基于SVPWM两电平和三电平逆变器的感应电机直接转矩控制仿真及分析资料

三电平SVPWM算法研究及仿真三电平SVPWM（Space Vector Pulse Width Modulation）是一种常见的电力电子转换技术，用于控制三相逆变器或变频器输出的电压波形。

本文将着重研究三电平SVPWM算法，并进行仿真评估。

首先，我们来介绍三电平SVPWM算法的原理。

它基于矢量控制（Vector Control）理论，通过在三相逆变器的输出电压空间矢量图上选择合适的电压矢量，以实现所需的输出电压。

1.获取输入信号：通过采样电网电压和电网电流，获取输入信号的相位和幅值。

2.电网电压矢量合成：将电网电压坐标变换到α-β坐标系，然后将三相电压矢量转换为α-β坐标系下的矢量。

3. 电机电流转换：通过坐标变换将α-β坐标系下的矢量转换为dq 坐标系下的矢量，其中d轴是电机电流的直流分量，q轴是电机电流的交流分量。

4. 电机电流控制：通过PI控制器对dq坐标系下的电机电流进行控制，以实现所需的电机电流。

5.电网电压生成：通过逆变器控制器生成电网输出电压的矢量。

6.SVM模块选择：根据电网电压矢量在α-β坐标系下的位置，选择合适的SVM模块进行控制。

7.输出PWM波形：根据选择的SVM模块，将PWM波形通过逆变器输出到电网上。

接下来，我们将进行三电平SVPWM的仿真评估。

仿真环境可以使用Matlab/Simulink或者PSCAD等软件。

首先，我们需要建立三电平逆变器的模型，包括电网电压、逆变器、电机等组成部分。

然后，编写三电平SVPWM算法的仿真程序。

在仿真程序中，通过输入电网电压和电机负载等参数，我们可以模拟电网电压和电机电流的变化情况。

然后，根据三电平SVPWM算法，计算逆变器输出的PWM波形，并将其作为输入给逆变器，从而实现对电网电压和电机电流的控制。

最后，通过仿真结果分析三电平SVPWM算法的性能，包括输出波形的失真程度、功率因数、谐波含量等。

并与传统的两电平SVPWM算法进行对比，评估其性能优势。

基于svpwm的三电平逆变器控制策略研究
基于svpwm（Space Vector Pulse Width Modulation）的三电平
逆变器控制策略研究是一个有趣又有兴趣的话题，尤其是在有需要开
发出新一代控制策略以满足市场不断提高要求时，受到越来越多的关注。

SVPWM是一种多相双向逆变器控制的有效方式，它能够在负载测动
或静态状态时提供有效的响应，以调节输出电压并减少电磁悬浮。

然而，当输出功率较大时，可能会出现火花现象，增加了损耗，影响了
系统效率。

因此，采用三电平逆变器技术减少了火花现象，可以改善
输出功率对分部多脉冲控制的响应。

SVPWM技术与三电平逆变器的结合构成了一种适用于三电平逆变器
的新一代控制策略，可以有效改善该系统的性能。

在研究中，已经实
现了针对三电平逆变器的改进的SVPWM策略，调节了单相的输出电压，将负载拖动电流降低至最低，并且可以对输入电压的变化作出及时响应，从而提高系统效率。

此外，由于信号电平与控制精度之间的关系，本文还介绍了如何
可以使用基于三电平逆变器的SVPWM策略来提高信号电平和控制精度
之间的性能。

该方案利用不同的控制方法来控制三相的逆变器的输出，通过理论和仿真结果，得出了显著的改善效果。

总而言之，基于svpwm的三相逆变器控制策略研究可能会取得长
足的进展，以满足市场的新一代控制需求。

在相关的研究工作中已经
取得了良好的成果，并且有望在未来继续发展，使得三电平逆变器能
够发挥更好的控制性能。

1 SVPWM 的基本原理分析SVPWM 控制的基本思想是将电机与逆变器看作一个整体，通过控制逆变器开关的导通和关断状态的顺序来控制三相异步电机运行状态，使其在内部产生一个恒定幅值、逼近圆形的旋转磁场。

当三相异步电机的定子端输入一个三相对称的电压时，会产生一个三相对称的电流，并且在电机内部产生一个旋转磁场。

根据三相异步电机的物理特性得出：iR dtd u +=ψ(1) 式中 u —电机定子端电压；ψ—电机内部磁链； i —电机的定子电流； R —电机的定子电阻。

在三相电源的电压频率较高时，磁链的变化率很快，故上式近似为：dtd u ψ≈(2) 对等式左右同时两边积分得到：⎰=udt ψ (3) 若考虑一段很小的时间t ∆内的变化，上式可以改写为：t u ∆+=0ψψ (4) 其中ψ是电机内部磁链的初始值，u 为电压空间矢量。

通过上式可以看出一个空间电压矢量表示了电机内部磁链的增量。

下图是两电平牵引逆变器的主电路图：MT1T3T5T4T6T2UdUd图1 两电平牵引逆变器主电路图从图中可以看出其拓扑结构是由六个开关管T1，T2，T3，T4，T5，T6构成的三相全桥。

由两电平电压型逆变器的控制方法可知，位于同一桥臂上的开关函数为互补关系，在这里定义开关量S A S B S C 为各桥臂开关的通断状态。

当S i =1时，上桥臂导通，下桥臂关断；当S i =0时，下桥臂导通，上桥臂关断，其中i=A 、B 、C ，依次代表从左到右三个桥臂。

这样，由S A S B S C 可组成000、001、010、011、100、101、110、111这8种开关模式。

在不同的开关模式下，逆变器会根据指令脉冲产生不同的输出电压。

因为电机定子绕组在空间上是三相对称的，由空间电压矢量的定义可知，三相逆变器所输出的相电压有八个基本空间电压矢量，它们分别定义为0U r、1U r、2U r、3U r、4U r 、5U r 、6U r 、7U r ，其中0U r 和7U r为空间电压零矢量，即开关模式位于000和111状态，逆变器输出相的电压为0。

基于SVPWM算法的数字控制三电平逆变器的研究【摘要】三电平逆变器属于电压型逆变器，它是多电平逆变器中比较有实用意义的一种电路，本文通过深入论述三电平逆变器SVPWM的基本原理及算法特点，总结了SVPWM的应用特点，为其能在工程领域应用提供一定的工程参考价值。

【关键词】逆变器；SVPWM；数字控制1.引言与传统的两电平逆变器相比，三电平逆变器自从上世纪80年代提出以后，逐步成为目前在系统设计和工程应用研究的热点之一。

三电平逆变器属于电压型逆变器，它是多电平逆变器中比较有实用意义的一种电路。

三电平逆变器具有好的输出电压、电流波形；器件具有两倍的正向阻断电压能力；能降低开关频率，从而使系统损耗减小让低压开关器件应用于高压逆变器中，然而由于其逆变状态比传统的两电平逆变器多若干倍，以及中点电压的不均衡问题给三电平逆变器带来了很多控制方面的复杂性。

