Elektronik devrelerin gerçek zamanlı bode diyagramlarının LabVIEW ile elde edilmesi

Bode diyagramı, bilim ve mühendisliğin birçok alanında kullanılan, kısaca frekans cevabı analizi olarak tanımlanan bir kavramdır. LabVIEW; verilerin toplanması, işlenmesi ve analizlerinin yapılabilmesi için çok uygun ve işlevli bir programdır. Bu çalışmada, SI Bode Plot VI gibi özel VI'lar (sanal enstrümanlar) kullanılmadan, elektronik devrelerin gerçek zamanlı bode diyagramlarının LabVIEW programı ile elde edilmesine yönelik farklı bir çalışma gerçekleştirilmiştir. Ayrıca, gerçekleştirilen çalışma, çok sık kullanılan MATLAB veya C gibi diğer platformlara da kolaylıkla entegre edilerek, gerçek zamanlı bode diyagram sonuçları alınabilir. LabVIEW’de elde edilen bode diyagram sonuçları, ORCAD-PSpice benzetim sonuçları ile karşılaştırılarak, yapılan çalışmanın başarımı gösterilmiştir.

Obtaining real-time Bode (analysis) of electronic circuits with LabVIEW

Bode diagram is a term used in many fields of science and engineering that can be described as frequencyresponse analysis. LabVIEW is a multifunctional program for acquiring, processing and analyzing data. Inthis paper, real time Bode diagram of electronic circuits are obtained in LabVIEW platform without usingspecial VIs(virtual instruments) such as SI Bode Plot VI. In addition to this, the realized study can be easilyintegrated in to other commonly used platforms such as MATLAB and C to obtain bode diagram results inreal time. To evaluate performance of the realized study, Bode diagram results obtained from LabVIEW isBode diagram is a term used in many fields of science and engineering that can be described as frequencyresponse analysis. LabVIEW is a multifunctional program for acquiring, processing and analyzing data. Inthis paper, real time Bode diagram of electronic circuits are obtained in LabVIEW platform without usingspecial VIs(virtual instruments) such as SI Bode Plot VI. In addition to this, the realized study can be easilyintegrated in to other commonly used platforms such as MATLAB and C to obtain bode diagram results inreal time. To evaluate performance of the realized study, Bode diagram results obtained from LabVIEW iscompared with the results obtained from ORCAD-PSpice simulations.compared with the results obtained from ORCAD-PSpice simulations.

