TY - JOUR
T1 - Crossover times in bipartite networks with activity constraints and time-varying switching rates
AU - Borst, Sem
AU - Hollander, Frank Den
AU - Nardi, Francesca Romana
AU - Taati, Siamak
N1 - Funding Information:
Funding. The research in this paper was supported through NWO Gravitation Grant 024.002.003–NETWORKS. ST was also supported through NWO Grant 612.001.409.
Publisher Copyright:
© Institute of Mathematical Statistics, 2022.
PY - 2022/12
Y1 - 2022/12
N2 - In this paper, we study the performance of a bipartite network in which customers arrive at the nodes of the network, but not all nodes are able to serve their customers at all times. Each node can be either active or inactive, and two nodes connected by a bond cannot be active simultaneously. This situation arises in wireless random-access networks where, due to destructive interference, stations that are close to each other cannot use the same frequency band. We consider a model where the network is bipartite, the active nodes switch themselves off at rate 1 and the inactive nodes switch themselves on at a rate that depends on time and on which half of the bipartite network they are in. An inactive node cannot become active when one of the nodes it is connected to by a bond is active. The switching protocol allows the nodes to share activity among each other. In the limit as the activation rate becomes large, we compute the crossover time between the two states where one-half of the network is active and the other half is inactive. This allows us to assess the overall activity of the network depending on the switching protocol. Our results make use of the metastability analysis for hard-core interacting particle models on finite bipartite graphs derived in an earlier paper. They are valid for a large class of bipartite networks, subject to certain assumptions. Proofs rely on a comparison with switching protocols that are not time varying, through coupling techniques.
AB - In this paper, we study the performance of a bipartite network in which customers arrive at the nodes of the network, but not all nodes are able to serve their customers at all times. Each node can be either active or inactive, and two nodes connected by a bond cannot be active simultaneously. This situation arises in wireless random-access networks where, due to destructive interference, stations that are close to each other cannot use the same frequency band. We consider a model where the network is bipartite, the active nodes switch themselves off at rate 1 and the inactive nodes switch themselves on at a rate that depends on time and on which half of the bipartite network they are in. An inactive node cannot become active when one of the nodes it is connected to by a bond is active. The switching protocol allows the nodes to share activity among each other. In the limit as the activation rate becomes large, we compute the crossover time between the two states where one-half of the network is active and the other half is inactive. This allows us to assess the overall activity of the network depending on the switching protocol. Our results make use of the metastability analysis for hard-core interacting particle models on finite bipartite graphs derived in an earlier paper. They are valid for a large class of bipartite networks, subject to certain assumptions. Proofs rely on a comparison with switching protocols that are not time varying, through coupling techniques.
KW - metastability
KW - switching protocols
KW - Wireless random-access networks
UR - http://www.scopus.com/inward/record.url?scp=85147764111&partnerID=8YFLogxK
U2 - 10.1214/22-AAP1787
DO - 10.1214/22-AAP1787
M3 - Article
AN - SCOPUS:85147764111
SN - 1050-5164
VL - 32
SP - 4279
EP - 4314
JO - Annals of applied probability
JF - Annals of applied probability
IS - 6
ER -