Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems
碩士 === 國立中正大學 === 電機工程研究所 === 107 === This thesis designs a finite-time polynomial fuzzy output-feedback tracking control which is applied to a 5 kW three-phase bidirectional inverter. First, the circuit architecture of a three-phase bidirectional inverter is introduced. Because the system can opera...
Main Authors: | , |
---|---|
Other Authors: | |
Format: | Others |
Language: | zh-TW |
Published: |
2019
|
Online Access: | http://ndltd.ncl.edu.tw/handle/ra5e4s |
id |
ndltd-TW-107CCU00442123 |
---|---|
record_format |
oai_dc |
spelling |
ndltd-TW-107CCU004421232019-11-02T05:27:19Z http://ndltd.ncl.edu.tw/handle/ra5e4s Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems 應用有限時間多項式模糊輸出回授追蹤控制系統之三相雙向換流器研製 CHEN, JYUN-YAN 陳俊晏 碩士 國立中正大學 電機工程研究所 107 This thesis designs a finite-time polynomial fuzzy output-feedback tracking control which is applied to a 5 kW three-phase bidirectional inverter. First, the circuit architecture of a three-phase bidirectional inverter is introduced. Because the system can operate in rectification mode and grid-connection mode, the state-equations in the two modes can be derived according to two-phase modulation (TPM), and we propose two theorems based on the finite-time polynomial fuzzy output-feedback tracking control. Theorem 1 has the Hꝏ performance which can restrain external disturbances to make the system stable in transient time, and we propose the SOS (Sum of Squares) stability equations. Theorem 2 has not only the advantages of theorem 1, but also considers the aging of components. Theorem 2 is more robust than theorem 1, so it also has the SOS stability equations to satisfy theorem 2 of stability conditions. Theorems 1 and 2 get the gains of the finite-time polynomial fuzzy output-feedback tracking control using Matlab SOSTOOLS. Finally, the gains are applied to three-phase bidirectional inverter, and operated in rectification mode and grid-connection mode. Experiments contain the constant power, such as 1kW, 3kW, 5kW, robustness of simulation and measurements. The results demonstrate that the performance of the Three-Phase bidirectional inverter using finite-time polynomial fuzzy output-feedback tracking controller is better than that of the division-summation controller for the three-phase bidirectional Inverter. YU, GWO-RUEY 余國瑞 2019 學位論文 ; thesis 154 zh-TW |
collection |
NDLTD |
language |
zh-TW |
format |
Others
|
sources |
NDLTD |
description |
碩士 === 國立中正大學 === 電機工程研究所 === 107 === This thesis designs a finite-time polynomial fuzzy output-feedback tracking control which is applied to a 5 kW three-phase bidirectional inverter. First, the circuit architecture of a three-phase bidirectional inverter is introduced. Because the system can operate in rectification mode and grid-connection mode, the state-equations in the two modes can be derived according to two-phase modulation (TPM), and we propose two theorems based on the finite-time polynomial fuzzy output-feedback tracking control. Theorem 1 has the Hꝏ performance which can restrain external disturbances to make the system stable in transient time, and we propose the SOS (Sum of Squares) stability equations. Theorem 2 has not only the advantages of theorem 1, but also considers the aging of components. Theorem 2 is more robust than theorem 1, so it also has the SOS stability equations to satisfy theorem 2 of stability conditions. Theorems 1 and 2 get the gains of the finite-time polynomial fuzzy output-feedback tracking control using Matlab SOSTOOLS. Finally, the gains are applied to three-phase bidirectional inverter, and operated in rectification mode and grid-connection mode. Experiments contain the constant power, such as 1kW, 3kW, 5kW, robustness of simulation and measurements. The results demonstrate that the performance of the Three-Phase bidirectional inverter using finite-time polynomial fuzzy output-feedback tracking controller is better than that of the division-summation controller for the three-phase bidirectional Inverter.
|
author2 |
YU, GWO-RUEY |
author_facet |
YU, GWO-RUEY CHEN, JYUN-YAN 陳俊晏 |
author |
CHEN, JYUN-YAN 陳俊晏 |
spellingShingle |
CHEN, JYUN-YAN 陳俊晏 Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
author_sort |
CHEN, JYUN-YAN |
title |
Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
title_short |
Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
title_full |
Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
title_fullStr |
Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
title_full_unstemmed |
Design and Implementation of a Three-Phase Bidirectional Inverter Using Finite-Time Polynomial Fuzzy Output-Feedback Tracking Control Systems |
title_sort |
design and implementation of a three-phase bidirectional inverter using finite-time polynomial fuzzy output-feedback tracking control systems |
publishDate |
2019 |
url |
http://ndltd.ncl.edu.tw/handle/ra5e4s |
work_keys_str_mv |
AT chenjyunyan designandimplementationofathreephasebidirectionalinverterusingfinitetimepolynomialfuzzyoutputfeedbacktrackingcontrolsystems AT chénjùnyàn designandimplementationofathreephasebidirectionalinverterusingfinitetimepolynomialfuzzyoutputfeedbacktrackingcontrolsystems AT chenjyunyan yīngyòngyǒuxiànshíjiānduōxiàngshìmóhúshūchūhuíshòuzhuīzōngkòngzhìxìtǒngzhīsānxiāngshuāngxiànghuànliúqìyánzhì AT chénjùnyàn yīngyòngyǒuxiànshíjiānduōxiàngshìmóhúshūchūhuíshòuzhuīzōngkòngzhìxìtǒngzhīsānxiāngshuāngxiànghuànliúqìyánzhì |
_version_ |
1719285387805851648 |