多电平逆变器的思想提出至今，出现了许多控制方法，但归纳起来主要有三种：正弦载波PWM（SPWM）、选择性消谐波PWM （HEPWM）、空间矢量PWM（SVPWM）。

2.三电平逆变器SVPWM方法的原理空间矢量PWM（SVPWM）是国外学者在交流电机调速中提出的，是由磁通轨迹控制思想发展而来的，其物理概念清晰，能明显减少逆变器输出电流的谐波成分，以及输出电压利用率高、中点电位易于控制平衡和功率管的开关次数较少，更容易且适合数字化实现。

SVPWM一经问世，就成为三相逆变器中最重要的调制方式。

它用空间矢量的概念来计算开关作用时间，是一种简化的数字PWM 调制。

SVPWM又称磁链追踪型PWM法，它是从电动机的角度出发，其着眼点是如何使电动机获得圆磁场。

具体地说，它是以三相对称正弦波电压供电下三相对称电动机定子理想磁链圆为基准，由三相逆变器不同开关模式下所形成的实际磁链矢量来追踪基准磁链圆，在追踪的过程中，逆变器的开关模式作适当的切换，从而形成PWM波。

2.1 空间电压矢量的定义交流电机绕组的电压、电流、磁链等物理量都是随时间变化的，分析时常用空间矢量来表示。

411/2008收稿日期：2007-10-05作者简介：胡慧慧(1980-)，女，硕士研究生，主要研究方向为电力电子与电力传动技术；马文忠(1968-)，男，副教授，博士，主要研究方向为电力电子变换与电机驱动技术。

基于SVPWM 的三电平逆变器仿真研究胡慧慧，马文忠，董磊（中国石油大学（华东）信息与控制工程学院，山东东营257061）摘 要：分析三电平逆变器的结构及工作原理，研究将电压空间矢量控制技术（SVPWM ）应用在三电平逆变器上的方法，并通过仿真，验证算法的可行性。

关键词：三电平；矢量控制；逆变器；仿真中图分类号：TM464文献标识码：A文章编号：1671-8410(2008)01-0041-04Simulation and Research of Three-level Inverter with SVPWMHU Hui-hui, MA Wen-zhong, DONG Lei(College of Information and Control Engineering, China University of Petroleum, Dongying, Shandong 257061, China)Abstract: This paper analyzes the structure and operation principle of three-level inverter and researches space vector PWM(SVPWM)control technique. The reliability of the system was estimated by simulation of the mathematical model.Key words:three-level; space vector control; inverter; simulation0引言与传统的逆变器相比，目前以二极管中点箝位型结构为代表的三电平逆变器更适合用于控制高电压、大功率电机，且具备输出电压波形谐波含量低，跳变（d u /d t ）引起的电磁干扰小等优点。

三电平逆变器的SVPWM控制与MATLAB仿真研究三电平逆变器是一种常用的电力电子设备，具有输出波形质量高、效率高、功率密度大等优点。

SVPWM是一种常用于三电平逆变器的控制算法，可以实现对输出电压的精确调节。

本文将对SVPWM控制算法进行研究，并使用MATLAB进行仿真验证。

首先，介绍三电平逆变器的基本原理。

三电平逆变器由两个半桥逆变器和一个中间电压平衡电路组成。

其工作原理是通过控制两个半桥逆变器的开关状态，将输入直流电压转换为输出交流电压。

为了实现高质量的输出波形，需要对逆变器的开关状态进行精确控制。

SVPWM是一种常用的控制算法，通过控制逆变器的开关状态来实现对输出电压的精确控制。

SVPWM控制算法的基本原理是将三相交流信号转换为空间电压矢量，然后通过控制逆变器的开关状态来实现对输出电压的调节。

该算法采用三角波进行调制，根据三角波和参考信号之间的相位差确定逆变器的开关状态。

具体来说，根据参考信号和三角波的相位关系，可以将逆变器的开关状态分为六个不同的区间。

在每个区间中，逆变器的开关状态发生变化，从而实现对输出电压的调节。

为了验证SVPWM控制算法的性能，我们使用MATLAB进行仿真。

首先，我们需要建立逆变器的数学模型。

逆变器的数学模型可以通过电路方程和开关动态方程来建立。

然后，我们可以编写MATLAB代码来实现SVPWM控制算法。

在代码中，需要定义参考信号和三角波的频率和幅值，并根据相位差确定逆变器的开关状态。

最后，我们可以通过MATLAB的仿真工具来模拟逆变器的工作过程，并观察输出电压的波形和频谱。

通过对SVPWM控制算法的研究和MATLAB的仿真验证，可以得出以下结论。

首先，SVPWM控制算法可以实现对三电平逆变器输出电压的精确控制。

其次，通过调整参考信号和三角波的频率和幅值，可以实现不同频率和幅值的输出电压。

最后，MATLAB的仿真工具可以有效地验证SVPWM控制算法的性能，并对三电平逆变器的工作过程进行可视化分析。

两电平SVPWM 原理及仿真分析陈坚，李铭舜，贾亦敏，刘海信，刘东洋，杨睿中国矿业大学 信息与电气工程学院 电气信息类11-7班摘要在工业生产与日常生活中，SVPWM 技术的应用越来越普遍，越来越成熟。

在异步电机调速方面相比于调压调速，传统SPWM 调速等调速方法，性能更加优异。

本文旨在总结介绍SVPWM 基本原理，解释相关信息。

通过理论分析与仿真实验阐述了SVPWM 的一种简单实现方式，论证了相关原理的正确性，得出了一种可行的SVPWM 实现方式。

关键词： SVPWM 圆形磁场 调制度SVPWM 原理简而言之：把逆变器和交流电动机视为一体，以圆形磁场为目标来控制逆变器工作。

三相对称正弦波电压供电时交流电机的理想磁通为圆形，此为基准磁通。

SVPWM 利用逆变器不同的开关模式产生实际磁通，使其逼近基准磁通，由比较结果决定逆变器开关状态，形成PWM 波形设直流母线侧电压为U dc ，逆变器输出的三相相电压为U A 、U B 、U C ，其分别加在空间上互差120°的三相平面静止坐标系上，可以定义三个电压空间矢量 U A (t)、U B (t)、U C (t)，它们的方向始终在各相的轴线上，而大小则随时间按正弦规律做变化，时间相位互差120°。

