Construct the closed-form solution of A-net of Petri nets by case study

Abstract: After our researches on the effect of a non-sharing resource in a kth order which is the concept of customization manufacturing, in this article we extend the research on the closed-form solution of control-related states to the so-called Anet which has one top non-sharing circle subnet connected to the idle place of left process in a deficient kth order system and is the fundamental model of different productions sharing the same common parts in manufacturing. The formulas just are depended on the parameter k… Show more

“…Figure 3(a,b)). According to the concept of a Complete reachability graph, Chao (2014) split the reachability graph of a PN N into reachable (from the initial state), live (reachable to the initial state), forbidden (reachable to the livelock (Chao & Yu, 2017) or deadlock states only), livelock (Chao & Yu, 2017) (reachable to the livelock state only), deadlock (reachable to no state), non-reachable (from the initial state) and non-reachable+ empty-siphon states (both non-reachable states in a N and the rev(N)). Due to the independence between the set of live and forbidden states, we have F = R -L, where R, F and L are the number of reachable, forbidden and live states of a PN.…”

“…The formulas are consistent with the reachability analysis using the INA (Integrated Net Analyzer) tool (Starke, 1992). Chao and Yu (2017) showed that the Deficient k-th order system is the essential element of a k-th order system with a non-sharing sub-net (NNS) (as shown in Figure 5) because the NNS will share some tokens in the idle place of left-hand-side process. Beside, Chao and Yu showed that there are so-called livelock states that presently INA cannot detect in such a system.…”

“…Even mixed integer programming (MIP) method applied for system-control applications in PNs (Li, Wu, et al, 2012;Nazeem et al, 2011;Wang et al, 2020), the non-deterministic polynomial-time hard (NP-hard) characteristic of the MIP (Schrijver, 1998) still limits the size of real-time systems modelled in real application. Chao (2014) broke through this barrier earlier by proposing that we can apply mathematics in terms of closed-form solutions (CFSs) to solve the reachability problem of PNs, and then constructing a solid theoretical framework based on graph theory to derive the CFS of the number of reachable, live, forbidden, deadlock, livelock (added by Chao and Yu (2017)), non-reachable and CONTACT Tsung Hsien Yu yutsunghsien@gmail.com No. 59, Nongquan Rd., Yilan City, Yilan County 260006, Taiwan (R.O.C.…”

Topological reverse mirroring: a new efficient knowledge-based methodology of reachability analysis for Petri nets

“…Figure 3(a,b)). According to the concept of a Complete reachability graph, Chao (2014) split the reachability graph of a PN N into reachable (from the initial state), live (reachable to the initial state), forbidden (reachable to the livelock (Chao & Yu, 2017) or deadlock states only), livelock (Chao & Yu, 2017) (reachable to the livelock state only), deadlock (reachable to no state), non-reachable (from the initial state) and non-reachable+ empty-siphon states (both non-reachable states in a N and the rev(N)). Due to the independence between the set of live and forbidden states, we have F = R -L, where R, F and L are the number of reachable, forbidden and live states of a PN.…”

“…The formulas are consistent with the reachability analysis using the INA (Integrated Net Analyzer) tool (Starke, 1992). Chao and Yu (2017) showed that the Deficient k-th order system is the essential element of a k-th order system with a non-sharing sub-net (NNS) (as shown in Figure 5) because the NNS will share some tokens in the idle place of left-hand-side process. Beside, Chao and Yu showed that there are so-called livelock states that presently INA cannot detect in such a system.…”

“…Even mixed integer programming (MIP) method applied for system-control applications in PNs (Li, Wu, et al, 2012;Nazeem et al, 2011;Wang et al, 2020), the non-deterministic polynomial-time hard (NP-hard) characteristic of the MIP (Schrijver, 1998) still limits the size of real-time systems modelled in real application. Chao (2014) broke through this barrier earlier by proposing that we can apply mathematics in terms of closed-form solutions (CFSs) to solve the reachability problem of PNs, and then constructing a solid theoretical framework based on graph theory to derive the CFS of the number of reachable, live, forbidden, deadlock, livelock (added by Chao and Yu (2017)), non-reachable and CONTACT Tsung Hsien Yu yutsunghsien@gmail.com No. 59, Nongquan Rd., Yilan City, Yilan County 260006, Taiwan (R.O.C.…”

Topological reverse mirroring: a new efficient knowledge-based methodology of reachability analysis for Petri nets

Constructing the closed-form solution of control-related states real-time information for insufficient k-th order systems with one non-sharing resource to realize dynamic modeling large TNCS systems of petri nets

Reachability-related analysis of double-deficient k-th order systems of Petri nets in terms of a closed-form solution