Large Queue Research Articles

Fishspear: a priority queue algorithm

The Fishspear priority queue algorithm is presented and analyzed. Fishspear is comparable to the usual heap algorithm in its worst-case running time, and its relative performance is much better in many common situations. Fishspear also differs from the heap method in that it can be implemented efficiently using sequential storage such as stacks or tapes, making it potentially attractive for implementation of very large queues on paged memory systems.

The effects of lot sizing and dispatching on customer service in an MRP environment

AbstractResults are presented of a simulation analysis of a hypothetical fabrication and assembly shop controlled by material requirements planning. The purpose of the study is to investigate the impact of lot sizing on the customer service performance of dispatching techniques in an MRP‐controlled assembly job shop operating near capacity. Six dispatching techniques are compared based on the tardiness of customer orders under four lot‐sizing techniques, two levels of demand, and two levels of nervousness. The study is conducted with a stable product mix, limited production capacity, and fixed routings. Random shifts in short‐term product mix cause short‐term bottlenecks, but one of the 15 work stations has less than 10% idle time and is the most commonly encountered bottleneck.The interaction of lot‐sizing and dispatching techniques was found to be a function of capacity utilization, a factor influenced by demand and nervousness level. Under low demand, earliest job due date yielded the best performance with regard to the percentage of tardy orders, average order tardiness, and maximum order tardiness. Under high demand, earliest job due date performed best with respect to average order tardiness and maximum order tardiness, but the best dispatching technique with respect to percentage of tardy orders depended on the lot‐sizing technique and the nervous‐ness level. Under high demand and high nervousness, effective capacity decreased and queues increased with economic order quantity, period order quantity, or least total cost. Economic order quantity generated the smallest batches. Period order quantity and least total cost generated extra set‐ups under high nervousness. Use of either of the three lot‐sizing techniques at high demand and high nervousness forced a choice between a dispatching technique that yields a low percentage of orders tardy (earliest modified operation due date) and one that generates low maximum order tardiness (earliest job due date). The Silver‐Meal heuristic consumed less effective capacity than the other lot‐sizing techniques. Using Silver‐Meal at high demand and nervousness, earliest job due date performed best with respect to each tardiness measure.The bottleneck causes the plant to behave like a single machine shop. Since large queues are maintained at the bottleneck, that is where the choice of dispatching technique is critical. Earliest due date minimizes the percentage of tardy orders. Earliest modified operation due date, operating like the shortest processing time rule, minimizes the percentage of tardy orders, but maximum tardiness is high. These results may stimulate new interest in single‐machine scheduling.The combination of least total cost and earliest job due produced the best overall performance at low demand. At high demand, Silver‐Meal and earliest job due date achieved the best performance.

A theory of traffic flow for congested conditions on urban arterial streets I: Theoretical development

In an earlier paper, Vaughan, Hurdle and Hauer posed a time-dependent traffic flow problem in which travellers go home from work on a long arterial street. Each traveller enters the street at a particular time and place, bound for some given destination as prescribed by a continuous trip density function, but the time at which his or her trip is completed depends on the traffic conditions en route; hence on the origins, destinations, and departure times of other motorists. A solution was obtained, but a solution that is valid only if no intersection becomes saturated. In this paper, the analysis is extended to cover cases where some key intersection does become saturated. The model is macroscopic and differs from alternative models of traffic flow in two ways. The first and more important is that the impact of the origin destination pattern on the traffic dynamics and vice versa are explicitly recognized and included in the model. This is particularly important when the impact of exit flows on downstream facilities is an issue and in applications involving route choice or elastic demand, since it allows choices based on the travel times that would be experienced by the travellers actually making the decisions. The second difference is that it is explicitly a queueing model: the basic assumption is that intersections along the roadway have capacities and that when the capacity of some key intersection is exceeded by the arrival flow, the large queue that results will be the dominant element controlling subsequent operation of the system.

Consistency of infinitesimal perturbation analysis estimators with rates

We study a class of infinitesimal perturbation analysis (IPA) algorithms for queueing systems with load-dependent service and/or arrival rates. Such IPA algorithms were originally motivated by applications to large queueing systems in conjunction with aggregation algorithms. We prove strong consistency of these estimators through a type of birth and death queue.