假设Um 为相电压有效值，f 为电源频率，则有：⎪⎩⎪⎨⎧+=-==)3/2cos()()3/2cos()()cos()(πθπθθm Cm B m A U t U U t U U t U 其中，ft πθ2=，则三相电压空间矢量相加的合成空间矢量 U(t)就可以表示为：θππj m j C j B A e U e t U e t U t U t U 23)()()()(3/43/2=++=可见 U(t)是一个旋转的空间矢量，它的幅值为相电压峰值的1.5倍，Um 为相电压峰值，且以角频率ω=2πf 按逆时针方向匀速旋转的空间矢量，而空间矢量 U(t)在三相坐标轴（a ，b ，c ）上的投影就是对称的三相正弦量。

两电平SVPWM仿真报告————————————————————————————————作者：————————————————————————————————日期：1 SVPWM 的基本原理分析SVPWM 控制的基本思想是将电机与逆变器看作一个整体，通过控制逆变器开关的导通和关断状态的顺序来控制三相异步电机运行状态，使其在内部产生一个恒定幅值、逼近圆形的旋转磁场。

当三相异步电机的定子端输入一个三相对称的电压时，会产生一个三相对称的电流，并且在电机内部产生一个旋转磁场。

根据三相异步电机的物理特性得出：iR dtd u +=ψ(1)式中 u —电机定子端电压；ψ—电机内部磁链； i —电机的定子电流； R —电机的定子电阻。

在三相电源的电压频率较高时，磁链的变化率很快，故上式近似为：dtd u ψ≈(2)对等式左右同时两边积分得到：⎰=udt ψ (3) 若考虑一段很小的时间t ∆内的变化，上式可以改写为：t u ∆+=0ψψ (4) 其中ψ是电机内部磁链的初始值，u 为电压空间矢量。

通过上式可以看出一个空间电压矢量表示了电机内部磁链的增量。

下图是两电平牵引逆变器的主电路图：MT1T3T5T4T6T2UdUd图1 两电平牵引逆变器主电路图从图中可以看出其拓扑结构是由六个开关管T1，T2，T3，T4，T5，T6构成的三相全桥。

由两电平电压型逆变器的控制方法可知，位于同一桥臂上的开关函数为互补关系，在这里定义开关量S A S B S C 为各桥臂开关的通断状态。

当S i =1时，上桥臂导通，下桥臂关断；当S i =0时，下桥臂导通，上桥臂关断，其中i=A 、B 、C ，依次代表从左到右三个桥臂。

这样，由S A S B S C 可组成000、001、010、011、100、101、110、111这8种开关模式。

在不同的开关模式下，逆变器会根据指令脉冲产生不同的输出电压。

因为电机定子绕组在空间上是三相对称的，由空间电压矢量的定义可知，三相逆变器所输出的相电压有八个基本空间电压矢量，它们分别定义为0U 、1U 、2U 、3U 、4U 、5U 、6U 、7U ，其中0U 和7U 为空间电压零矢量，即开关模式位于000和111状态，逆变器输出相的电压为0。