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National Instruments. [Online]. Available: http://www.ni.com/labview/, LabVIEW, National Instruments Website. [Accessed: 04-May-2017].
Beyon, Jeffery Y. LabVIEW programming, data acquisition and analysis. Prentice Hall PTR, 2000.
A. Mason and S. Parkes, “Using SpaceWire with LabVIEW”, In SpaceWire Conference (SpaceWire), International, pp. 1-4, IEEE, 2014.
P. J. Moriarty, B. L. Gallagher, C. J. Mellor and R. R. Baines, “Graphical computing in the undergraduate laboratory: Teaching and interfacing with LabVIEW”. American Journal of Physics, vol. 71, no. 10, pp. 1062-1074, 2003.
S. Kacar and I Cankaya, “Analysis of nonlinear systems using matlab and asp. net based web interface”, Journal of the Faculty of Engineering and Architecture of Gazi University, vol. 27, no.4, pp. 795-806, 2012.
E. Sonmez and S. Kacar, “Kontrol Sistemleri dersi için Matlab Builder Ne ve Asp. net tabanlı web laboratuarı tasarımı”, Sakarya Üniversitesi Fen Bilimleri Enstitüsü Dergisi, vol. 20, no. 2, pp. 155- 165, 2016.
S. Kacar, I. Cankaya and A.F. Boz, “Investigaton of computational load and parallel computing of Volterra series method for frequency analysis of nonlinear systems”, Optoelectronics and advanced materialsrapid communications, vol. 8, no. 5-6, pp. 555-566, 2014.
S. Kacar and I. “Cankaya, Design of an interface for non-linear systems analysis with Volterra series method”, In Signal Processing and Communications Applications Conference (SIU), IEEE 18th pp. 566-569, 2010.
What is Bode Diagram?dfgdgdgffgfffffffffff [Online].Available: http://www.elektrikport.com/teknik kutuphane/bode-diyagrami nedir/17345#ad-image-0 [Accessed: 04- May-2017].
Y. Li, D.M. Vilathgamuwa and P.C. Loh,”Design, analysis, and real-time testing of a controller for multibus microgrid system”, IEEE Transactions on power electronics, vol. 19, no.5, pp. 1195-1204, 2004.
A. Akgul, I. Moroz, I. Pehlivan and S. Vaidyanathan, “A new four-scroll chaotic attractor and its engineering applications” Optik-International Journal for Light and Electron Optics, vol.123, no.13, pp. 5491- 5499, 2016.
A. Akgul, S. Hussain and I. Pehlivan, "A new three-dimensional chaotic system, its dynamical analysis and electronic circuit applications" Optik-International Journal for Light and Electron Optics vol.127, no.18, pp.7062-7071, 2016.
C.Li, I. Pehlivan, J.C. Sprott, and A. Akgul, “ A novel four-wing strange attractor born in bistability” IEICE Electronics Express, vol. no.4, pp. 20141116-20141116, 2012.
A. Akgul, H. Calgan, I. Koyuncu, I. Pehlivan and A. Istanbullu, “ Chaos-based engineering applications with a 3D chaotic system without equilibrium points. Nonlinear Dynamics, vol. 84, no.2, pp. 481- 495, 2016.
A. Akgul, C. Li and I. Pehlivan. "Amplitude Control Analysis of a Four-Wing Chaotic Attractor, its Electronic Circuit Designs and Microcontroller-Based Random Number Generator." Journal of Circuits, Systems and Computers,1750190, 2017.
G. Kai, W. Zhang, Z.C. Wei, J.F. Wang and A. Akgul, “Hopf Bifurcation, Positively Invariant Set, and Physical Realization of a New Four-Dimensional Hyperchaotic Financial System”, Mathematical Problems in Engineering, 2017.
Z. Wei, I. Moroz, J.C. Sprott, A. Akgul and W. Zhang, W, “Hidden hyperchaos and electronic circuit application in a 5D selfexciting homopolar disc dynamo”, Chaos: An Interdisciplinary Journal of Nonlinear Science, vol.27, no. 3, 033101, 2017.
W. Hu, A. Akgul, C. Li, T. Zheng and P. Li, “A Switchable Chaotic Oscillator with Two Amplitude–Frequency Controllers”, Journal of Circuits, Systems and Computers, 1750158, 2017.
C. Volos, A. Akgul, V.T. Pham, I. Stouboulos and I. Kyprianidis “A simple chaotic circuit with a hyperbolic sine function and its use in a sound encryption scheme”, Nonlinear Dynamics, pp. 1-15, 2017.
M.A. Jafari, E. Mliki, A. Akgul, V.T. Pham, S.T. Kingni, X. Wang, X and S. Jafari, “Chameleon: the most hidden chaotic flow” Nonlinear Dynamics, 1-15, 2017.
A. Akgul and I. Pehlivan, "A new threedimensional chaotic system without equilibrium points, its dynamical analyses and electronic circuit application." Tech. Gaz.(Croatia) vol. 23, no. 1, pp. 209-214, 2016.
U. Cavusoglu, A. Akgul, S. Kaçar, I. Pehlı̇ van and A. Zengı̇ n, “A novel chaos‐ based encryption algorithm over TCP data packet for secure communication” Security and Communication Networks, 2016.
S. Kacar, “Analog circuit and microcontroller based RNG application of a new easy realizable 4D chaotic system”, Optik-International Journal for Light and Electron Optics vol. 127, no. 20, pp. 9551- 9561, 2016.
National Instruments. [Online]. Available: http://www.ni.com/mydaq/ NI-myDAQ, National Instruments Website. [Accessed: 04-May-2017].
The McGill Physiology Virtual Laboratory. [Online].Available:http://www.medicine.m cgill.ca/physio/vlab/biomed_signals/atodvl ab.htm. [Accessed: 04-May-2017].
Measurement Computings.gsgsdsgdsdgss. [Online].Available:http://www.mccdaq.co m/PDFs/specs/Multiplexing-and Sampling.pdf [Accessed: 04-May-2017].