ers. R. Gurunathan, et al. [83], pr

ers. R. Gurunathan, et al. [83], presented in a zero voltage switching (ZVS) dc link, single-phase, PWM VSI is proposed in this literature. E. F. Vidal, et al. [84], suggested in this a new threephase rectifi er that allows the operation as rectifi er or as inverter. A. Xu, et al. [85], has been suggested multipulse converters are suitable for high-power application with the merits of low switching frequency and perfect harmonic performance. C. A. Canesin, et al. [86], introduced in a single-phase high-power factor PWM boost rectifi er featuring soft commutation of the active switches at zero current. X. Ruan, et al [87], used in this literature a family of modulation strategies for PWM three-level (TL) converters. J. Wu, et al. [88], presented in this literature a 100 kW three-phase PWM boost rectifi er that serves as the front-end power source for a dc distributed power system. 2.3 Switching Frequency H. W. Van Der Broeck, et al. [89], suggested in this literature is harmonic content of current, torque pulsations, and harmonic copper losses of a three-phase induction machine fed by a twophase PWM inverter. S. K. Mazumder, et al. [90], addressed in this demonstrate a new concept for wireless PWM control of a parallel dc–dc buck converter. K. M. Smith, Jr., et al. [91], introduced in this literature a new nonlinear control technique that has one-cycle response and has nearly constant switching frequency. Y. Tzou, et al. [92], used in a new circuit realization of the novel SVPWM strategy. An SVPWM control integrated circuit (IC) has been developed. I. Boonyaroonate, et al. [93], presented in a class E isolated dc/dc converter for regulating the output voltage at a fi xed switching frequency is presented verifi ed in this literature. D. De Souza Oliveira, et al. [94], suggested in this literature the application of the asymmetrical duty cycle to the three-phase dc/dc PWM isolated converter. J. K. Steinke,et al. [95], addressed in this literature by putting an LCfi lter between a PWM VSI and induction motor, standard industrial motors can be utilized also for adjustable speed drive (ADS) applications. L. D. Reis Barbosa, et al. [96], introduced a high-switching frequency associated with soft commutation techniques is a trend in switching converter. P. K. Jain, et al. [97], used in this literature APWM dc/dc resonant converter topologies that exhibit near-zero switching losses while operating at constant and very high frequencies in this literature. K. Satyanarayana,et al. [98], has been presented in this literature two RPWM algorithms for voltage source inverter fed induction motor drives with fi xed switching frequency for reduced harmonic distortion and acoustical noise. 2.4 Others Performance Parameters P. Mantovanelli, et al. [99], addressed a new current-fed dc-dc power converter circuit whose features are as follows: 1) inherent high reliability provided by the input boost inductor in this literature. E. Toribio, et al. [100], has been used a study of a dc–dc Boost converter whose output voltage is controlled by naturally sampled constant-frequency PWM operating in both continuous and discontinuous mode. R. B. Prest, et al. [101], used almost all PWM converters using bipolar transistors experience the problem of reverse transistor conduction. J. Sun, et al. [102], suggested in this literature PWM based on the elimination of low-order harmonics necessitates solving systems of nonlinear equations in this literature. S. R. Bowes, et al. [103], has been addressed Harmonic Elimination PWM strategies for drives, and static power converters has been recently developed in this literature. T. Wu, et al. [104], introduced in this literature structural approach to synthesizing soft switching PWM converters based on the concept of basic converter units (BCUs). With a proper reconfi guration, PWM converters can be synthesized from buck BCU or boost. N. Bianchi,et al. [105], has been used in high speed applications, slotless PM motors appear an attractive solution, being almost insensitive to magneto motive force harmonics. A. Ammous, et al. [106], presented in this contrary to the classical ideal averaged models, the introduced averaged model includes the nonlinear effects of the power semiconductor devices. R. Oruganti, et al. [107], addressed a new converter with two variations is proposed. A novel APWM control techniques is used to control the converter under constant switching frequency operation in this literature. 3 Summary of the paper The following tables give summary of the paper as: 3.1 Reduction of Harmonics point of view of PWM techniques 3.1.1 Reduction of Harmonics point of view: Table 1. Reduction of Harmonics point of view Parameters Voltage Harmonics Current Harmonics Voltage & Current Harmonics Voltage, Current, & Noise Harmonics Distortion Factor (HDF) Voltage Regulation Current Regulation Total No. of Literatures Reviews out of 72 Literatures 13 22 22 01 10 02 02 % of Literatures Reviews out of 72 Literatures 18.05 30.56 30.56 1.39 13.89 2.78 2.78 From above tables 1, it is concluded that the 18.05% of total literatures are reviews based on Voltage Harmonics, 30.56% of total literatures are reviews based on Current Harmonics, 30.56% of total literatures are reviews on based Voltage & Current Harmonics, 1.39% of total literatures are reviews based on Voltage, Current & Noise Harmonics, 13.89% of total literatures are reviews on based Harmonics Distortion Factor (HDF), 2.78% of total literatures are reviews on based Voltage Regulation, and 2.78% of total literatures are reviews on based from Current Regulation viewpoints. 3.1.2 Power Factor, Switching Frequency, and Others parameters point of view Table 2. Power Factor, Switching Frequency, and Others parameters point of view