Telecommunication networks are based on crossbar switching structure. Non-blocking crossbar switching structure is used crosspoint switch fabric ICs. High performance non-blocking matrixes cross point switches are use to avoid the congested path to the output, and eliminate the bandwidth problem of one at a time. Telecommunication switching uses multistage crossbar switching to overcome the limitations of individual chips or boards. The research paper focuses on the FPGA implementation of 64 x 64 three stage telecommunication switching. The generic architecture scheme is followed to implement 64 x 64 three stage network configuration, with 64 inlets and 64 outlets as cluster size. The design is developed with the help of Xilinx ISE 14.2, software, synthesized on Virtex- 5 FPGA, and function simulation is carried out in Modelsim 10.1b student edition. Very High Speed Integrated Circuit Hardware Description Language (VHDL) is used to develop the design. © 2015 The Authors. Published by Elsevier B.V.

Sonal Singhal

Electrical Engineering

(SoE) School of Engineering

Kumar A.

Kuchhal P.

Fulltext

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Shiv Nadar University

Procedia Computer Science

The research article presents the design of five stage multistage telecommunication switching and FPGA synthesis. The cluster configuration of the designed network is 256 × 256 that supports maximum 3.436 × 10 10 calls simultaneously using 6,356,992 paths under the condition of full available network. Multistage switches are amenable to modular design and guarantees full available network. Modular design approach is used to build the large scale network, which can be fabricated easily using VLSI technology. The modular structure used to implement 256 × 256 five stage designs is 2 × 128 in first stage, 128 × 128 in second stage, 128 × 128 in third stage, 128 × 128 in fourth stage, and 128 × 2 in fifth stage. Moreover, the memory utilization has been found increased when number of nodes varied from 2 × 2 to 256 × 256 cluster size for the network. The design is developed with the help of Xilinx ISE 14.2 using VHDL, synthesized on Virtex-5 FPGA, and function simulation is carried out in Modelsim 10.1b student edition. The experimental set up ensures the successful transmission of data among inlets/outlets of the developed five stage network chip. © 2017, Springer Science+Business Media, LLC.

Wireless Personal Communications

Five Stage Telecommunication Switching Design and Synthesis

The research article presents the hardware chip design and FPGA implementation of the four-stage telecommunication switching system. The switching capacity of the exchange is increased with the implementation of the programmable multistage network. In multistage network, there are alternate paths to provide the availability of the network. The four-stage switching provides more capacity in comparison to three-stage switching. Modular design approach is used to build the large-scale network, which can be fabricated easily using VLSI technology. The design is carried for 8 × 8 switching network. The work is carried out in Xilinx ISE 14.2 software using VHDL programming language and synthesized on Vitex-5 FPGA. © Springer Science+Business Media Singapore 2017.

Advances in Intelligent Systems and Computing

Four-stage telecommunication switching design and synthesis

Integration

Network-on-Chip design and synthesis outlook

The Journal of Supercomputing

A Novel Multistage Network Architecture with Multicast and Broadcast Capability

Journal of Systems Architecture

QNoC: QoS architecture and design process for network on chip

Design and FPGA synthesis of three stage telecommunication switching in HDL environment