Review of High-Performance Three-Phase Power-Factor Correction Circuits Hengchun Mao,Member,IEEE,Fred C.Y.Lee,Fellow,IEEE,Dushan Boroyevich,Member,IEEE,and Silva Hiti,Member,IEEEAbstract—This paper reviews recent progress in topology, control,and design aspects in three-phase power-factor correction (PFC)techniques.Different switching rectifier topologies are presented for various applications.Representative soft-switching schemes,including zero-voltage and zero-current switched pulsewidth modulated(PWM)techniques,are investigated. Merits and limitations of these techniques are discussed and illustrated by experimental results obtained on prototype converters.Control and inputfilter design issues are also discussed.Index Terms—Power factor correction,soft switching,three-phase converters.I.I NTRODUCTIONM OTIV ATED by the forthcoming stringent power-quality regulations,power-factor correction(PFC)has been an active research topic in power electronics.The single-phase PFC is already a common practice,and the industrial application of three-phase PFC techniques has also emerged. Up to this point,the research of three-phase converters has been heavily focused on inverter applications.Although most techniques developed in the inverter area can be used in PFC applications,a PFC circuit has its unique characteristics and,therefore,deserves some special treatment.The primary differences between PFC and inverter applications include the following aspects.•Special attention has to be paid to the quality of input current to reduce the pollution to the utility,usually measured by the input current total harmonic distortion (THD).Although there are no specific limits on the input current distortion of general high-power three-phase converters at present,it is a common practice to limit the input current THD of three-phase PFC converters at least below10%.This makes control design more critical than in inverters.Manuscript received November5,1996;revised March3,1997.H.Mao was with the Virginia Power Electronics Center,Bradley De-partment of Electrical Engineering,Virginia Polytechnic Institute and State University,Blacksburg,V A24061-0111USA.He is now with Bell Labora-tories,Lucent Technologies,Mesquite,TX75149USA.F.C.Y.Lee and D.Boroyevich are with the Virginia Power Electronics Center,Bradley Department of Electrical Engineering,Virginia Polytechnic Institute and State University,Blacksburg,V A24061-0111USA.S.Hiti was with the Virginia Power Electronics Center,Bradley Department of Electrical Engineering,Virginia Polytechnic Institute and State University, Blacksburg,V A24061-0111USA.She is now with Delco Electronics—Power Control Systems,Torrance,CA90509-2923USA.Publisher Item Identifier S0278-0046(97)05260-X.•The electromagnetic interference(EMI)emissions are a great concern in PFC applications.The high-speed switch-ing action of a PFC converter generates both differential-mode and common-mode noises at the input of the PFC converter at high frequencies.Passivefiltering is widely used to reduce the EMI emissions into the utility.•High switching frequencies are desirable to reduce the size and weight of reactive components(especially in-ductors)and to improve current-control performance.While a20-kHz switching frequency is deemed sufficient in most inverter applications,a PFC converter prefersa much higher switching frequency,e.g.,50–100kHzin tens of kilowatt power level.The effect of soft-switching techniques is,therefore,very prominent in PFC applications.•The input currents are generally in phase with the input voltages,and bidirectional powerflow is usually not required in PFC circuits.These facts provide someflex-ibility to develop soft-switching techniques and control schemes specific to PFC converters.Soft-switching techniques shape the switch voltage or cur-rent waveforms in the switching transients to create a favor-able switching condition.Therefore,the switching losses of switchesandvarious quasi-resonant dc-link or parallel dc-link converters [12]–[14]share the same basic concept with ZVT techniques. Many three-phase topologies also explicitly utilize the ZVT or ZCT principle[1],[5],[8],[15],[17]–[19].The RC, QRC,and MRC achieve soft-switching function by creating piecewise-sinusoidal voltage/current waveforms in a resonant fashion and suffer from high circulating energy,high switch voltage/current rating,variable switching frequencies,and complex control requirements.The QSW tries to reduce the circulating energy of QRC’s by blocking part of the resonance with additional switches,but still has the shortcoming of high switch voltage stress.On the other hand,the soft-transition techniques modify the converter operation only in a short period during switching transitions and allow the converter to be controlled with constant-frequency PWM.A soft-transition converter has similar voltage/current stresses and circulating energy,as in its PWM counterpart.Since three-phase PFC converters usually deal with relatively high power,it is important that the soft-switching function does not significantly increase the switch voltage/current stresses and converter control complexity.For most PFC applications, soft transition techniques are more efficient than other soft-switching techniques.There are two basic approaches to controlling power in a power-conditioning system.Thefirst approach is the single-stage conversion,which integrates input current control,load voltage regulation,and,possibly,input/output isolation into one power stage.The second approach is the traditional two-stage scheme,where the input stage(i.e.,a PFC converter) controls the input currents and provides a coarsely regulated output voltage,while the load regulation is performed by second-stage power conversion.The single-stage approach eliminates the intermediate dc bus in the two-stage approach and could have a simpler power stage structure,which makes it seemingly attractive for certain applications.However,with the single-stage approach,the control complexity is increased, and all power semiconductor devices are subject to the input voltage change and disturbance and may have higher voltage and current stress than with the two-stage approach.There-fore,the single-stage approach does not necessarily achieve performance and cost advantages over the two-stage approach. This paper provides a comprehensive overview of three-phase PFC techniques,with emphasis on soft-switching as-pects.Section II covers several simple topologies with single switch or consisting of single-phase converters.Section III presents the soft-switching techniques for three-phase contin-uous conduction mode(CCM)boost rectifiers,and Section IV includes a brief description of soft-switching three-phase buck rectifiers.Section V deals with the control aspect of three-phase PFC converters.Conclusions and predictions of future development trends are presented in Section VI.II.S IMPLE T HREE-P HASE PFC C IRCUITSTo reduce the converter cost and avoid the complexity of full-bridge three-phase converters,several simple topologies have been used for the low power end of three-phase PFC applications.A.Three-Phase Rectifiers Consisting of ThreeSingle-Phase PFC ConvertersA simple way to implement a PFC converter in a three-phase application is to combine three single-phase boost rectifiers at the input side,one for each phase and each followed by a dc–dc converter.This configuration is simplified in[1]by directly coupling the outputs of the three single-phase PFC converters,as is shown in Fig.1.This simplification could result in significant cost reduction,since only one dc–dc converter is required.The outputcapacitorusually does notequal,is used to eliminate the diode reverse recovery and switch turn-on loss.The auxiliaryswitchcan also bring the switch voltage to zero and creates the zero-voltage turn-on condition.Due to the much reduced switching loss,converter efficiency can be improved with the ZVT operation.Also,certain redundancy is inherent in this arrangement,since the three phase converters can operate independently.However,there are many more power semiconductor devices in the main power path and more power loss in this configuration than in a real three-phase PFC converter,as will be discussed in the later sections.As a result, the efficiency is lower than in many other topologies.The measured efficiency on a100-kHz prototype is90%with1.7-kW output power,90-V rms input and380-V output voltages [1].Due to its relatively low efficiency and high input current distortion,this topology is not suitable for high-power high-performance applications.B.Three-Phase Single-Switch DCM RectifiersHigh power factor can be easily obtained when boost,buck-boost,flyback,Sepic,Cuk,and zeta converters are operated in discontinuous current mode(DCM)with constant duty cycles. There are several such three-phase PFC topologies developed which require only one active switch[2]–[5].The single-MAO et al.:REVIEW OF POWER-FACTOR CORRECTION CIRCUITS439Fig.1.Three-phase ZVT PFC rectifier consisting of single-phase converters.switch boost rectifier,shown in Fig.2,is the most populartopology in this category,due to its simplicity and relativelygood ually,the converter is controlled by aslow voltage loop,which keeps the duty cycle of the mainswitch