	1.054	1.010	1.062
Composite12_60	9 793	9 825	10 418	1.10	1.05	1.00	0.075	0.021	0.000	1.021	1.003	0.953
Composite13_66	9 737	9 757	10 214	1.05	1.00	1.20	0.002	0.000	0.008	1.002	0.985	1.035
（ $+$ ， $-$ ， $≈$ ）		（0，17，8）	（1，13，11）		（0，14，11）	（2，12，11）		（0，11，14）	（2，10，13）		（0，22，3）	（3，17，5）

Fig.4 Comparison of LEI and QQCIIR

Fig. 5 Comparison of convergence curves on Geometry5_10 instance

Tab. 2 Comparison of algorithm time cost

实例类型	L-ACO	ACO	M-LMEA
Simple	53.35±6.52	1.30±0.10	786.94±98.37
Geometry	57.04±8.70	1.45±0.18	794.25±77.65
Composite	279.9±89.0	10.9±4.49	1 942.04±663.72

Tab. 3 Comparison of QQCI improvement rates under different quality weights

$γ$	QQCI提升率
$γ$	Simple类	Geometry类	Composite类	整体
0.50	0.242	0.247	0.104	0.168
0.55	0.215	0.219	0.091	0.149
0.60	0.189	0.192	0.080	0.130
0.65	0.164	0.165	0.068	0.113
0.70	0.140	0.139	0.058	0.095

Tab. 3 Comparison of QQCI improvement rates under different quality weights

$γ$	QQCI提升率
$γ$	Simple类	Geometry类	Composite类	整体
0.50	0.242	0.247	0.104	0.168
0.55	0.215	0.219	0.091	0.149
0.60	0.189	0.192	0.080	0.130
0.65	0.164	0.165	0.068	0.113
0.70	0.140	0.139	0.058	0.095

Tab. 4 Ablation experimental results

实例	Length↓		Quantity↑		SDI↑		QQCI↑
实例	seed	mutation	seed	mutation	seed	mutation	seed	mutation
Simple1_9	680±0.00	680±0.00	3.00±0.00	3.00±0.00	0.630±0.00	0.630±0.00	1.552±0.00	1.552±0.00
Sinple2_10	1 276±16.6	1 274±14.5	1.10±0.30	1.35±0.57	0.055±0.18	0.067±0.11	1.026±0.09	1.103±0.17
Sinple3_10	832±0.00	832±0.00	4.15±0.96	5.15±1.15	0.422±0.08	0.463±0.07	1.754±0.17	1.915±0.17
Sinple4_11	810±6.11	805±4.25	1.15±0.36	1.50±0.67	0.105±0.27	0.170±0.25	1.043±0.12	1.149±0.20
Sinple5_12	769±5.17	764±5.09	1.35±0.48	1.05±0.22	0.263±0.36	0.038±0.16	1.099±0.15	1.008±0.07
Sinple6_12	847±8.28	848±7.51	1.20±0.40	1.40±0.58	0.154±0.32	0.276±0.39	1.062±0.13	1.121±0.18
Geometry1_10	130±0.00	130±0.00	8.20±0.87	9.05±1.02	0.716±0.01	0.719±0.01	2.317±0.10	2.410±0.11
Geometry2_12	1 344±0.00	1 344±0.00	5.90±1.34	7.60±1.88	0.709±0.03	0.733±0.03	2.021±0.19	2.233±0.23
Geometry3_10	72±0.00	72±0.00	1.35±0.48	1.25±0.43	0.180±0.27	0.120±0.22	1.112±0.15	1.080±0.14
Geometry4_10	72±0.00	72±0.00	3.85±0.36	3.85±0.36	0.660±0.05	0.673±0.07	1.713±0.07	1.713±0.07
Geometry5_10	78±0.00	78±0.00	6.45±1.32	7.95±1.28	0.655±0.05	0.678±0.04	2.098±0.18	2.284±0.15
Geometry6_15	131±0.36	1.713±0.07	3.95±1.83	3.70±1.58	0.667±0.29	0.768±0.26	1.673±0.35	1.646±0.31
Composite1_28	3 088±14.9	3 078±12.3	1.15±0.36	1.50±0.81	0.043±0.11	0.096±0.21	1.041±0.11	1.139±0.21
Composite2_34	3 702±25.0	3 664±25.0	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.980±0.00	0.985±0.00
Composite3_22	9 763±40.7	9 669±27.5	1.00±0.00	1.60±0.86	0.000±0.00	0.041±0.05	0.986±0.00	1.163±0.23
Composite4_33	8 826±9.95	8 806±11.7	1.90±1.58	2.20±1.25	0.076±0.13	0.177±0.26	1.216±0.34	1.321±0.28
Composite5_35	9 206±24.7	9 182±28.5	1.05±0.22	1.25±0.54	0.003±0.01	0.124±0.03	1.006±0.07	1.067±0.16
Composite6_39	23 985±59.7	23 950±60.4	1.05±0.22	1.55±0.67	0.003±0.01	0.070±0.20	1.010±0.07	1.162±0.19
Composite7_42	14 581±19.7	14 550±27.2	1.05±0.22	1.10±0.30	0.002±0.01	0.025±0.10	1.009±0.07	1.026±0.10
Composite8_45	11 126±20.9	11 102±29.7	1.10±0.30	1.25±0.43	0.061±0.19	0.033±0.06	1.023±0.10	1.072±0.14
Composite9_48	6 981±21.8	6 941±41.4	1.05±0.22	1.00±0.00	0.033±0.15	0.000±0.00	0.997±0.07	0.985±0.00
Composite10_55	10 586±12.1	10 567±21.1	1.25±0.54	1.10±0.30	0.188±0.05	0.021±0.08	1.067±0.16	1.025±0.09
Composite11_59	24 689±27.5	24 667±28.2	1.05±0.22	1.15±0.48	0.048±0.21	0.004±0.01	1.010±0.07	1.038±0.14
Composite12_60	9 802±35.1	9 778±30.0	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.988±0.00	0.990±0.00
Composite13_66	9 746±35.2	9 731±42.2	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.986±0.00	0.987±0.00