Experience in organizing a pediatric ophthalmological service in Naberezhnye Chelny

In the city, which has 160 thousand children, by 1989 there was an extremely unfavorable situation with the provision of ophthalmic care to them. In a specialized kindergarten for the treatment of strabismus and amblyopia, 6 children's oculists work (that is, 6.5 staff units are employed against the standard 16.5). Due to the shortage of personnel, large queues were created for an appointment with a doctor, who worked with great overloads (having no material interest).

Dynamic queue behavior in networks with window protocols

Dynamic queue behavior in networks with window protocols

Controlling Input: The Real Key to Shorter Lead Times

Operations managers are now more than ever acutely aware of the importance of Manufacturing Lead Times (MLT). Tremendous advantages such as increased flexibility, increased responsiveness, decreased work in process (WIP) inventories, improved due date performance, and decreased finished goods inventory can be realized with a shorter MLT. Unfortunately, US manufacturers have not been very successful at efforts to reduce MLT. This is especially true for those companies using MRP. In MRP, component lead times are often exaggerated to insure that sufficient time is available for the completion of all components. With the exaggeration of component lead times comes an increased manufacturing lead time. Also, due to the normally accepted weekly time bucket, a product with six levels in its bill of materials requires a minimum of six weeks to manufacture. A second reason US companies have failed to significantly reduce MLT is the over‐emphasis on machine utilizations. When plant performance is based on overall utilization, shop floor foremen try to maintain a sufficient level of work in front of their department to ensure that the machines are never starved. As a result of these large queues at each workcentre, a high level of WIP in the entire plant is maintained. And, due to the direct relationship between lead times and WIP to be discussed later, as the level of WIP increases, a proportional increase in lead time follows.

A picture archiving and communication system module for radiology

This paper presents the design and implementation of a clinical picture archiving and communication system (PACS) module within the radiology department of a 700-bed teaching hospital. The system is composed of an integrated network of digital devices used to electronically acquire, store, manage, and display radiological text and image information. Operationally the system behaves as a large queueing network allowing processes to operate concurrently in a coordinated and prioritized fashion. Secondary reviews (radiology conferences and fast case reviews by clinicians) are being conducted from a 512 × 512 CRT viewing station. Preliminary evaluation based on formal survey and usage statistics shows that the system is rapidly being accepted by radiologists and clinicians for the review and processing of digital radiographic images.

A Frame-Based Mission Decomposition Model

This paper presents the results of a mathematical modeling (computer simulation) effort that applied frame-based, data processing constructs, originally developed and applied in the context of artificial intelligence, to the decomposition of a complex Air Force bomber mission. The model was written in LISP to facilitate the development of a concurrent processing environment in which to simulate the simultaneous occurrence of multiple external events/crew tasks. The model simulated a four hour segment of a strategic mission scenario. Two distinct crew complements, four-man and two-man, together with their respective levels of aircraft avionics automation, were represented during a proof-of-concept demonstration. The model provided measures of resource (crew and “black box”) utilization, presumed to correlate to “workload,” at different levels of specificity. These measures were used to identify crew task “chokepoints” (large queue sizes, task interrupts) and to evaluate the effects of automation.

Capacity analysis of a manufacturing cell

Abstract Traditional capacity analysis in manufacturing assumes that capacity is adequate if average utilization is under 100%. In practice, high utilization levels result in the formation of large queues, which in turn cause high production lead times and work-in-process inventories. Queueing models of manufacturing cells have been successfully used to analyze the relationships between utilization and queues. However, these models do not consider the impact of operational policy on the performance characteristics of the facility; this impact can be substantial. Here we describe the capacity analysis of a cell in which alternative overtime and shift policies, equipment choice and batching policy are considered. It is seen that in an integrated cell configuration, excess equipment capacity may be economically preferable to multiple shifts.

