The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Kertas kerja ini menerangkan pendekatan simulasi yang cekap bagi sistem penukar kuasa DC-DC frekuensi tinggi siri-selari dikawal DSP. Pendekatan simulasi litar penukaran kuasa yang dicadangkan adalah berdasarkan persamaan litar, dimodelkan dengan menggantikan litar perintang beralih masa yang berbeza-beza menggantikan semua blok pensuisan semikonduktor kuasa yang boleh dikawal dan tidak terkawal bagi litar penukar kuasa. Algoritma algebra menukarkan matriks persamaan litar kepada matriks persamaan vektor keadaan. Penyelesaian persamaan keadaan adalah dengan kaedah penyepaduan berangka Runge Kutta tertib ke-3. Keputusan simulasi digambarkan dan dibincangkan bersama dengan keputusan eksperimen.
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Salinan
Ulhaqsyed MOBIN, Eiji HIRAKI, Hiroshi TAKANO, Mutsuo NAKAOKA, "Simulation of Series-Parallel Resonant DC-DC Converter System with DSP-Based Digital Control Scheme" in IEICE TRANSACTIONS on Fundamentals,
vol. E83-A, no. 7, pp. 1458-1466, July 2000, doi: .
Abstract: This paper describes an efficient simulation approach of a DSP controlled series-parallel resonant high frequency DC-DC power converter system. Proposed power conversion circuit simulation approach is based on a circuit equation, modeled by substituting time-varying switched resistor circuit in place of all the controllable and uncontrollable power semiconductor switching blocks of power converter circuits. An algebraic algorithm transforms the matrices of the circuit equation into the matrices of the state vector equation. Solution of state equation is by 3rd order Runge Kutta numerical integration method. Simulation results are illustrated and discussed together with experimental results.
URL: https://global.ieice.org/en_transactions/fundamentals/10.1587/e83-a_7_1458/_p
Salinan
@ARTICLE{e83-a_7_1458,
author={Ulhaqsyed MOBIN, Eiji HIRAKI, Hiroshi TAKANO, Mutsuo NAKAOKA, },
journal={IEICE TRANSACTIONS on Fundamentals},
title={Simulation of Series-Parallel Resonant DC-DC Converter System with DSP-Based Digital Control Scheme},
year={2000},
volume={E83-A},
number={7},
pages={1458-1466},
abstract={This paper describes an efficient simulation approach of a DSP controlled series-parallel resonant high frequency DC-DC power converter system. Proposed power conversion circuit simulation approach is based on a circuit equation, modeled by substituting time-varying switched resistor circuit in place of all the controllable and uncontrollable power semiconductor switching blocks of power converter circuits. An algebraic algorithm transforms the matrices of the circuit equation into the matrices of the state vector equation. Solution of state equation is by 3rd order Runge Kutta numerical integration method. Simulation results are illustrated and discussed together with experimental results.},
keywords={},
doi={},
ISSN={},
month={July},}
Salinan
TY - JOUR
TI - Simulation of Series-Parallel Resonant DC-DC Converter System with DSP-Based Digital Control Scheme
T2 - IEICE TRANSACTIONS on Fundamentals
SP - 1458
EP - 1466
AU - Ulhaqsyed MOBIN
AU - Eiji HIRAKI
AU - Hiroshi TAKANO
AU - Mutsuo NAKAOKA
PY - 2000
DO -
JO - IEICE TRANSACTIONS on Fundamentals
SN -
VL - E83-A
IS - 7
JA - IEICE TRANSACTIONS on Fundamentals
Y1 - July 2000
AB - This paper describes an efficient simulation approach of a DSP controlled series-parallel resonant high frequency DC-DC power converter system. Proposed power conversion circuit simulation approach is based on a circuit equation, modeled by substituting time-varying switched resistor circuit in place of all the controllable and uncontrollable power semiconductor switching blocks of power converter circuits. An algebraic algorithm transforms the matrices of the circuit equation into the matrices of the state vector equation. Solution of state equation is by 3rd order Runge Kutta numerical integration method. Simulation results are illustrated and discussed together with experimental results.
ER -