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TABLE VIII CONTROLLER 2 DESIGNED FOR dl = O, dz = 5, d3 = 10,
1998
Cited by 34
Table 1. State transition rate in asymmetric ring network model. Number of Current state
2002
"... In PAGE 7: ...In the remainder of this subsection, the argument t is omitted since we con- sider the system in equilibrium. The transition rate from the state (N(j) d , J(j) l ) is shown in Table1 . Note that we omit the superscript (j) of any notation for the simplicity.... ..."
Cited by 1
TABLE III. Summary of the mechanisms behind the current evolving network models. For each model (beyond the SF model) we list the concept or mechanism deviating from the linear growth and preferential attachment, the basic ingredients of the SF model, and the interval in which the exponent of the degree distribution can vary.
2001
Cited by 1
Table 1: Models currently in the GloMoSim library.
1999
"... In PAGE 3: ...GloMoSim is a scalable simulation library for wireless network systems built using the PARSEC simulation environment [2]. Table1 lists the GloMoSim models currently available at each of the major layers. GloMoSim also supports two different node mobility models.... ..."
Cited by 131
Table 1: Models currently in the GloMoSim library.
1999
"... In PAGE 3: ...GloMoSim is a scalable simulation library for wireless network systems built using the PARSEC simulation environment [2]. Table1 lists the GloMoSim models currently available at each of the major layers. GloMoSim also supports two different node mobility models.... ..."
Cited by 131
Table 1: Models currently in the GloMoSim library.
1999
"... In PAGE 3: ...GloMoSim is a scalable simulation library for wireless network systems built using the PARSEC simulation environment [2]. Table1 lists the GloMoSim models currently available at each of the major layers. GloMoSim also supports two different node mobility models.... ..."
Cited by 131
Table 1: Models currently in the GloMoSim library.
1999
"... In PAGE 3: ...GloMoSim is a scalable simulation library for wireless network systems built using the PARSEC simulation environment [2]. Table1 lists the GloMoSim models currently available at each of the major layers. GloMoSim also supports two different node mobility models.... ..."
Cited by 131
Table 2: Important Simulation Parameters lect). This manager repeatedly issues requests to the CPU, Disk and Network Interface managers to perform its particular operation. The Network Interface manager enforces a FCFS protocol for access to the global communications network. The Network module currently models a fully connected network and the Terminal module provides the entry point for new queries. The Query Manager constructs a query plan for executing a multi-site query. The Query Scheduler coordi- nates the execution of the operators of a multi-site query. Finally, the System Catalog manager keeps track of how many relations are de ned, what disk each relation is declustered across, which partitioning strategy is used to decluster a relation, and the number of pages of each relation on each disk. For each relation, a mapping from logical page numbers to physical disk addresses is also maintained. This physical assignment of pages allows for accurate modeling of sequential as well as random disk accesses. Indices, including both clustered and non-clustered B+ trees can be constructed on a relation. Table 5 summarizes the key parameters of the model.This simulation model was validated against the Gamma database machine (see [Sch90, Hsi90] for details).
1992
Cited by 38
Table 1 shows DMT system components and their counterpart simulation models assuming three computers and a local area network. The table as shown includes all major software and hardware components. The DEVS/DOC simulation models represent either distinctly or as an aggregate, the DMT prototype. Consider the Virtual Network Computing (VNC) server and client applications. In the current simulation of the DMT, VNC client and server are distinct software applications. However, in the DMT model they are aggregated as part of JSAF and Weapon Director software applications. That is, while the model of the DMT system is based on its prototype realization, the model and the prototype do not have a one-to-one correspondence with one another in terms of LCN and DCO layers and their OSM mapping. Nevertheless, despite the absence of such formal relationships, key architectural design considerations (e.g., scalability) of the system can be demonstrated and studied via these approximate simulation models.
in Simulation-based SW/HW Architectural Design Configurations for Distributed Mission Training Systems
"... In PAGE 7: ... 98): Processor and Media Access Unit PCJSAF, PCJSAFmau Computer (Win. NT): Processor and Media Access Unit PCDB, PCDBmau Computer (Linux): Processor and Media Access Unit PC1, PC1mau Table1 : Hardware/software components and their corresponding simulation models The system modeling effort for systems such as DMT can proceed in four steps. First, the network is defined in terms of processing nodes, gates, and links.... ..."
Table 1: Applications of ad hoc networks
"... In PAGE 2: ... 1.1 Applications We summarize some current and future applications of ad hoc networks in Table1 . The applications listed in the table are sorted by their area of use, network devices, and communication model.... ..."
Cited by 1
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