practically constant over a line cycle,so each inputcurrent has an envelope proportional to its corresponding phasevoltage.The duty cycle determines the magnitude of the inputcurrents and,thus,the input power,which provides a meansto regulate the output voltage.Although the input currentpeak is proportional to the sinusoidal input voltage in eachswitching cycle,the average input current is distorted by theinductor current during the discharging stage,the duration ofwhich is determined by the difference between the output andinput voltages.To reduce the distortion,the output voltagehas to be sufficiently higher than the input voltage peak tolimit the duration of the discharging stage.Fig.2(b)showsthe dependence of input current THD on the ratio of outputvoltage to input line voltage amplitude(voltage gain440IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS,VOL.44,NO.4,AUGUST1997Fig.3.Three-phase full-bridge boost rectifier.input current now is only the inductor current in the charging stage,nearly perfect sinusoidal current can be obtained.The disadvantage of thisflyback converter is the high voltage stress of the switch and the complex clamp circuit necessary to absorb the leakage energy of theflyback transformers.M B OOST R ECTIFIERSFor high-power applications,especially when high perfor-mance is required,the CCM boost rectifier is usually used, due to its high efficiency,good current quality,and low EMI emissions.The basic topology of three-phase CCM boost rectifiers,which is identical to a voltage-source inverter,is shown in Fig.3.The converter is controlled by an output voltage loop for output regulation and inner current loops which shape the input currents according to their sinusoidal references.Due to the existence of multiloop control,excellent control characteristics can be achieved if output voltage is higher than the input line voltage amplitude.Differential mode EMI emissions,inductor current rating,and switch current rating are also kept low,due to the continuous input currents. Due to the severe diode reverse-recovery problem,the major part of the switching loss in a CCM boost converter is usually the turn-on loss.Several zero-voltage switching techniques have been proposed to reduce or eliminate the switch turn-on loss,while alleviating the turn-off loss indirectly by the use of snubber capacitors.Great simplicity can be achieved if the soft-switching mechanism is applied to the dc link instead of applying to the ac side,as in the resonant dc link(RDCL)[9], [10]and other dc-link commutated converters[11]–[15].In the actively clamped RDCL shown in Fig.4(a),the dc link always resonates at a high frequency,thus enabling bridge switches to be turned on/off with zero-voltage conditions.Although device switching losses are significantly reduced,the conduction loss in the auxiliary circuit is quite high.The switches in RDCL converters also suffer from high voltage stress(usually about 1.5times the output voltage)and high circulating energy.Discrete pulse modulation(DPM)is usually used in RDCL converters to synthesize the three-phase voltages.DPM, although complex,requires the dc-link resonating frequency to be8–10times higher than the switching frequency of a PWM converter for similar current spectral performance[34] and limits the converter performance.It is desirable to be able to keep the widely used PWM control in soft-switching converters.Several topologies in[12]–[15]incorporate soft switching in PWM converters through the use of a dc-rail switch to separate the main bridge from the dc-link voltage source and a parallel resonant branch to resonate the bridge voltage to zero when a soft-switching commutation is required. However,the active dc-rail switch has to conduct high current with a large duty cycle and also causes significant conduction loss.Fortunately,in the PFC applications where bidirectional powerflow is not required,a diode can be used as the dc-rail switch.The resulting simpler and more efficient ZVT topology is shown in Fig.4(b)[8].The dc-rail diode also alleviates the short-through problem of the bridge switches and,thus, enhances the operation reliability of the rectifier.Fig.5shows the experimental waveforms of a50-kHz10-kW prototype,in which zero dc-link voltage indicates the zero-voltage turn-on of main switches.ThereducedMAO et al.:REVIEW OF POWER-FACTOR CORRECTION CIRCUITS441(a)(b)(c)(d)Fig.4.Soft-switching topologies of three-phase boost rectifier.(a)Actively clamped RDCL converter.(b)DC-rail ZVT boost rectifier.(c)ZVT boost rectifier.(d)Improved ZVT boost rectifier.current peak are reduced significantly while all main switches are turned on with zero voltage.In rectifier mode,the main switch turn-off events are the same as in an optimum SVM,in which only the two smaller phase currents are switched in each switching cycle.A prototype converter has been built for a permanent motor drive in a flywheel energy storage system [22].The experimental efficiency in both inverter mode and rectifier mode is above 97%at 100-kHz switching frequency,500-W output power,120-V dc,and 100-V peak ac voltages.Some modifications to further reduce the auxiliary switch stresses are discussed in [23]and [24].Several three-level boost rectifiers are proposed in [20]and [21]for high-voltage applications,where the switch voltage rating is reduced to half the output voltage.The three-level topologies have lower switching losses and input current ripple than conventional two-level topologies and provide a way to use power MOSFET’s for some high-voltage and high switching frequency applications.Due to the lower power loss and voltage rating of the switches,as well as the smaller boost inductance,a three-level rectifier could offer significant performance and cost advantages over two-level rectifiers.The topology in [21]seems especially attractive,since it can be viewed as paralleled single-phase PFC converters,and the active switches are in the clamp path,instead of the main power path.Fig.6shows its ZVT version proposed in [19].IV.T HREE -P HASE B UCK R ECTIFIERSA buck rectifier has some attractive features compared to a boost rectifier,such as inherent short-circuit protection,easy inrush current control,and low output voltage.In addition,its input currents can be controlled in open loop,and much wider voltage loop bandwidth can be achieved.A buck rectifier with a freewheeling diode is shown in Fig.7(a).Generally,(a)(b)Fig.5.Experimental waveforms of three-phase ZVT boost rectifier.(a)Input currents (time scale 5ms/div,vertical scale 20A/div).(b)Resonant waveforms (time scale 0.5 s =div):a buck rectifier has higher conduction loss than its boost counterpart,because more semiconductor devices are in series,and the input currents are discontinuous.However,a buck rectifier usually has lower switching loss,especially at low line conditions,where the boost rectifier’s switching loss (and also conduction loss)reaches its maximum.The worst case power loss of a three-phase buck rectifier is not necessarily higher than that of a three-phase boost rectifier.At present,three-phase buck rectifiers are not used as widely as three-phase boost rectifiers,probably because a single-phase buck442IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS,VOL.44,NO.4,AUGUST1997Fig.6.Three-phase three-level ZVT boost rectifier.(a)Nonisolated three-phase buck rectifier.(b)Isolated single-stage ZVS buckrectifier.(a)(b)Fig.7.Three-phase buck rectifiers.rectifier is not a viable technique and three-phase current-source inverters,which use the same topology as the buck rectifiers without the freewheeling diode,are not popular,except in very high-power SCR applications.However,it is possible that three-phase buck rectifiers could achieve certain performance/cost advantages over boost rectifiers for some applications,especially if the performance of bidirec-tional voltage devices [e.g.,symmetrical insulated-gate bipolar transistors (IGBT’s)]can be significantly improved with the development of power semiconductor techniques in the future.Some soft-switching topologies of nonisolated buck rectifiers are studied in [28].Single-stage power conversion with buck topology can be achieved by replacing the dc-link inductor with a transformer,as reported in [25].To reset the transformer,the dc-link voltage has to be bidirectional,and each bridge arm has to be a four-quadrant switch,which can be implemented as two back-to-back switch/diode pairs.The soft-switching version of an isolated buck rectifier [26],[27],shown in Fig.7(b),achieves zero-voltage turn-on for all switches,without any additional components,by using the same technology as in ZVS phase-shifted full-bridge dc–dc converters.The converter efficiency and cost is about the same as in a two-stage approach utilizing a CCM boost rectifier and a dc–dc converter.Fig.8shows the experimental transformer primary voltage and current waveforms of a 91-kHz prototype.The positive and negative pulses from the same phases are grouped together,and a positive pulse and a negative pulse are always used alternately,as clearly indicated by Fig.8,so that the transformer utilization is maximized.The continuous primaryMAO et al.:REVIEW OF POWER-FACTOR CORRECTION CIRCUITS443Fig.8.Primary voltage and current of ZVS buck