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Review of Reconfigurable Virtual Instrumentation and It Implementation in Cameroon Labs

Received: 12 May 2021     Accepted: 1 June 2021     Published: 16 June 2021
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Abstract

With the exponential evolution of the complexity of reconfigurable logic circuits, the Field Programmable Gate Array (FPGA) becomes an attractive element to realize reconfigurable virtual instruments, due to their inherent flexibility. The simple bus architecture allows us to use pre-exist IP Cores (IP Cores) in VHDL and interconnecting them, also allowed us to reuse code in all designs. Research on reconfigurable virtual instruments has continued to evolve and has become a real alternative for many research laboratories in developing countries such as Cameroon. In this paper, we present a review of the FPGA-Based Reconfigurable Virtual instrumentation and the experimental tools developed in our labs. The development of experimental sciences and engineering benefits from the ability to obtain reliable data from controlled situations and process as measurements and comparisons. This achievement invokes two parallel approaches: software development and hardware development. This has been demonstrated in our context with the implementation of a virtual oscilloscope. Indeed, with the processing of reconfigurable technological circuit, designing virtual instruments with multiple shapes is henceforth feasible. The advantages offered by this innovation are essentially the reduction of development times, the optimization of resources and the reduction of costs. Given the need for these instruments in research laboratories, their lack in universities in our countries poses a real problem. Fortunately, in recent years, research and technological innovation have largely developed to offer reconfigurable solutions in instrumentation based on SoCs. The oscilloscope described in this article can communicate directly with a PC, using a USB serial port that allows communication between the instruments and the PC.

Published in Journal of Electrical and Electronic Engineering (Volume 9, Issue 3)
DOI 10.11648/j.jeee.20210903.14
Page(s) 87-92
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2021. Published by Science Publishing Group

Keywords

Reconfigurable Virtual Instrumentation, FPGA, Technological Innovation, Electronic System, GPC, SoC

References
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[2] Gibbon, P., Joubert, G., Lippert, T., Mohr, B. & Peters, F. (2008). Advances in Parallel Computing, IOS Press.
[3] Hsiung, P., Santambrogio, D. & Huang, C. (2009). Reconfigurable System Design and Verification, CRC Press.
[4] USA. Hunt, A. & Thomas, D. (1999). The Pragmatic Programmer, Addison-Wesley Professional, USA.
[5] Bojan Gergič, Darko Hercog, Ladislav Mikola, Vojko Matko, Using the Internet and Virtual Instrumentation to enhance the learning of Electrical Measurements, University of Maribor, Faculty of Electrical Engineering and Computer Science.
[6] Răzvan A. Ciobotariu, Cristian Foşalău, Cristian Rotariu Pulse Wave Velocity Measuring System using Virtual Instrumentation on Mobile Device, International, Journal of Advances in Telecommunications, Electrotechnics, Signals and Systems, Vol. 2, No. 2 (2013).
[7] Maxfield, C. (2004). The Design Warrior’s Guide to FPGAs, Newnes, USA. Navabi, Z. (2006). Verilog Digital System Design, McGraw-Hill Publishing Companies, Inc., USA. Pugh, K. (2007). Interface-Oriented Design, The Pragmatic Programmers LLC., USA. Seal, R. (2008).
[8] Gazzano, Julio Daniel Dondo, Crespo, Maria Liz, Cicuttin, Andres, Calle, Fernando Rincon, Field-Programmable Gate Array (FPGA) Technologies for High Performance instrumentation, 2016.
[9] Sujesh S, Scientist C; Rajeev A, Technical Assistant; Muraleedharan CV, Scientist F, A Virtual Instrumentation (VI) based system to acquire physiological parameters during preclinical animal trials of a prosthetic heart valve device, Sree Chitra Tirunal Institute for Medical Sciences & Technology (SCTIMST), Sree Chitra Tirunal Institute for Medical Sciences & Technology (SCTIMST), 2018.
[10] Design and implementation of a multi-purpose radar controller using opensource tool, Proceedings of the IEEE.
[11] Radar Conference 2008, Rome, May 2008, pp. pp. 1–4. Stroustrup, B. (2000). The C++ Programming Language, Addison-Wesley, USA.
[12] ihir Narayan Mohanty, Biswajit Mishra, Aurobinda Routray, "FPGA implementation of constrained LMS algorithm", International Conference on Energy, Automation and Signal, 2011.
[13] Seal, R. (2008). Design and implementation of a multi-purpose radar controller using opensource tool, Proceedings of the IEEE Radar Conference 2008, Rome, May 2008, pp. 1–4.
[14] A. Taskin, T. Kumbasar, “An open source Matlab/Simulink toolbox for interval type-2 fuzzy logic systems,” Proceedings of IEEE Symposium Series on Computational Intelligence, pp. 1561–1568, 2015.
[15] Marfa Jos6 Moure, Maria Dolores Vald6s, Enrique Mandado, Virtual Instruments Based on Reconfigurable Logic.
[16] C. Quintans, M. J. Moure, R. Garcia-Valladares, M. D. Valdes, E. Mandado, A virtual instrumentation lab based on a reconfigurable coprocessor, Proceedings of the 21st IEEE Instrumentation and Measurement Technology Conference (IEEE Cat. No. 04CH37510), 2004.
[17] Lin, Guo-Ruey Tsai and Min-Chuan, FPGA-Based Reconfigurable Measurement Instruments withFunctionality Defined by User, Hindawi Publishing CorporationEURASIP Journal on Applied Signal Processing, 1–14DOI 10.1155, 2019.
Cite This Article
  • APA Style

