TY - JOUR
T1 - Traffic-light scheduling on the grid
AU - Kortsarz, Guy
AU - Peleg, David
PY - 1994/9/14
Y1 - 1994/9/14
N2 - This paper studies the problem of route scheduling under the telephone model of communication networks. Previous work in this model considered mostly the "broadcast" and "gossip" communication primitives. The approach studied here is that of devising simple, distributed universal schedules, that are efficient for wide families of routing instances, rather than attempting to solve individual instances separately. The paper concentrates on "traffic-light" type schedules for route scheduling on the two-dimensional grid. In order to study the problem of scheduling given route instances, routes are classified according to the number of directions they use, and tight bounds are given on the time required for scheduling route instances in each class. For routes of length d or less, using only one direction, scheduling is shown to require d+O(1) time. For simple routes using only two or three directions, scheduling is shown to require 2d + 3 and 2d + 4 time, respectively. Finally, for arbitrary simple routes scheduling is shown to require 2d+Θ( d) time.
AB - This paper studies the problem of route scheduling under the telephone model of communication networks. Previous work in this model considered mostly the "broadcast" and "gossip" communication primitives. The approach studied here is that of devising simple, distributed universal schedules, that are efficient for wide families of routing instances, rather than attempting to solve individual instances separately. The paper concentrates on "traffic-light" type schedules for route scheduling on the two-dimensional grid. In order to study the problem of scheduling given route instances, routes are classified according to the number of directions they use, and tight bounds are given on the time required for scheduling route instances in each class. For routes of length d or less, using only one direction, scheduling is shown to require d+O(1) time. For simple routes using only two or three directions, scheduling is shown to require 2d + 3 and 2d + 4 time, respectively. Finally, for arbitrary simple routes scheduling is shown to require 2d+Θ( d) time.
UR - http://www.scopus.com/inward/record.url?scp=0041804011&partnerID=8YFLogxK
U2 - 10.1016/0166-218X(94)90186-4
DO - 10.1016/0166-218X(94)90186-4
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AN - SCOPUS:0041804011
SN - 0166-218X
VL - 53
SP - 211
EP - 234
JO - Discrete Applied Mathematics
JF - Discrete Applied Mathematics
IS - 1-3
ER -