Tab. 4 Ablation experimental results

实例	Length↓		Quantity↑		SDI↑		QQCI↑
实例	seed	mutation	seed	mutation	seed	mutation	seed	mutation
Simple1_9	680±0.00	680±0.00	3.00±0.00	3.00±0.00	0.630±0.00	0.630±0.00	1.552±0.00	1.552±0.00
Sinple2_10	1 276±16.6	1 274±14.5	1.10±0.30	1.35±0.57	0.055±0.18	0.067±0.11	1.026±0.09	1.103±0.17
Sinple3_10	832±0.00	832±0.00	4.15±0.96	5.15±1.15	0.422±0.08	0.463±0.07	1.754±0.17	1.915±0.17
Sinple4_11	810±6.11	805±4.25	1.15±0.36	1.50±0.67	0.105±0.27	0.170±0.25	1.043±0.12	1.149±0.20
Sinple5_12	769±5.17	764±5.09	1.35±0.48	1.05±0.22	0.263±0.36	0.038±0.16	1.099±0.15	1.008±0.07
Sinple6_12	847±8.28	848±7.51	1.20±0.40	1.40±0.58	0.154±0.32	0.276±0.39	1.062±0.13	1.121±0.18
Geometry1_10	130±0.00	130±0.00	8.20±0.87	9.05±1.02	0.716±0.01	0.719±0.01	2.317±0.10	2.410±0.11
Geometry2_12	1 344±0.00	1 344±0.00	5.90±1.34	7.60±1.88	0.709±0.03	0.733±0.03	2.021±0.19	2.233±0.23
Geometry3_10	72±0.00	72±0.00	1.35±0.48	1.25±0.43	0.180±0.27	0.120±0.22	1.112±0.15	1.080±0.14
Geometry4_10	72±0.00	72±0.00	3.85±0.36	3.85±0.36	0.660±0.05	0.673±0.07	1.713±0.07	1.713±0.07
Geometry5_10	78±0.00	78±0.00	6.45±1.32	7.95±1.28	0.655±0.05	0.678±0.04	2.098±0.18	2.284±0.15
Geometry6_15	131±0.36	1.713±0.07	3.95±1.83	3.70±1.58	0.667±0.29	0.768±0.26	1.673±0.35	1.646±0.31
Composite1_28	3 088±14.9	3 078±12.3	1.15±0.36	1.50±0.81	0.043±0.11	0.096±0.21	1.041±0.11	1.139±0.21
Composite2_34	3 702±25.0	3 664±25.0	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.980±0.00	0.985±0.00
Composite3_22	9 763±40.7	9 669±27.5	1.00±0.00	1.60±0.86	0.000±0.00	0.041±0.05	0.986±0.00	1.163±0.23
Composite4_33	8 826±9.95	8 806±11.7	1.90±1.58	2.20±1.25	0.076±0.13	0.177±0.26	1.216±0.34	1.321±0.28
Composite5_35	9 206±24.7	9 182±28.5	1.05±0.22	1.25±0.54	0.003±0.01	0.124±0.03	1.006±0.07	1.067±0.16
Composite6_39	23 985±59.7	23 950±60.4	1.05±0.22	1.55±0.67	0.003±0.01	0.070±0.20	1.010±0.07	1.162±0.19
Composite7_42	14 581±19.7	14 550±27.2	1.05±0.22	1.10±0.30	0.002±0.01	0.025±0.10	1.009±0.07	1.026±0.10
Composite8_45	11 126±20.9	11 102±29.7	1.10±0.30	1.25±0.43	0.061±0.19	0.033±0.06	1.023±0.10	1.072±0.14
Composite9_48	6 981±21.8	6 941±41.4	1.05±0.22	1.00±0.00	0.033±0.15	0.000±0.00	0.997±0.07	0.985±0.00
Composite10_55	10 586±12.1	10 567±21.1	1.25±0.54	1.10±0.30	0.188±0.05	0.021±0.08	1.067±0.16	1.025±0.09
Composite11_59	24 689±27.5	24 667±28.2	1.05±0.22	1.15±0.48	0.048±0.21	0.004±0.01	1.010±0.07	1.038±0.14
Composite12_60	9 802±35.1	9 778±30.0	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.988±0.00	0.990±0.00
Composite13_66	9 746±35.2	9 731±42.2	1.00±0.00	1.00±0.00	0.000±0.00	0.000±0.00	0.986±0.00	0.987±0.00

