This is a study of the economic behavior of vendors of service in competition. A simple model with two competing exponential servers and Poisson arrivals is considered. Each server is free to choose his own service rate at a cost per time unit that is strictly convex and increasing. There is a fixed reward to a server for each customer that he serves. The model is designed to study one specific aspect of competition, namely, competition in speed of service as a means for capturing a larger market share in order to maximize long-run expected profit per time unit. A two-person strategic game is formulated and its solutions are characterized. Depending on the revenue per customer served and on the cost of maintaining service rates, the following three situations may arise: i a unique symmetric strategic Nash equilibrium in which expected waiting time is infinite; ii a unique symmetric strategic equilibrium in which expected waiting time is finite; and iii several, nonsymmetric strategic equilibria with infinite expected waiting time. An explicit expression for the market share of each server as a function of the service rates of the two servers is also given.
[1]
P. Naor.
The Regulation of Queue Size by Levying Tolls
,
1969
.
[2]
Michael J. Magazine,et al.
A Classified Bibliography of Research on Optimal Design and Control of Queues
,
1977,
Oper. Res..
[3]
S. Stidham,et al.
Individual versus Social Optimization in the Allocation of Customers to Alternative Servers
,
1983
.
[4]
M. Rubinovitch.
The Slow Server Problem
,
1983
.
[5]
Jacques Teghem,et al.
Control of the service process in a queueing system
,
1986
.
[6]
Lode Li.
The role of inventory in delivery-time competition
,
1992
.