    Gisele Beatrice Sonfack, Pabame Frederic. (2021). Review of Reconfigurable Virtual Instrumentation and It Implementation in Cameroon Labs. Journal of Electrical and Electronic Engineering, 9(3), 87-92. https://doi.org/10.11648/j.jeee.20210903.14

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    ACS Style

    Gisele Beatrice Sonfack; Pabame Frederic. Review of Reconfigurable Virtual Instrumentation and It Implementation in Cameroon Labs. J. Electr. Electron. Eng. 2021, 9(3), 87-92. doi: 10.11648/j.jeee.20210903.14

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    AMA Style

    Gisele Beatrice Sonfack, Pabame Frederic. Review of Reconfigurable Virtual Instrumentation and It Implementation in Cameroon Labs. J Electr Electron Eng. 2021;9(3):87-92. doi: 10.11648/j.jeee.20210903.14

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  • @article{10.11648/j.jeee.20210903.14,
      author = {Gisele Beatrice Sonfack and Pabame Frederic},
      title = {Review of Reconfigurable Virtual Instrumentation and It Implementation in Cameroon Labs},
      journal = {Journal of Electrical and Electronic Engineering},
      volume = {9},
      number = {3},
      pages = {87-92},
      doi = {10.11648/j.jeee.20210903.14},
      url = {https://doi.org/10.11648/j.jeee.20210903.14},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jeee.20210903.14},
      abstract = {With the exponential evolution of the complexity of reconfigurable logic circuits, the Field Programmable Gate Array (FPGA) becomes an attractive element to realize reconfigurable virtual instruments, due to their inherent flexibility. The simple bus architecture allows us to use pre-exist IP Cores (IP Cores) in VHDL and interconnecting them, also allowed us to reuse code in all designs. Research on reconfigurable virtual instruments has continued to evolve and has become a real alternative for many research laboratories in developing countries such as Cameroon. In this paper, we present a review of the FPGA-Based Reconfigurable Virtual instrumentation and the experimental tools developed in our labs. The development of experimental sciences and engineering benefits from the ability to obtain reliable data from controlled situations and process as measurements and comparisons. This achievement invokes two parallel approaches: software development and hardware development. This has been demonstrated in our context with the implementation of a virtual oscilloscope. Indeed, with the processing of reconfigurable technological circuit, designing virtual instruments with multiple shapes is henceforth feasible. The advantages offered by this innovation are essentially the reduction of development times, the optimization of resources and the reduction of costs. Given the need for these instruments in research laboratories, their lack in universities in our countries poses a real problem. Fortunately, in recent years, research and technological innovation have largely developed to offer reconfigurable solutions in instrumentation based on SoCs. The oscilloscope described in this article can communicate directly with a PC, using a USB serial port that allows communication between the instruments and the PC.},
     year = {2021}
    }
    

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    AB  - With the exponential evolution of the complexity of reconfigurable logic circuits, the Field Programmable Gate Array (FPGA) becomes an attractive element to realize reconfigurable virtual instruments, due to their inherent flexibility. The simple bus architecture allows us to use pre-exist IP Cores (IP Cores) in VHDL and interconnecting them, also allowed us to reuse code in all designs. Research on reconfigurable virtual instruments has continued to evolve and has become a real alternative for many research laboratories in developing countries such as Cameroon. In this paper, we present a review of the FPGA-Based Reconfigurable Virtual instrumentation and the experimental tools developed in our labs. The development of experimental sciences and engineering benefits from the ability to obtain reliable data from controlled situations and process as measurements and comparisons. This achievement invokes two parallel approaches: software development and hardware development. This has been demonstrated in our context with the implementation of a virtual oscilloscope. Indeed, with the processing of reconfigurable technological circuit, designing virtual instruments with multiple shapes is henceforth feasible. The advantages offered by this innovation are essentially the reduction of development times, the optimization of resources and the reduction of costs. Given the need for these instruments in research laboratories, their lack in universities in our countries poses a real problem. Fortunately, in recent years, research and technological innovation have largely developed to offer reconfigurable solutions in instrumentation based on SoCs. The oscilloscope described in this article can communicate directly with a PC, using a USB serial port that allows communication between the instruments and the PC.
    VL  - 9
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Author Information
  • Electrical Department, Advanced Vocational Technology Centre, University of Douala, Douala, Cameroon

  • Electrical Department, Advanced Vocational Technology Centre, University of Douala, Douala, Cameroon

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