Model construction and topology analysis of logistics equipment system-of-systems heterogeneous network

doi:10.23919/JSEE.2026.000078

Journal of Systems Engineering and Electronics ›› 2026, Vol. 37 ›› Issue (2): 594-603.doi: 10.23919/JSEE.2026.000078

• SYSTEMS ENGINEERING • Previous Articles

Model construction and topology analysis of logistics equipment system-of-systems heterogeneous network

Fanghua YANG¹^,²(), Cong JIN²^,*(), Zihan ZHAO²(), Yanjing LU²(), Pei LI²()

¹School of Management, Beijing Institute of Technology, Beijing 100081, China
²Systems Engineering Institute, Academy of Military Sciences, People’s Liberation Army, Beijing 100071, China

Received:2024-02-05 Online:2026-04-18 Published:2026-04-30
Contact: Cong JIN E-mail:fanghuayy@sina.com;jinyuening918@163.com;zhh_track@163.com;66537055@qq.com;1205495738@qq.com
About author:
YANG Fanghua was born in 1975. He received his M.S. degree in 2005. Currently, he is an associate researcher and M.S. supervisor at the Systems Engineering Institute, Academy of Military Sciences. His research interests are systems engineering, equipment system-of-systems demonstration and estimation. E-mail: fanghuayy@sina.com

JIN Cong was born in 1990. She received her Ph.D. degree from China University of Mining and Technology (Beijing) in 2019. She is currently working toward her Ph.D. degree at the Systems Engineering Institute, Academy of Military Sciences. Her research interests are the complex network theory, equipment system-of-systems demonstration and estimation. E-mail: jinyuening918@163.com

ZHAO Zihan was born in 1991. He received his Ph.D. degree from Army Engineering University of PLA in 2020. He is currently working at the Systems Engineering Institute, Academy of Military Sciences. His main research direction is equipment system-of-systems demonstration. E-mail: zhh_track@163.com

LU Yanjing was born in 1982. He received his Ph.D. degree from National University of Defense Technology in 2012. He is currently working at the Systems Engineering Institute, Academy of Military Sciences. His research interests include systems engineering, control and decision, computer engineering, and equipment system-of-systems demonstration. E-mail: 66537055@qq.com

LI Pei was born in 1991. He received his Ph.D. degree from Army Engineering University of PLA in 2019. He is currently working at the Systems Engineering Institute, Academy of Military Sciences. His main research direction is equipment system-of-systems demonstration. E-mail: 1205495738@qq.com
First author contact:
Co-first author

Abstract

Abstract:

With the improvement of the informatization and intelligence level of logistics equipment, the interactive and collaborative relationships between equipment entities become complex, and the uncertainty problems emerge in the equipment system-of-systems. Herein, a heterogeneous network model is built to describe logistics equipment system-of-systems, which considers the heterogeneity and complex connections of different logistics equipment nodes. Next, the topological structure properties of this model are analyzed. On this basis, the experiments on the logistics equipment system-of-systems under attack strategies including degree attacks, betweenness centrality attacks and random attacks are taken to assess the changes of structural invulnerability. Results show that the logistics equipment system-of-systems heterogeneous network has similar topological structure characteristics of typical complex networks, namely small-world effect and scale-free characteristics, indicating that the flow, sharing, and synchronization between logistics equipment entities in the network are relatively easy. Meantime, the key logistics equipment nodes with large values such as degree, closeness centrality, and betweenness centrality should be protected in the logistics equipment system-of-systems heterogeneous network against deliberate attacks. The current work provides a perspective for demonstration and affords the theoretical support for development and decision-making of logistics equipment system-of-systems.

Key words: logistics equipment system-of-systems, heterogeneous network, topology analysis, equipment demonstration

Fanghua YANG, Cong JIN, Zihan ZHAO, Yanjing LU, Pei LI. Model construction and topology analysis of logistics equipment system-of-systems heterogeneous network[J]. Journal of Systems Engineering and Electronics, 2026, 37(2): 594-603.