References 30

[1]	KORTE B， VYGEN J. Combinatorial optimization： theory and algorithms， AC 21［M］. 6th ed. Berlin： Springer， 2018： 5-6.
[2]	KORTE B， VYGEN J. Combinatorial optimization： theory and algorithms， AC 21［M］. 6th ed. Berlin： Springer， 2018： 29-30.
[3]	DHOUIB S. Adaptive iterated stochastic metaheuristic to optimize holes drilling path in printed circuit boards［J］. Engineering Applications of Artificial Intelligence， 2023， 121： No.105829.
[4]	NAŁĘCZ-CHARKIEWICZ K， NOWAK R M. Algorithm for DNA sequence assembly by quantum annealing［J］. BMC Bioinformatics， 2022， 23： No.122.
[5]	孙鉴，马宝全，吴隹伟，等. 地震场景下无人机群路径规划与任务分配均衡联合优化［J］. 计算机应用， 2024， 44（10）： 3232-3239.
	SUN J， MA B Q， WU Z W， et al. Joint optimization of UAV swarm path planning and task allocation balance in earthquake scenarios［J］. Journal of Computer Applications， 2024， 44（10）： 3232-3239.
[6]	赵浩宇，于自强，陈晓萌，等. 支持关键词搜索的top-K条最优路线查询问题［J］. 计算机应用， 2024， 44（8）： 2455-2465.
	ZHAO H Y， YU Z Q， CHEN X M， et al. top-K optimal route query problem with keyword search support［J］. Journal of Computer Applications， 2024， 44（8）： 2455-2465.
[7]	YIN Y Q， YANG Y J， YU Y G， et al. Robust vehicle routing with drones under uncertain demands and truck travel times in humanitarian logistics ［J］. Transportation Research Part B： Methodological， 2023， 174： 102781.
[8]	HUANG T， GONG Y J， ZHANG J. Seeking multiple solutions of combinatorial optimization problems： a proof of principle study［C］// 2018 IEEE Symposium Series on Computational Intelligence. Piscataway： IEEE， 2018： 1212-1218.
[9]	BÄCK T， FOGEL D B， MICHALEWICZ Z. Evolutionary computation 1： basic algorithms and operators［M］. New York： Taylor & Francis Group， 2000： 􀃸-􀃸.
[10]	DORIGOM， STÜTZLE T. Ant colony optimization： overview and recent advances［C］// GENDREAU M， POTVIN J Y. Handbook of metaheuristics， ISOR 272. Cham： Springer， 2019： 311-351.
[11]	HAN X C， KE H W， GONG Y J， et al. Multimodal optimization of traveling salesman problem： a niching ant colony system［C］// Proceedings of the 2018 Genetic and Evolutionary Computation Conference Companion. New York： ACM， 2018： 87-88.
[12]	HUANG T， ZHANG Z Q， GONG Y J， et al. nLKH-ACS： a niching Lin-Kernighan-Helsgaun based ant colony system for multi-solution traveling salesman problems［J］. IEEE Transactions on Evolutionary Computation， 2025， 29（6）： 2596-2610.
[13]	MO Y， YOU X， LIU S. Multi-colony ant optimization with dynamic collaborative mechanism and cooperative game［J］. Complex and Intelligent Systems， 2022， 8（6）： 4679-4696.
[14]	GAO W. New ant colony optimization algorithm for the traveling salesman problem［J］. International Journal of Computational Intelligence Systems， 2020， 13（1）： 44-55.
[15]	BROWN T B， MANN B， RYDER N， et al. Language models are few-shot learners［C］// Proceedings of the 34th International Conference on Neural Information Processing Systems. Red Hook： Curran Associates Inc. 2020： 1877-1901.
