电工技术学报
電工技術學報
전공기술학보
TRANSACTIONS OF CHINA ELECTROTECHNICAL SOCIETY
2009年
11期
178-183
,共6页
VLSI%基波计量%谐波计量%FFT%小波包分解
VLSI%基波計量%諧波計量%FFT%小波包分解
VLSI%기파계량%해파계량%FFT%소파포분해
VLSI%fundamental energy metering%harmonic energy metering%FFT%wavelet packet decomposition
提出了一种适用于超大规模集成电路(以下简称VLSI)实现的谐波电能计量算法.该算法以电网中能量的分布为出发点,对基波和谐波分量采用了不同的数字滤波处理,并且通过一个前馈控制系统实现了滤波器中心频率对电网频率的跟随,达到了同步采样的效果,解决了在电网频率不准确时快速傅里叶变换(以下简称FFT)频谱泄漏造成的计量误差问题.与用小波包分解实现谐波电能计量的算法相比,该算法需要的滤波器更少,更节省硬件面积,因而更适合VLSI的设计实现.网表级仿真结果表明电网频率在±5%范围内波动时基波有功功率计量误差小于0.1%,各次谐波有功功率计量误差小于1%,完全能满足谐波电能计量的商业要求.集成了该算法的谐波电能计量芯片已投片生产.
提齣瞭一種適用于超大規模集成電路(以下簡稱VLSI)實現的諧波電能計量算法.該算法以電網中能量的分佈為齣髮點,對基波和諧波分量採用瞭不同的數字濾波處理,併且通過一箇前饋控製繫統實現瞭濾波器中心頻率對電網頻率的跟隨,達到瞭同步採樣的效果,解決瞭在電網頻率不準確時快速傅裏葉變換(以下簡稱FFT)頻譜洩漏造成的計量誤差問題.與用小波包分解實現諧波電能計量的算法相比,該算法需要的濾波器更少,更節省硬件麵積,因而更適閤VLSI的設計實現.網錶級倣真結果錶明電網頻率在±5%範圍內波動時基波有功功率計量誤差小于0.1%,各次諧波有功功率計量誤差小于1%,完全能滿足諧波電能計量的商業要求.集成瞭該算法的諧波電能計量芯片已投片生產.
제출료일충괄용우초대규모집성전로(이하간칭VLSI)실현적해파전능계량산법.해산법이전망중능량적분포위출발점,대기파화해파분량채용료불동적수자려파처리,병차통과일개전궤공제계통실현료려파기중심빈솔대전망빈솔적근수,체도료동보채양적효과,해결료재전망빈솔불준학시쾌속부리협변환(이하간칭FFT)빈보설루조성적계량오차문제.여용소파포분해실현해파전능계량적산법상비,해산법수요적려파기경소,경절성경건면적,인이경괄합VLSI적설계실현.망표급방진결과표명전망빈솔재±5%범위내파동시기파유공공솔계량오차소우0.1%,각차해파유공공솔계량오차소우1%,완전능만족해파전능계량적상업요구.집성료해산법적해파전능계량심편이투편생산.
In this paper a harmonic energy metering algorithm suitable for very large scale integrated circuit (VLSI) implementation is proposed. By taking into consideration of the distribution of the energy, filters with different orders to process the fundamental and harmonics are used. All the digital filters can track the change of the fundamental frequency by a feed forward system. It solves frequency leakage (thus metering error) problem associated with frequency variations that fast Fourier transform (FFT) has. Comparing to the wavelet packet decomposition, the proposed algorithm is more area efficient because of fewer filters are needed. Simulations and hardware verifications show that a metering accuracy of 0.1% for the fundamental and of 1% for the harmonics even with the frequency varying by ±5% can be achieved. The algorithm is implemented in a chip that is currently in prototyping.
