Abstract
Advances in technology demands replacement of all analog blocks by its counter digital blocks. Harmonic oscillator (HO) is a mathematical implementation, facilitates generation of sinusoidal waveform, with adjustable frequency, amplitude and harmonics of fundamental frequency with different phase shifts. It is a fundamental block for many communication systems and power control applications.
This paper presents implementation of harmonic oscillator using different discretization techniques to test its stability. Most stable hybrid method is then used for generation of pulse width modulation (PWM) pulses, used in power control applications. Further using HO, an Amplitude Shift Keying (ASK) modulation system is implemented to witness its communication applications. HO simulation model is developed using Xilinx System Generator (XSG) in Matlab Simulink. Its VHDL simulation and synthesis is done to verify the functionality and identify the implementation resources required by various discretization methods. Hardware implementation is tested on Spartun-7 Field Programmable Gate Array (FPGA) platform.
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References
Mitra, J., Nayak, T.K.: An FPGA-based phase measurement system. IEEE Trans. Very Large Scale Integr. (VLSI) Syst. 26(1), 133–142 (2018)
Diao, L., Tang, J., Loh, P.C., Yin, S., Wang, L., Liu, Z.: An efficient DSP–FPGA-based implementation of hybrid PWM for electric rail traction induction motor control. IEEE Trans. Power Electron. 33(4), 3276–3288 (2018)
Jiménez, O., Barragán, L.A., Navarro, D., LucÃa, O., Artigas, J.I., Urriza, I.: FPGA-based real-time calculation of the harmonic impedance of series resonant inductive loads (2010)
Jimenez, O., Lucia, O., Barragan, L.A., Navarro, D., Artigas, J.I., Urriza, I.: FPGA-based test-bench for resonant inverter load characterization. IEEE Trans. Ind. Inform 9(3), 1645–1654 (2013)
Sreenivasappa, B.V., Udaykumar, R.Y.: Analysis and implementation of discrete time PID controllers using FPGA. Int. J. Comput. Eng. 2(1), 71–82 (2010)
Attia, H.A., Ping, H.W., Al-Mashhadany, Y.: Design and analysis for high performance synchronized inverter with PWM power control. In: Proceedings of the IEEE Conference on Clean Energy and Technology (CEAT), Langkawi TBD, Malaysia, pp. 265–270 (2013)
Rao, Y.S., Iyer, S.: DSP-FPGA implementation of a phase locked loop for digital power electronics. In: Proceedings of the IEEE Region 8 International Conference on Computational Technologies in Electrical and Electronics Engineering (SIBIRCON), Irkutsk, Russia, pp. 665–670 (2010)
Selvamuthukumaran, R., Gupta, R.: Rapid prototyping of power electronics converters for photovoltaic system application using Xilinx system generator. IET Power Electron. 7, 2269–2278 (2014)
Mondragon, M., Calderon, E., Hernandez, M., Resendiz, R.: Implementation of high resolution unipolar PWM inverter using Xilinx system generator. In: IEEE (2016)
Sawant, R.R., Chauhan, M., Yerramreddy, S.S., Rao, Y.S.: Harmonic oscillator: a classical fundamental building block for modern electric power control. In: IEEE National Power Electronics Conference (NPEC), Pune India, December 2017
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Sankhe, D.N., Sawant, R.R., Srinivas Rao, Y. (2020). Implementation of Harmonic Oscillator Using Xilinx System Generator. In: Abraham, A., Cherukuri, A., Melin, P., Gandhi, N. (eds) Intelligent Systems Design and Applications. ISDA 2018 2018. Advances in Intelligent Systems and Computing, vol 941. Springer, Cham. https://doi.org/10.1007/978-3-030-16660-1_49
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DOI: https://doi.org/10.1007/978-3-030-16660-1_49
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