[16]	RÉGIN F， DE MARIA E， BONLARRON A. Combining constraint programming reasoning with large language models［C］// Proceedings of the 30th International Conference on Principles and Practice of Constraint Programming. Wadern： Leibniz-Zentrum für Informatik， 2024： No.25.
[17]	VAN STEIN N， BÄCK T. LLaMEA： a large language model evolutionary algorithm for large-scale optimization［J］. IEEE Transactions on Evolutionary Computation， 2025， 29（2）： 331-345.
[18]	DONG Q， LI L， DAI D， et al. A survey on in-context learning［C］// Proceedings of the 2024 Conference on Empirical Methods in Natural Language Processing. Stroudsburg： ACL， 2024： 1107-1128.
[19]	LIU S， CHEN C， QU X， et al. Large language models as evolutionary optimizers［C］// Proceedings of the 2024 IEEE Congress on Evolutionary Computation. Piscataway： IEEE， 2024： 1-8.
[20]	WANG D， ZHANG Z， TENG Y. Large language model implemented simulated annealing algorithm for traveling salesman problem［C］// Proceedings of the 2024 IEEE International Conference on Systems， Man， and Cybernetics. Piscataway： IEEE， 2024： 209-214.
[21]	LIU F， TONG X， YUAN M， et al. Evolution of heuristics： towards efficient automatic algorithm design using large language model［C］// Proceedings of the 41st International Conference on Machine Learning. New York： JMLR.org， 2024： 32201-32223.
[22]	DORIGO M， GAMBARDELLA L M. Ant colony system： a cooperative learning approach to the traveling salesman problem［J］. IEEE Transactions on Evolutionary Computation， 1997， 1（1）： 53-66.
[23]	STÜTZLE T， HOOS H H. MAX-MIN ant system［J］. Future Generation Computer Systems， 2000， 16（8）： 889-914.
[24]	CHU X Y， TALLURI S， LU Q X， et al. An empirical characterization of outages and incidents in public services for large language models ［C］// Proceedings of the 16th ACM/SPEC International Conference on Performance Engineering. New York： ACM， 2025： 69-80.
[25]	LI X， EPITROPAKIS M G， DEB K， et al. Seeking multiple solutions： an updated survey on niching methods and their applications［J］. IEEE Transactions on Evolutionary Computation， 2017， 21（4）： 518-538.
[26]	WANG M Y， SPITZ A. Quantifying the risks of LLM- and tool-assisted rephrasing to linguistic diversity ［EB/OL］. ［2025-04-06］. .
[27]	FONTAINE M C， NIKOLAIDIS S. Differentiable quality diversity［C］// Proceedings of the 35th International Conference on Neural Information Processing Systems. Red Hook： Curran Associates Inc.， 2021： 10040-10052.
[28]	PEREIRA J L J， OLIVER G A， FRANCISCO M B， et al. A review of multi-objective optimization： methods and algorithms in mechanical engineering applications［J］. Archives of Computational Methods in Engineering， 2022， 29（4）： 2285-2308.
[29]	DEB K， PRATAP A， AGARWAL S， et al. A fast and elitist multiobjective genetic algorithm： NSGA-Ⅱ［J］. IEEE Transactions on Evolutionary Computation， 2002， 6（2）： 182-197.
[30]	SÖRENSEN K. Distance measures based on the edit distance for permutation-type representations［J］. Journal of Heuristics， 2007， 13（1）： 35-47.

