Direct Digital Space Vector Modulation Technology for Current Source Inverters
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摘要:
针对电流源型逆变器(CSI)空间矢量脉宽调制(SVPWM)中开关信号无法通过数字调制信号与载波信号直接比较生成、需额外引入硬件逻辑转换电路导致可靠性下降与信号延时的问题,提出一种面向CSI的SVPWM直接数字式实现方法. 首先,分析所有开关状态形成的基本矢量空间分布,给出参考电流矢量的扇区判断方法;以前3个扇区为例,推导相邻矢量的占空比计算方法,总结所有扇区的矢量选择与占空比计算表达式,并对过调制区的占空比进行修正;然后,将单位载波周期内矢量作用顺序映射为开关动作信号,总结不同扇区下数字信号处理器(DSP)动作限定寄存器与比较值寄存器的配置方法;最后,设计控制系统环路结构,在3 kW实验平台上对所提方法进行验证,并与采用逻辑硬件转换电路的方案进行稳态性能对比. 实验结果表明:所提方法能够使DSP输出正确的开关信号波形,电流总谐波畸变率(THD)仅为0.99%,5次与7次谐波含量分别为0.100%与0.105%;而采用硬件逻辑转换电路方案的电流THD为1.46%,5次与7次谐波含量分别为0.18%与0.16%. 所提直接数字式SVPWM实现方法正确可行,由于避免了信号传输延时,具有更优越的稳态性能.
Abstract:To address the problems in the space vector pulse width modulation (SVPWM) of current source inverter (CSI) that switching signals cannot be directly generated through the comparison between digital modulation signals and carrier signals, and that the required additional hardware logic conversion circuits cause reliability degradation and signal delay, a direct digital implementation method of SVPWM for CSI was proposed. Firstly, the spatial distribution of basic vectors formed by all switching states was analyzed, and a sector determination method for the reference current vector was provided. Taking the first three sectors as an example, the calculation method for the duty cycle of adjacent vectors was derived; the expressions for vector selection and duty cycle calculation in all sectors were summarized, and the duty cycle in the over-modulation region was corrected. Then, the vector action sequence within a carrier cycle was mapped into switching action signals, and the configuration methods of action qualifier registers and compare value registers of the digital signal processor (DSP) under different sectors were summarized. Finally, the loop structure of the control system was designed, the proposed method was verified on a 3 kW experimental platform, and its steady-state performance was compared with that of the scheme adopting hardware logic conversion circuits. The experimental results indicate that the proposed method enables the DSP to output correct switching signal waveforms; the total harmonic distortion (THD) of current is only 0.99%, and the 5th and 7th harmonic contents are 0.100% and 0.105%, respectively. The current THD of the scheme adopting hardware logic conversion circuits is 1.46%, and the 5th and 7th harmonic contents are 0.18% and 0.16%, respectively. The proposed direct digital implementation method of SVPWM is correct and feasible, and it has superior steady-state performance due to the avoidance of signal transmission delay.
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表 1 n和扇区的关系
Table 1. Relationship between n and sectors
n 1 2 3 4 5 6 扇区 Ⅰ Ⅲ Ⅱ Ⅳ Ⅵ Ⅴ 表 2 各扇区所施加的有效矢量、零矢量及其占空比
Table 2. Applied active vectors, zero vectors, and their duty cycles in all sectors
扇区 第一有效矢量及其占空比 第一有效矢量及其占空比 零矢量及占空比 Ⅰ I6, d6= −Y/idc I1, d1=Z/idc I7, d7= 1− d1− d6 Ⅱ I1, d1= X/idc I2, d2=Y/idc I8, d8= 1− d1− d2 Ⅲ I2, d2= Z/idc I3, d6=−X/idc I9, d9= 1− d2− d3 Ⅳ I3, d3= Y/idc I4, d4=−Z/idc I7, d7= 1− d3− d4 Ⅴ I4, d4= −X/idc I5, d5=−Y/idc I8, d8= 1− d4− d5 Ⅵ I5, d5= −Z/idc I6, d6=X/idc I9, d9= 1− d5 − d6 表 3 所有扇区的矢量切换顺序
Table 3. Vector switching sequences in all sectors
扇区 矢量切换顺序 Ⅰ I7 → I6 → I1 → I7 → I1 → I6 → I7 Ⅱ I8 → I1 → I2 → I8 → I2 → I1 → I8 Ⅲ I9 → I2 → I3 → I9 → I3 → I2 → I9 Ⅳ I7 → I3 → I4 → I7 → I4 → I3 → I7 Ⅴ I8 → I4 → I5 → I8 → I5 → I4 → I8 Ⅵ I9 → I5 → I6 → I9 → I6 → I5 → I9 表 4 所有扇区六格开关管的动作模式
Table 4. Action modes of six switching tubes in all sectors
扇区 S1 S2 S3 S4 S5 S6 Ⅰ 导通 有效模式2 关断 零模式 关断 有效模式1 Ⅱ 有效模式1 导通 有效模式2 关断 零模式 关断 Ⅲ 关断 有效模式1 导通 有效模式1 关断 零模式 Ⅳ 零模式 关断 有效模式1 导通 有效模式2 关断 Ⅴ 关断 零模式 关断 有效模式1 导通 有效模式2 Ⅵ 有效模式2 关断 零模式 关断 有效模式1 导通 表 5 不同模式下的动作限定寄存器配置
Table 5. Configuration of action qualifier registers under different modes
模式 CBD
(11-10)CBU
(9-8)CAD
(7-6)CAU
(5-4)PRD
(3-2)ZRO
(1-0)导通 00 00 00 00 00 10 关断 00 00 00 00 00 01 零模式 01 10 10 01 00 10 有效模式 10 01 01 10 00 01 -
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