A Clustering Approximation Technique for Queueing Network Models with a Large Number of Chains

The past few years have witnessed an increasing number of large distributed computer system implementations based on local area networks. In these systems a number of resources (CPU's, file servers, disks, etc.) are shared among jobs originating at different sites. Evaluating the performance of such large systems typically requires the solution of a queueing network model with a large number of closed chains, which precludes the use of exact solution techniques. Therefore, it is important to develop accurate and cost-effective methods for the approximate analysis of closed queueing networks with many chains. In this paper, we present an approach based on the clustering of chains and service centers. The method is applicable to queueing networks with single server fixed rate, infimite server and multiple server service centers. We present the results obtained when the method is used to solve large queueing network models. Extensive comparison of this method to existing approximation techniques indicates that the approach has better accuracy/cost characteristics.

Scheduling of re‐entrant flow shops

AbstractWe propose and develop a scheduling system for a very special type of flow shop. This flow shop processes a variety of jobs that are identical from a processing point of view. All jobs have the same routing over the facilities of the shop and require the same amount of processing time at each facility. Individual jobs, though, may differ since they may have different tasks performed upon them at a particular facility. Examples of such shops are flexible machining systems and integrated circuit fabrication processes. In a flexible machining system, all jobs may have the same routing over the facilities, but the actual tasks performed may differ; for instance, a drilling operation may vary in the placement or size of the holes. Similarly, for integrated circuit manufacturing, although all jobs may follow the same routing, the jobs will be differentiated at the photolithographic operations. The photolitho‐graphic process establishes patterns upon the silicon wafers where the patterns differ according to the mask that is used.The flow shop that we consider has another important feature, namely the job routing is such that a job may return one or more times to any facility. We say that when a job returns to a facility it reenters the flow at that facility, and consequently we call the shop a re‐entrant flow shop. In integrated circuit manufacturing, a particular integrated circuit will return several times to the photolithographic process in order to place several layers of patterns on the wafer. Similarly, in a flexible machining system, a job may have to return to a particular station several times for additional metal‐cutting operations.These re‐entrant flow shops are usually operated and scheduled as general job shops, ignoring the inherent structure of the shop flow. Viewing such shops as job shops means using myopic scheduling rules to sequence jobs at each facility and usually requires large queues of work‐in‐process inventory in order to maintain high facility utilization, but at the expense of long throughput times.In this paper we develop a cyclic scheduling method that takes advantage of the flow character of the process. The cycle period is the inverse of the desired production rate (jobs per day). The cyclic schedule is predicated upon the requirement that during each cycle the shop should perform all of the tasks required to complete a job, although possibly on different jobs. In other words, during a cycle period we require each facility to do each task assigned to it exactly once. With this requirement, a cyclic schedule is just the sequencing and timing on each facility of all of the tasks that that facility must perform during each cycle period. This cyclic schedule is to be repeated by each facility each cycle period. The determination of the best cyclic schedule is a very difficult combinatorial optimization problem that we cannot solve optimally for actual operations. Rather, we present a computerized heuristic procedure that seems very effective at producing good schedules. We have found that the throughput time of these schedules is much less than that achievable with myopic sequencing rules as used in a job shop. We are attempting to implement the scheduling system at an integrated circuit fabrication facility.

An Overview of PANACEA, a Software Package for Analyzing Markovian Queueing Networks

PANACEA is a software package that significantly extends the range of Markovian queueing networks that are computationally tractable. It solves multi-class closed, open, and mixed queueing networks. Based on an underlying theory of integral representations and asymptotic expansions, PANACEA solves queueing networks that are orders of magnitude larger than can be solved by other established algorithms. The package is finding widespread use in Bell Laboratories. It also has important software innovations. A flexible programming-language-like interface facilitates compact representation of large queueing networks. An out-of-core implemental strategy enables PANACEA to be ported to processors with modest memory. The modular structure of this software package, along with the automatic machine-generated parser, makes it easily extendable. This paper provides an overview of two basic versions of PANACEA, versions 1.0 and 1.1, which solve “closed” networks only. A description of its model language is given from the point of view of its capability to describe queueing networks in a compact, natural manner. The paper discusses the algorithms, together with their time and storage requirements, that are used in the implementation. Several numerical examples are given.

