Industrial systems with protective devices (PDs) perform essential tasks but face significant failure risks. Under certain conditions, missions should be aborted to initiate rescue processes, balancing the system survivability and the task success probability. However, the task abort strategy for systems assembled with PDs is understudied. To bridge this research gap, this paper establishes a reliability model for the mission-oriented k-out-of-n: F system with multiple subsystems assembled with PDs in a shock environment and optimizes a policy for guiding its mission termination. Each subsystem is assigned to complete a certain proportion of the entire missions and the mission completion speed of different subsystems varies. New task abort criteria are built by integrating the state information of subsystems and their PDs. Mission success is defined by the proportion of subsystems achieving their subtasks, meeting a threshold. A comprehensive method mixing Markov process and universal generating function is built to derive reliability and mission related indexes. Two optimization models with different objective functions are built and solved to derive the optimum mission abort policy. Finally, a case study with Automated Guided Vehicles verifies the research results and model applicability.
YangZLyuHZhaoY, et al. Reliability assessment for bolt joint system with multiple dependent competing failure processes. Proc Inst Mech Eng Part O: J Risk Reliab2024; 239(5): 1016–1023.
2.
ShiHAbubakarMBaiX, et al. Vibration isolation methods in spacecraft: a review of current techniques. Adv Space Res2024; 73(8): 3993–4023.
3.
DuiHZhangCZhengX.Component joint importance measures for maintenances in submarine blowout preventer system. J Loss Prev Process Ind2020; 63: 104003.
4.
ShenJHuJMaY.Two preventive replacement strategies for systems with protective auxiliary parts subject to degradation and economic dependence. Reliab Eng Syst Saf2020; 204: 107144.
5.
ShenJZhangYMaY, et al. A novel opportunistic maintenance strategy for systems with dependent main and auxiliary components. IMA J Manag Math2021; 32(1): 69–90.
6.
ZhangNZhangJShenJ.Reliability and maintenance analysis of a system with dependent main and auxiliary components. Comput Ind Eng2023; 179: 109188.
7.
ShenJXuJDuanY, et al. Reliability modelling for systems degrading in Markovian environments with protective auxiliary components. Proc Inst Mech Eng Part O: J Risk Reliab2024; 239(4): 858–872.
8.
ChenYZhangWXuD.Reliability assessment with varying safety threshold for shock resistant systems. Reliab Eng Syst Saf2019; 185: 49–60.
9.
WangXChenXZhaoX, et al. Reliability analysis of self-healing systems equipped with multi-component protective devices operating in a shock environment. Reliab Eng Syst Saf2024; 244: 109844.
10.
WangXWangJZhaoX, et al. Optimal reassignment policy for a balanced system with multi-state subsystems supported by protective devices in a shock environment. Reliab Eng Syst Saf2026; 270: 112185.
11.
WangXNingRZhaoX, et al. Reliability assessments for two types of balanced systems with multi-state protective devices. Reliab Eng Syst Saf2023; 229: 108852.
12.
NingRWangXZhaoX, et al. Joint optimization of preventive maintenance and triggering mechanism for k-out-of-n: F systems with protective devices based on periodic inspection. Reliab Eng Syst Saf2024; 251: 110396.
13.
NingRWangXZhaoX, et al. Joint optimization of maintenance and spares inventory policies for a series system with multiple voting subsystems supported by protective devices. Proc Inst Mech Eng Part O: J Risk Reliab2025; 239(1): 79–96.
14.
ZhaoXLiZWangX, et al. Reliability analysis of a system including multi-state demand-based subsystems supported by protective devices considering two types of triggering errors. Comput Ind Eng2024; 198: 110673.
15.
DuiHZhangHDongX, et al. Cascading failure and resilience optimization of unmanned vehicle distribution networks in IoT. Reliab Eng Syst Saf2024; 246: 110071.
16.
QiuQMaillartLProkopyevO, et al. Optimal condition-based mission abort decisions. IEEE Trans Reliab2023; 72(1): 408–425.
17.
MyersA.Probability of loss assessment of critical k-out-of-n: G systems having a mission abort policy. IEEE Trans Reliab2009; 58: 694–701.
18.
LevitinGXingLDaiY.Co-optimization of state dependent loading and mission abort policy in heterogeneous warm standby systems. Reliab Eng Syst Saf2018; 172: 151–158.
19.
YangLMaYWeiF, et al. Optimal condition-based parameter learning and mission abort decisions. Nav Res Logist. Epub ahead of print 25August2024. https://doi.org/10.1002/nav.22225
20.
PalaniappanMJyothiVChowdhuryT, et al. A method for evaluating safety reliability of descend/ascend drop-weight system and mission abort decision for deep-ocean scientific human submersibles. Sci Rep2024; 14(1): 19266.