rectifier.current is a characteristic of ZVS bridge circuits,similar to that in dc–dc converters.The measured converter efficiency is 92.2%with2-kW output power,208-V input rms,and50-V output voltages.V.C ONTROL AND S YSTEM I SSUESA.Control DesignControl of power converters usually can be divided into three functions:modulation,current control,and regulation of an output variable(the output voltage in rectifiers).In the three-phase inverter applications,the system dynamics is usually dominated by the slow electromechanical and/or large reactive components,so that the inverter dynamic performance is not very critical.Additionally,accurate ac current control is not very important in many inverter applications(except forfield-oriented drives).On the contrary,high-quality current control,without the use of large reactive components,is the major objective in PFC applications.With high switching frequencies,which are made possible through the use of soft-switching techniques,high performance and very wide bandwidth control can now be designed.The control design is facilitated by recent improvements in the modeling of three-phase converters[31],[40],[41],[48].All standard modulation techniques developed for inverters can be used in rectifier applications.An excellent survey of these techniques can be found in[37].Sinusoidal PWM (SPWM)is well suited for analog implementation[42],but causes higher switching losses and current distortion[8]. In boost rectifiers,SPWM can be used with third-harmonic injection to decrease the minimum output voltage by15%.The same effect is automatically achieved with space–vector mod-ulation(SVM)[37],which also significantly reduces switching loss and high-frequency current ripple.Many of the soft-switching techniques require the use of completely different modulation strategies[34]or modifications of the standard PWM schemes[8],[38],[39],due to the requirement of synchronizing switch turn-on instants in the three phases. The simplest current control for boost rectifiers is the hysteresis control,which combines the modulation and current control into a single function.It also provides the widest current-loop bandwidth of all schemes.The major problems with the hysteresis control are its load dependence of the switching frequency and the interference among phases,re-sulting in irregular converter operation and uneven current waveforms.These problems can be remedied by controlling two line-to-line currents(differences between the phase cur-rents)[43],[44].Average current control is widely used in three-phase recti-fiers.Because there are only two independent current variables in a three-phase rectifier,only two input currents need to be controlled.The modulation scheme is often adjusted,such that the switches in the phase carrying the highest current are disabled,so the switching loss is reduced by about50%. The control can be implemented either with analog or digital hardware.In digital implementations,two current compen-sators in rotating coordinates are usually used[31].The advantage of the digital implementation is that all control variables are constant in steady state for a balanced system, and good steady-state current quality can be easily obtained. Conversely,in the analog current control,the control variables are time-varying,and the ideal control voltages may even be discontinuous at the current zero crossing.Therefore,very fast analog controllers have to be used to achieve good current control,and the current distortion is usually higher than with the digital controllers,due tofinite controller gains at line frequency[33].Similar to dc–dc converters,the output voltage loop bandwidth for boost rectifiers is severely limited by the presence of the right-half plane zero in control-to-output transfer function[31],[45].For digital implementations,the bandwidth is limited even more by the computational and sampling delays.In the buck rectifiers,due to topological restrictions,three phases cannot operate independently.This prevents the direct use of hysteresis input current controllers.Instead,SVM or modified SPWM techniques are usually used[46],[49]. Excellent input current quality can be achieved with open loop control[47].B.Filter Design and System InteractionSince a PFC converter has to meet EMI specifications, an inputfilter is usually required.Thefilter should provide enough high-frequency noise attenuation,while keeping a low input displacement angle and should be as small and as light as possible to increase power density.A way to predict the conducted EMI emission of boost rectifiers is presented in [33],which can be easily extended to buck rectifiers.The use of multistage Cauer–Chebyshevfilters is proposed,and a complete design procedure is presented in[32].A proper damping network is necessary to ensure system stability.444IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS,VOL.44,NO.4,AUGUST 1997TABLE IF EATURE C OMPARISONOFS OFT -S WITCHING T HREE -P HASE PFC CONVERTERSBecause of losses in damping resistors,nonstandard damping schemes have to be used [32].The system interaction between the converter and the input filter (including line impedance)is an important and complex issue.Since a three-phase converter is intended for high-power applications,it is characterized by low input impedance.On the other hand,the output impedance of the input filter cannot be reduced arbitrarily,since its capacitance is limited by displacement factor requirements [32].As a result,the filter output impedance and converter input impedance usually overlap over a certain frequency range,and system interaction may occur,especially when high line frequency is used.The interaction in the buck rectifier has been addressed in [47],while a general stability analysis is presented in [48].The interaction at the dc link is also a critical issue in two-stage PFC converters,since the second stage presents to the front-end rectifier a constant power (negative resistance in small signal sense),due to its tight output voltage regulation.System design should involve considerations similar to those used in distributed dc power systems [50].As a general guideline,the converter should be designed with enough input inductance and output capacitance to sufficiently increase the input impedance and lower the output impedance at higher frequencies.The control design also plays an important role in alleviating the system interaction.VI.C ONCLUSIONSThis paper has given a comprehensive review of recent developments in three-phase PFC techniques,especially soft-switching techniques.It can be expected that soft-switching converters will be an increasingly viable alternative to theconventional hard-switching power conversion in many high-performance applications,since they can alleviate or solve some problems which have plagued hard-switching convert-ers for many years.At least,soft-switching techniques can provide another dimension to optimize the PFC system.Table I summarizes the main features of several three-phase soft-switching PFC topologies.However,soft-switching techniques in high-power converters are still at the early development stage.To realize the full potential of soft switching for different applications,more evaluation and practical design work are still needed.The efficiency improvement,i.e.,the power loss reduction,of soft-switching converters is an important advantage and has been demonstrated in many previous papers.However,the soft-switching operation also creates favorable switching trajectories for power switches,thus improving the reliability,voltage-current stress,and EMI emissions of the power converter.These factors could have a significant impact on the performance,cost,and design practice of power conversion equipment and need to be assessed in more detail in the future.A.Future DevelopmentIt can be expected that the use of three-phase PFC circuits will grow substantially in the future.The growth will be most prominent in applications such as telecommunications,autonomous ac power systems (e.g.,aircraft and ships),and other applications where performance and/or power density are critical.In the consumer and industrial markets,the growth will be mainly conditioned by new power-quality regulations,due to the significant add-on cost of active PFC when com-pared to diode rectification and bulky passive filter.For low-MAO et al.:REVIEW OF POWER-FACTOR CORRECTION CIRCUITS445power applications,the simple three-phase PFC circuits may provide a cost-effective solution with satisfactory performance. At the high-power end,the tradeoff between passive harmonic filtering and the active PFC with mandatory high-frequency EMIfiltering tends to be in favor of the active circuits in the future,also.Most of the three-phase inverter topologies and control technologies can be easily adapted for PFC applications. For example,regenerative,current-regulated voltage-source inverters for motor drives can be directly used as boost rectifiers with minimum modifications.However,the issues of high-frequency operation,input current quality,EMIfiltering, high efficiency,and power density remain the driving force. 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二电平和三电平逆变器svpwm调制方法-概述说明以及解释1.引言1.1 概述概述部分应该对二电平和三电平逆变器svpwm调制方法进行简要介绍，说明其在逆变器领域中的重要性和应用。

