Analysis of multistation production systems with limited buffer capacity. I: The subsystem model
From MaRDI portal
Publication:1368536
DOI10.1016/S0895-7177(97)00052-6zbMath0893.90080OpenAlexW2092977345MaRDI QIDQ1368536
Publication date: 13 November 1997
Published in: Mathematical and Computer Modelling (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/s0895-7177(97)00052-6
decompositiontandem queuesquasi birth-death processeslimited interstation buffersperformance of multistation production systemsstation breakdownthroughput analysis
Related Items (7)
Analysis of multistation production systems with limited buffer capacity. II: The decomposition method ⋮ Discrete time model for two-machine one-buffer transfer lines with restart policy ⋮ The two-machine one-buffer continuous time model with restart policy ⋮ A three-station merge system with unreliable stations and a shared buffer ⋮ Variance of the output as a function of time: Production line dynamics ⋮ A general theory on spectral properties of state-homogeneous finite-state quasi-birth-death processes ⋮ Models of production lines as quasi-birth-death processes
Cites Work
- Unnamed Item
- Unnamed Item
- A continuous materials flow production line model with station breakdown
- Efficiency and production rate of a transfer line with two machines and a finite storage buffer
- Analysis of multistation production systems with limited buffer capacity. II: The decomposition method
- An Efficient Decomposition Method for the Approximate Evaluation of Tandem Queues with Finite Storage Space and Blocking
- A Method for Solving Algebraic Equations Using an Automatic Computer
- An Algorithmic Solution to Two-Stage Transfer Lines with Possible Scrapping of Units
- Birth-and-death processes on the integers with phases and general boundaries
- Modeling and Analysis of Three-Stage Transfer Lines with Unreliable Machines and Finite Buffers
This page was built for publication: Analysis of multistation production systems with limited buffer capacity. I: The subsystem model