Large language model-enhanced ant colony optimization for multi-solution traveling salesman problems

面向多解旅行商问题的大语言模型增强蚁群优化算法

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 9

References 30

Related Articles 15

Recommended Articles

Metrics

[1]	Jiali ZHENG, Gang ZHOU, Jing CHEN, Shunhang LI. Adaptive multi-feature fusion detection method for AI-generated text [J]. Journal of Computer Applications, 2026, 46(5): 1433-1440.
[2]	Qianfei WANG, Yang LI, Deyu LI, Suge WANG. Dual-channel feature fusion representation method for short-text clustering based on large language model [J]. Journal of Computer Applications, 2026, 46(5): 1441-1449.
[3]	Xing SHENG, Sunxian WENG, Kuosong CHEN, Zhongping WANG, Ruifeng REN, Yong LIU. Deep learning-based patent value evaluation for power grid enterprises [J]. Journal of Computer Applications, 2026, 46(5): 1468-1474.
[4]	Xiaoyu WANG, Xin LI, Di XUE, Zhangtao JIANG, Wei WANG, Yanjun XIAO. Vulnerability classification framework for video surveillance network security based on large language models [J]. Journal of Computer Applications, 2026, 46(4): 1158-1170.
[5]	Kaizhou SHI, Xuan HE, Guoyi HOU, Gen LI, Shuanggao LI, Xiang HUANG. Airborne product metrological traceability knowledge graph construction method based on large language models [J]. Journal of Computer Applications, 2026, 46(4): 1086-1095.
[6]	Haoyang ZHANG, Liping ZHANG, Sheng YAN, Na LI, Xuefei ZHANG. Review of large language model methods for knowledge graph completion [J]. Journal of Computer Applications, 2026, 46(3): 683-695.
[7]	Bin SHEN, Xiaoning CHEN, Hua CHENG, Yiquan FANG, Huifeng WANG. Intelligent undergraduate teaching evaluation system based on large language models [J]. Journal of Computer Applications, 2026, 46(3): 993-1003.
[8]	Enkang XI, Jing FAN, Yadong JIN, Hua DONG, Hao YU, Yihang SUN. Review of threats faced by federated learning in privacy and security field [J]. Journal of Computer Applications, 2026, 46(3): 798-808.
[9]	Yiming HUANG, Xihua ZOU, Guo DENG, Di ZHENG. Pre-answering and retrieval filtering： dual-stage optimization method for RAG-based question-answering systems [J]. Journal of Computer Applications, 2026, 46(3): 696-707.
[10]	Dingjia WU, Zhe CUI. MG-SQL： SQL generation framework with enhanced schema linking and multi-generator collaboration [J]. Journal of Computer Applications, 2026, 46(3): 723-731.
[11]	Rilong WANG, Zhenping LI, Xiaosong LI, Qiang GAO, Ya HE, Yong ZHONG, Yingxiao ZHAO. Multi-Agent collaborative knowledge reasoning framework [J]. Journal of Computer Applications, 2026, 46(3): 708-714.
[12]	Fei GAO, Dong CHEN, Dixing BIAN, Wenqiang FAN, Qidong LIU, Pei LYU, Chaoyang ZHANG, Mingliang XU. Multistage coupled decision-making framework for researcher redeployment after discipline revocation [J]. Journal of Computer Applications, 2026, 46(2): 416-426.
[13]	Haoqian JIANG, Dong ZHANG, Guanyu LI, Heng CHEN. SetaCRS： Conversational recommender system with structure-enhanced hierarchical task-oriented prompting strategy [J]. Journal of Computer Applications, 2026, 46(2): 368-377.
[14]	Yixin LIU, Xianggen LIU, Wen LIU, Hongbo DENG, Ziye ZHANG, Hua MU. Benchmark dataset for retrieval-augmented generation on long documents [J]. Journal of Computer Applications, 2026, 46(2): 386-394.
[15]	Yi LIN, Bing XIA, Yong WANG, Shunda MENG, Juchong LIU, Shuqin ZHANG. AI-Agent based method for hidden RESTful API discovery and vulnerability detection [J]. Journal of Computer Applications, 2026, 46(1): 135-143.