A Traffic Overflow System With a Large Primary Queue

We analyze a traffic overflow system that consists of two groups of trunks, with waiting spaces for each group, and some overflow capability from the primary to the secondary group. We consider the case in which the number of waiting spaces in the primary queue is large compared to the corresponding number in the secondary queue and to the number of trunks in the secondary group. The case of an infinite number of waiting spaces in the primary queue is also allowed. We contrast the approach presented with some previous approaches that are suitable when the number of waiting spaces in the primary queue is not comparatively large. As with previous approaches, the aim is to reduce the dimensions of the system of equations to be solved in order to calculate various steady-state quantities of interest. Our results include expressions for the loss probabilities, the probability of overflow from the primary to the secondary group, and the average waiting times in the queues. We also obtain the stability condition under which the results are valid when the number of waiting spaces in the primary queue is infinite.

Some Traffic Overflow Problems with a Large Secondary Queue

When calls offered to a primary group of trunks find all of them busy, provisions are often made for these calls to overflow to other groups of trunks. Such traffic overflow systems have been of interest for a long time, but recently overflow systems that allow for some calls to be queued have been of importance. In this paper we analyze a traffic overflow system with queuing. The system consists of two groups, a primary and a secondary. We consider two cases which differ in the treatment of demands waiting in the primary queue. We present an analytical approach which is suitable if the secondary queue is large, or even infinite, and we contrast it with an earlier approach of ours which is more suitable if the secondary queue is not large. The analysis considerably reduces the dimensions of the problem and simplifies the calculation of various steady-state quantities of interest. Our results include expressions for the loss probabilities, the average waiting times in the queues, and the average number of demands in service in each group.

Approximation Methods for Queues with Application to the Fixed-Cycle Traffic Light

Approximations based upon the representation of the queue as a continuous fluid with either deterministic or stochastic properties are applied to the analysis of models of a fixed-cycle traffic light. These approximations are based upon the use of a law of large numbers or a central limit theorem and are not very sensitive to the detailed stochastic structure of the arrival or departure processes. In the applications considered here these approximations give delays correct to within a few percent. Introduction. The main object of the following paper is to describe and illustrate some approximation methods that can be used to obtain rough estimates of queue lengths, delays, etc., for various queueing problemis, particularly highway traffic intersection problems, which may be too difficult to solve exactly, or if solved exactly give formulas that are more detailed than one needs for the purpose of making quick estimates. The types of approximation we have in mind are those that will apply when the average queue lengths are much larger than 1. They will be asymptotic approximations that strictly speaking are valid only in the limiit of infinite queues, but ones which still give rough estimates for finite but large queues (perhaps of the order of 10). There is an extensive literature on queueing theory including at least a half dozen books and several hundred papers, but the vogue in queueing theory has been to obtain exact solutions of highly idealized models of various processes (exact, however, only in the sense that one usually must invert a few generating functions or Laplace transforms to obtain the quantities one really wants). Consequently the practical value of queueing theory has been severely limited by the lack of approximation methods which one can use to analyse more difficult problems, to estimate errors introduced by the model, or even to compute numbers from very cumbersome exact formulas. A few attempts, however, have been mnade in recent years to break away from the now standard analytic techniques. Particularly noteworthy are the works of Kingman [1], who has shown that properties of nearly saturated queues are rather insensitive to the detailed form of the arrival or service distributions, and of Benes [2], who has shown that many of the results of queueing theory do not depend upon some of the customary statistical independence assumptions. Even here, however, mathematical elegance takes precedence over intuition or applications. In the literature on traffic theory there are already at least 20 references relating to the single problem of delays at a fixed-cycle traffic light, three quarters of which are primarily directed toward a fruitless pursuit of simple exact solutions * Received by the editors October 19, 1964, and in revised form November 19, 1964. t Division of Applied Mathematics, Brown University, Providence, Rhode Island. Part of this work was done while the author was a Fulbright professor at the University of Adelaide, South Australia. The work was also supported in part by the National Science Foundation at Brown University.