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References 32

1	ZHANG M Y, DOU Y J, CHEN Z Y, et al Review of deep reinforcement learning and its applications in military field. Systems Engineering and Electronics, 2024, 46 (4): 1297- 1308.
2	ZHAO Q T, LI L W, SUN Z H, et al A multi-perspective study on impact of artificial intelligence on military reform. Ordnance Industry Automation, 2024, 43 (10): 1- 6.
3	WU X L, WU T T, ZHANG Z Low-cost UAVs operational network in high-end warfare. Tactical Missile Technology, 2023, (5): 157- 163.
4	SONG, X, SHI W, TAN G, et al Multi-level tolerance opinion dynamics in military command and control networks. Physica, A. Statistical Mechanics and its Applications, 2015, 437, 322- 332. doi: 10.1016/j.physa.2015.05.082
5	DONG J W, TANG W, YU M G A method for modeling and evaluating the interoperability of multi-agent systems based on hierarchical weighted networks. Journal of Systems Engineering and Electronics, 2025, 36 (3): 754- 767. doi: 10.23919/JSEE.2025.000047
6	PAN X, WANG H X, YANG Y J, et al Resilience based importance measure analysis for SoS. Journal of Systems Engineering and Electronics, 2019, 30 (5): 920- 930. doi: 10.21629/jsee.2019.05.10
7	BAI G H, LI Y J, FANG Y N, et al Network approach for resilience evaluation of a UAV swarm by considering communication limits. Reliability Engineering and System Safety, 2020, 193, 106602- 106617. doi: 10.1016/j.ress.2019.106602
8	LIU T L, YANG Z R, ZHANG H, et al Modeling and performance analysis of military communication network based on complex network. Systems Engineering and Electronics, 2020, 42 (12): 2892- 2898.
9	CAO J P, OU M X, LI Y S, et al Island air defense electronic countermeasure equipment system construction and effectiveness evaluation. Systems Engineering and Electronics, 2023, 45 (9): 2784- 2792.
10	BOCCALETTI S, LATORA V, MORENO Y, et al Complex networks: structure and dynamics. Complex Systems and Complexity Science, 2006, 424 (4/5): 175- 308.
11	YANG K W, LI J C, LIU M D, et al Complex systems and network science: a survey. Journal of Systems Engineering and Electronics, 2023, 34 (3): 543- 573. doi: 10.23919/JSEE.2023.000080
12	KEATING C, ROGERS R, UNAL R, et al System of systems engineering. Engineering Management Journal, 2003, 15 (3): 36- 45.
13	DOU Y J, ZHOU Z X, ZHAO D L, et al Weapons system portfolio selection based on the contribution rate evaluation of system of systems. Journal of Systems Engineering and Electronics, 2019, 30 (5): 905- 919. doi: 10.21629/jsee.2019.05.09
14	LI R Y, HE M, HE H Y, et al A branch and price algorithm for the robust WSOS scheduling problem. Journal of Systems Engineering and Electronics, 2021, 32 (3): 658- 667. doi: 10.23919/jsee.2021.000056
15	DoD Architecture Framework Working Group. DoD Architecture Framework, version 1.5. Washington, DC: Department of Defense, 2007.
16	DoD Architecture Framework Working Group. DoD Architecture Framework, version 2.0. Washington, DC: Department of Defense, 2009.
17	ZHANG M M, CHEN H H, MAO Y, et al An approach to measuring business-IT alignment maturity via DoDAF2.0. Journal of Systems Engineering and Electronics, 2020, 31 (1): 95- 108. doi: 10.21629/jsee.2020.01.11
18	TANG Z S Architecture modeling of anti-UAV equipment based on DoDAF. Ordnance Industry Automation, 2024, 43 (8): 55- 59. doi: 10.1109/bigdia60676.2023.10429067
19	AFSHANI J, HAROUNABADI A, DEZFOULI M A A new model for designing uncertain enterprise architecture. Management Science Letters, 2012, 2 (2): 689- 696. doi: 10.5267/j.msl.2012.01.005
20	HE H Y, ZHU W X, LI R Y, et al An executable modeling and analyzing approach to C4ISR architecture. Journal of Systems Engineering and Electronics, 2020, 31 (1): 113- 121. doi: 10.21629/jsee.2020.01.12
21	XIU S L, LUO X S, LUO AI M, et al Logic and behavior validation of C4ISR architecture description. Systems Engineering and Electronics, 2005, 27 (2): 275- 279.
22	WAGENHALS L W, SHIN I, KIM D, et al C4ISR architectures: II. A structured analysis approach for architecture design. Systems Engineering, 2015, 3 (4): 248- 287.
23	ZHANG Z C, MAO X B, SHENG L An open architecture design method of C4ISR system. Fire Control and Command Control, 2022, 47 (11): 107- 115.
24	HUANG T, GAO Q H, LIU Z H, et al Topological properties of launch platform anti-damage network based on complex network theory. Systems Engineering and Electronics, 2023, 45 (10): 3157- 3164.
25	YU B Q, LI X Y, CHENG S Q, et al A method for evaluating the effectiveness of land-air collaborative warfare system based on complex networks. Fire Control and Command Control, 2024, 49 (1): 105- 110.
26	CARES J, INCORPORATED A. An information age combat model. Proc. of the International Command and Control Research and Technology Symposium, 2024: 325−348.
27	DELLER S, BELL M I, BOWLING S R, et al Applying the information age combat model: quantitative analysis of network centric operations. International C2 Journal, 2009, 3 (1): 1- 25.
28	DELLER S, RABADI G, TOLK A, et al Organizing for improved effectiveness in networked operations. Military Operations Research, 2012, 17 (1): 5- 16. doi: 10.1002/9781118918937.ch13
29	DEKKER A H. Simulating network robustness: two perspectives on reality. Proc. of the SimTecT Simulation Conference, 2004: 126−131.
30	DEKKER A H. Network topology and military performance. Proc. of the International Congress on Modeling and Simulation, 2005: 2174−2180.
31	DEKKER A H. Analyzing C2 structures and self-synchronization with simple computational models. Proc. of the 16th International Command and Control Research and Technology Symposium, 2011: 12−14.
32	XING J C, CHEN C X, CHEN X R. Research progress on joint operation modeling based on complex networks. Proc. of the Chinese Control and Decision Conference, 2019: 2095−2099.

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Model construction and topology analysis of logistics equipment system-of-systems heterogeneous network

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