可以按照以下方式编写该部分的内容：概述逆变器是一种将直流电能转换为交流电能的装置，广泛应用于电力电子领域。

在逆变器的调制方法中，svpwm是一种常用且有效的调制技术。

根据逆变器的拓扑结构的不同，svpwm调制方法可以分为二电平和三电平两种。

二电平逆变器svpwm调制方法通过对逆变器开关管的控制，使输出波形接近正弦波，并最大化功率输出。

其调制原理是将高频三角波与标准正弦波进行比较，通过控制开关管的导通时间实现输出波形的控制。

二电平逆变器svpwm调制方法具有简单、可靠的特点，在许多应用中得到广泛使用。

相比之下，三电平逆变器svpwm调制方法引入了一个额外的中点电压，可以提供更高的输出电压质量。

其调制原理是将标准正弦波与两个输出电压等级的三角波进行比较，通过控制开关管的导通时间和电平，实现输出波形的更精确控制。

三电平逆变器svpwm调制方法适用于高功率应用和对输出电压质量要求较高的场景。

本文将重点探讨二电平和三电平逆变器svpwm调制方法的调制原理和实现方式，比较其优缺点，并对其应用前景进行展望。

二电平和三电平逆变器svpwm调制方法的研究对提高逆变器效率、降低谐波失真以及满足不同应用需求具有重要意义。

1.2 文章结构文章结构部分的内容应该包括对整篇文章的结构进行概括和简要说明。

可以按照以下方式编写:本文主要围绕着二电平逆变器SVPWM调制方法和三电平逆变器SVPWM调制方法展开讨论。

文章结构如下：第一部分为引言，包括概述、文章结构和目的。

在概述中，将会介绍逆变器的作用和重要性，以及SVPWM调制方法在逆变器中的应用背景。

文章结构将会简要列举本文的章节和主要内容。

目的部分将明确本文旨在比较二电平和三电平逆变器SVPWM调制方法的优劣以及探讨其应用前景。

基于SVPWM的三电平拓扑仿真与实验杨智，赵正明，胡璇罗浩电机传动系，国电南京自动化有限公司，南京210003，中国电气工程与应用电子技术，清华大学，北京100084，中国摘要：三电平逆变器已成为电力电子领域的研究热点。

在对三电平拓扑结构进行研究的基础上，给出了逆变器各节点的运行参数和波形，为设计可靠的系统和选择合适的半导体器件提供了参考。

一个三电平逆变器控制系统模型的提出和模拟在PSIM（PowerSIM），以及仿真的相关波形和数据详细。

同时给出了基于该设计的实际实验的运行参数和波形。

通过比较，证明了该控制系统的有效性。

还介绍了常用的半导体选择方法。

一、引言可靠性与价格成为电力电子的重要研究对象[ 1 ]。

然而，拓扑结构、控制方法、半导体选择、分布参数、工作条件等多方面因素影响着实际情况。

因此，一个成功的产品的设计应密切相关的分析，设计，仿真，实验的系统许多论文给出了SVPWM仿真，但不给出主电路的波形。

本文将讨论的三电平逆变器的拓扑结构，并提供模拟的配置（基于PSIM）。

在系统中选择主要的电气节点显示的电流和电压波形。

同时，一个三级调速55kW变频系统实验平台，是考虑到现实。

在实验中，主要的电气节点的真实波形的测量仪器，并将实验结果与仿真结果进行比较，以验证模型的正确性和合理性。

同时，对三电平逆变器的运行过程、主电路的特性、不同电节点之间的关系进行了分析。

为半导体器件的选择、工作站的分析、系统的设计和实验提供了参考。

二、控制算法模型众所周知，如果电流和电压波形能在电机间隙中形成圆旋转磁场，那么逆变器就具有良好的性能。

交-直-交变频器的输出脉冲电压的半导体。

如果脉冲电压可以使旋转磁场，电机将顺利运行。

因此，SVPWM算法就应该如此工作。

控制模型与PSIM的算法基于SVPWM算法。

图1中，每个参数都可以在仿真中进行调整。

图（1）控制算法模型三、主电路模型主电路模型是典型的三电平逆变器拓扑结构，如图2所示。

基于SVPWM三相并网逆变器仿真报告目录1.SVPWM逆变器简介 (1)2.SVPWM逆变器基本原理 (2)2.1.SVPWM调制技术原理 (2)2.2.SVPWM算法实现 (5)3.SVPWM逆变器开环模型 (9)3.1.SVPWM逆变器开环模型建立 (9)3.2.SVPWM逆变器开环模型仿真分析 (12)4.SVPWM逆变器闭环模型 (14)4.1.SVPWM逆变器闭环模型建立 (14)4.2.SVPWM逆变器闭环模型仿真分析 (15)1.SVPWM逆变器简介三电平及多电平空间矢量调制(Space Vector Pulse Width Modulation，SVPWM)法是建立在空间矢量合成概念上的PWM方法。

它以三相正弦交流参考电压用一个旋转的电压矢量来代替，通过这个矢量所在位置附近三个相邻变换器的开关状态矢量，利用伏秒平衡原理对其拟和形成PWM波形。

空间矢量调制方法在大范围调制比内有很好的性能，具有很小的输出谐波含量和较高的电压利用率。

而且这种方法对各种目标的控制相对容易实现。

SVPWM技术源于三相电机调速控制系统。

随着数字化控制手段的发展，在UPS/EPS、变频器等各类三相PWM逆变电源中得到了广泛的应用。

与其他传统PWM技术相比，SVPWM技术有着母线电压利用率高、易于数字化实现、算法灵活便于实现各种优化PWM 技术等众多优点。

2. SVPWM 逆变器基本原理2.1. SVPWM 调制技术原理SVPWM 的理论基础是平均值等效原理，即在一个开关周期内通过对基本电压矢量加以组合，使其平均值与给定电压矢量相等。

在某个时刻，电压矢量旋转到某个区域中，可由组成这个区域的两个相邻的非零矢量和零矢量在时间上的不同组合来得到。

两个矢量的作用时间可以一次施加，也可以在一个采样周期内分多次施加，这样通过控制各个电压矢量的作用时间，使电压空间矢量接近按圆轨迹旋转，就可以使逆变器输出近似正弦波电压。

SVPWM 实际上是对应于交流感应电机或永磁同步电机中的三相电压源逆变器功率器件的一种特殊的开关触发顺序和脉宽大小的组合，这种开关触发顺序和组合将在定子线圈中产生三相互差120°电角度、失真较小的正弦波电流波形。

毕业论文Array二○一四年六月基于SVPWM的异步电机直接转矩控制原理及仿真专业班级：电气工程及其自动化1班姓名：指导教师：轮机工程学院摘要本文首先论述了交流调速系统的发展与现状，简要回顾了电力电子器件、直接转矩控制技术、空间矢量脉宽调制技术的发展历程。

接着，系统地论述了直接转矩控制系统的原理，直接转矩控制技术是继矢量控制技术后发展的有一种高性能交流调速技术，它采用空间矢量的分析方式，在两相静止坐标系下计算并控制电机的电磁转矩和磁链。

不过，直接转矩控制技术作为一种较新颖的技术，自然存在着不少的问题，比如电流与转矩的脉动问题等。

本论文针对传统直接转矩控制系统所固有的问题，提出了基于空间矢量调制技术的直接转矩控制策略。

这种新型控制策略将两者的优点结合起来，把电动机和PWM逆变器看成一体，使电动机获得幅值恒定的近似圆形的磁场，以解决其转矩、电流脉动问题。

在论文的撰写阶段，本人做了如下的工作：通过理论分析，建立了两相静止坐标系下的异步电机数学模型，设计转矩和磁链观测模块，设计坐标变换模块，设计SVPWM生成模块。

最后使用Simulink进行仿真，根据原理，搭建出各个模块的仿真图，仿真实验结果表明，此种控制策略可以减少电磁转矩以及电流的脉动，大大提高直接转矩控制系统的控制性能。