21.
LevitinGFinkelsteinM.Optimal mission abort policy for systems operating in a random environment. Risk Anal2018; 38(4): 795–803.
22.
PengR.Joint routing and aborting optimization of cooperative unmanned aerial vehicles. Reliab Eng Syst Saf2018; 177: 131–137.
23.
QiuQCuiL.Gamma process based optimal mission abort policy. Reliab Eng Syst Saf2019; 190: 106496.
24.
ZhaoXLiZWangX, et al. Reliability and mission abort strategy for a multi-state k-out-of-n: F system in a dynamically changing shock environment. Reliab Eng Syst Saf2025; 264: 111433.
25.
LevitinGXingLDaiY.Using kamikaze components in multi-attempt missions with abort option. Reliab Eng Syst Saf2022; 227: 108745.
26.
LevitinGXingLDaiY.Optimizing partial component activation policy in multi-attempt missions. Reliab Eng Syst Saf2023; 235: 109251.
27.
LevitinGXingLDaiY.Optimal system loading and aborting in additive multi-attempt missions. Reliab Eng Syst Saf2024; 251: 110315.
28.
GaoHTuTFangC, et al. Multi-state k-out-of-n: F network system performance evaluation by considering a balance dependence mechanism. Reliab Eng Syst Saf2025; 264: 111291.
29.
ZhaoXNingRWangX, et al. Maintenance optimization for production systems with polytype engineers under limited maintenance capability: a reinforcement learning approach. IEEE Trans Reliab2025; 74: 5780–5791.
30.
JiaXXingLSongX.Aggregated Markov-based reliability analysis of multi-state systems under combined dynamic environments. Qual Reliab Eng Int2020; 36(3): 846–860.
31.
DuiHLuYWuS.Competing risks-based resilience approach for multi-state systems under multiple shocks. Reliab Eng Syst Saf2024; 242: 109773.
32.
WangJYangX.Inventory optimization of spare parts for k-out-of-n pairs: G balanced systems. Proc Inst Mech Eng Part O: J Risk Reliab2025; 239(6): 1539–1555.
33.
YiKXiaoHKouG, et al. Trade-off between maintenance and protection for multi-state performance sharing systems with transmission loss. Comput Ind Eng2019; 136: 305–315.
34.
XiaoHYiKPengR, et al. Reliability of a distributed computing system with performance sharing. IEEE Trans Reliab2021; 71(4): 1555–1566.
35.
SuPWangGDuanF.Reliability analysis for k-out-of-(n+1): G star configuration multi-state systems with performance sharing. Comput Ind Eng2021; 152: 106991.
36.
WangWFangCSiP, et al. Reliability analysis of interval-valued multi-state sliding window system for sequential tasks. Comput Ind Eng2024; 188: 109924.
37.
Mahdavi-NasabNArdakanM.Reliability optimization of multi-state consecutive sliding window systems under different activation strategies. Comput Ind Eng2023; 181: 109292.
38.
YiKKouGGaoK, et al. Optimal allocation of multi-state elements in a sliding window system with phased missions. Proc Inst Mech Eng Part O: J Risk Reliab2021; 235: 50–62.
TsungCChangFLiuX.On the construction of an edge-based remote sensing framework: the applications on automated guided vehicles and drones. Electronics2022; 11(7): 1034.
41.
Fontenla-CarreraGPensadoEVeiga-LópezF, et al. Efficient offshore wind farm inspections using a support vessel and UAVs. Ocean Eng2025; 332: 121416.
42.
AlqefariSMenaiM.Multi-UAV task assignment in dynamic environments: current trends and future directions. Drones2025; 9(1): 75.
43.
VismanisOArentsJFreivaldsK, et al. Robotic system for post office package handling. Appl Sci2023; 13(13): 7643.
44.
LevitinGFinkelsteinMDaiY.Mission abort and rescue for multistate systems operating under the Poisson process of shocks. Reliab Eng Syst Saf2020; 202: 107027.
45.
WangXWangLChenX, et al. Joint optimization of protection adjustment and preventive maintenance policies for multi-state self-healing systems with protective devices in a shock environment. Reliab Eng Syst Saf2026; 269: 112000.
46.
LyuHWeiHXieH, et al. Mixed shock model for the multi-state system with a two-phase degradation process under Markov environment. Reliab Eng Syst Saf2025; 264: 111254.
47.
ChadjiconstantinidisSEryilmazS.Reliability of a mixed δ-shock model with a random change point in shock magnitude distribution and an optimal replacement policy. Reliab Eng Syst Saf2023; 232: 109080.