关键词：异步电动机；直接转矩；空间矢量脉宽调制；MATLABABSTRACTFirstly, this thesis discusses the current situation and development of the alternating current governor system. And briefly retrospect the development history of power electronic devices, direct torque control system, and space vector pulse width modulation. Then systematically discuss the theory of direct torque control. It’s an alternating current governor technology with high performance developed after vector control technology, which adopts the analysis method of space vector to calculate and control the electromagnetic torque and flux linkage of motor in the two-phase static coordinate. However, naturally, there are some problems, such as the pulsation problem of current and electromagnetic torque in direct torque control technology for it is a rather novel technology. This thesis puts forward a control policy of direct torque control system based on space vector PWM aiming at the inherent problems of traditional direct torque control system.This new control policy combines two technologies together seeing the electromotor and PWM inverter as a whole to make a circular magnetic field with a constant amplitude to solve the pulsation problem of current and electromagnetic torque. In the period of writing this thesis, I have done the work as follows: Through the theory analysis, build the mathematical model of asynchronous motor in the two-phase static coordinate, and design the observation modules of torque and flux linkage, the coordinate transformation modules, and SVPWM generating modules.Lastly, I use Simulink to simulate them, building every simulation diagram according to the theory. And the result indicates that this control policy can promote the control performance of direct torque control system greatly through reducing the pulsation of torque and current.Keywords：Asynchronous motor，Direct torque control，Space vector pulse width modulation，MATLAB目录第1章绪论 (1)1.1 交流调速系统的发展与现状 (1)1.1.1 交流调速系统的硬件发展 (1)1.1.2 交流调速系统控制方法的发展 (1)1.2 直接转矩控制技术的发展与现状 (2)1.3 空间电压矢量调制技术（即SVPWM）的发展以及现状 (3)1.4 本章小结 (4)第2章异步电动机的数学模型 (5)2.1 三相静止坐标系下的异步电机数学模型 (5)2.2坐标变换 (6)2.2.1 三相—两相静止坐标变换 (6)2.2.2 两相—两相旋转坐标变换 (7)2.3 交流异步电动机在静止两相坐标系下的动态数学模型： (8)2.4 本章小结 (9)第3章直接转矩控制系统原理 (10)3.1直接转矩控制系统结构框图 (10)3.2 磁链控制闭环与转矩控制闭环 (10)3.2.1 磁链控制闭环 (10)3.2.2 转矩控制闭环 (13)3.3 逆变器 (14)3.4电压空间矢量选择 (15)3.5扇区判断 (16)3.6本章小结 (17)第4章空间矢量脉宽调制技术 (18)4.1 空间矢量脉宽调制原理 (18)4.2 期望电压空间矢量的获得 (21)4.3 SVPWM调制算法 (22)4.4 本章小结 (22)第5章基于SVPWM异步电机直接转矩控制系统 (23)5.1 基于SVPWM 直接转矩控制系统 (23)5.2磁链定向方式 (23)5.3 DTC-SVM的扇区判断 (24)5.4空间电压矢量调制 (26)5.5 本章小结 (28)第6章DTC-SVM仿真研究 (29)6.1 MATLAB/Simulink的简介 (29)6.2 基本仿真模块 (29)6.3 坐标变换仿真模块 (29)6.3.1三相—两相静止坐标仿真模块 (30)6.3.2 旋转坐标变换仿真模块 (30)6.4 转矩观测仿真模块 (30)6.5 磁链观测仿真模块图 (31)6.6 SVPWM仿真模块 (31)6.6.1 SVPWM模块仿真图 (32)6.6.2扇区判断仿真模块 (32)6.6.3基本电压空间矢量工作时间计算仿真模块 (32)6.6.4逆变器导通时刻计算 (34)6.6.5 SVPWM波生成模块 (34)6.7仿真实验结果 (35)6.7.1 定子磁链轨迹比较 (35)6.7.2定子电流比较 (36)6.7.3 转速响应比较 (38)6.7.4 转矩响应比较 (39)6.8 本章小结 (40)第7章结论 (41)参考文献 (42)致谢 (43)附录1 (44)附录2 (45)第1章绪论1.1 交流调速系统的发展与现状一直以来，直流调速系统以其简单而优越的调速性能，掩盖了其具有结构复杂，换向麻烦等缺点，被广泛地应用。

1 引言1.1交流调速技术的发展和现状在工农业生产、科技、国防及日常生活等各个领域，电动机作为主要的动力设备被广泛应用。

直流电动机相比于交流电动机，结构复杂、体积大、成本和维护费用高，并且不适于环境恶劣的场合，但凭借控制简单、调速平滑和性能良好等特点在早期电气传动领域中一直占据主导地位[1]。

从20世纪30年代开始，人们就致力于交流调速技术的研究。

特别是20世纪60年代以后，电力电子技术和控制技术的飞速发展，使得交流调速性能得到很大的提高，在实际应用领域也得到认可和快速的普及。

交流调速的发展可以说是硬件和软体的发展过程[3]。

随着电力电子技术、微处理器技术和自动化控制技术的不断完善和发展，使得交流调速系统的调速范围宽、速度精度高和动态响应快，其技术性能可与直流调速系统相媲美、相竞争，并在工程应用领域中逐渐取代直流调速系统[5]。

交流电动机的高效调速方法是变频调速，它不但能实现无级调速，而且根据负载的特性不同，通过适当调节电压和频率之间的关系，可使电机始终高效运行，并保证良好的动态特性，更能降低起动电流、增加起动转矩和改善电机的起动性能。

交流调速控制理论的发展经历了电压-频率控制、矢量控制、直接转矩控制，控制理论的发展使控制系统性能不断提高[2]。

电压-频率协调控制，即恒压频比控制，是指在基频以下调速时维持输出电压幅值和频率的比值恒定，实现恒转矩调速运行；在基频以上调速时，将输出电压维持在额定值，使磁通与频率成反比下降，实现弱磁恒功率调速运行。

其控制系统结构简单，成本低，能满足一般的平滑调速，但动、静态性能有限，适用于风机、水泵等负载对调速系统动态性能要求不高的场合[8]。

矢量控制就是将磁链与转矩解耦，有利于分别设计两者的调节器，以实现对交流电机的高性能调速。

矢量控制方式又有基于转差频率控制的矢量控制方式、无速度传感器的矢量控制方式和有速度传感器的矢量控制方式等[12]。

这样就可以将一台三相异步电机等效为直流电机来控制，因而获得与直流调速系统同样的静、动态性能。