Methods and power conversion system control apparatus to control igbt junction temperature at low speed

1 . A method for controlling a multiphase inverter, the method comprising: when a fundamental output frequency of the multiphase inverter is less than a non-zero threshold frequency, using at least one electronic processor, computing a plurality of high frequency injected phase duty ratios at least partially according to at least one desired output parameter and a common mode frequency corresponding to a common mode period less than a time constant of a thermal impedance of switching devices of the multiphase inverter; when the fundamental output frequency of the multiphase inverter is less than the non-zero threshold frequency, using the at least one electronic processor, selectively computing a plurality of offset phase duty ratios at least partially according to the high frequency injected phase duty ratios and an offset value; and when the fundamental output frequency of the multiphase inverter is less than the non-zero threshold frequency, using the at least one electronic processor, generating inverter switching control signals using discontinuous pulse width modulation at least partially according to the offset phase duty ratios. 2 . The method of claim 1 , comprising: when the fundamental output frequency of the multiphase inverter is greater than or equal to the non-zero threshold frequency, using the at least one electronic processor, computing a plurality of initial phase duty ratios at least partially according to a desired output parameter; and when the fundamental output frequency of the multiphase inverter is greater than or equal to the non-zero threshold frequency, using the at least one electronic processor, generating the inverter switching control signals using space vector pulse width modulation at least partially according to the initial phase duty ratios. 3 . The method of claim 2 , wherein generating the inverter switching control signals when the fundamental output frequency of the multiphase inverter is greater than or equal to the non-zero threshold frequency comprises: using the at least one electronic processor, computing a plurality of third harmonic injected phase duty ratios at least partially according to a third harmonic of the fundamental output frequency of the multiphase inverter; and generating the inverter switching control signals using third harmonic injection pulse width modulation according to the third harmonic injected phase duty ratios. 4 . The method of claim 3 , wherein the non-zero threshold frequency corresponds to a threshold period less than or equal to the time constant of the thermal impedance of the switching devices of the multiphase inverter. 5 . The method of claim 4 , wherein the common mode period is less than or equal to 0.02 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 6 . The method of claim 2 , wherein the non-zero threshold frequency corresponds to a threshold period less than or equal to the time constant of the thermal impedance of the switching devices of the multiphase inverter. 7 . The method of claim 2 , wherein the common mode period is less than or equal to 0.02 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 8 . The method of claim 1 , wherein the non-zero threshold frequency corresponds to a threshold period less than or equal to the time constant of the thermal impedance of the switching devices of the multiphase inverter. 9 . The method of claim 8 , wherein the common mode period is less than or equal to 0.02 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 10 . The method of claim 8 , wherein the non-zero threshold frequency corresponds to a threshold period less than or equal to twice the time constant of the thermal impedance of the switching devices of the multiphase inverter. 11 . The method of claim 10 , wherein the common mode period is less than or equal to 0.02 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 12 . The method of claim 1 , wherein the common mode period is less than or equal to 0.02 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 13 . The method of claim 12 , wherein the common mode period is less than or equal to 0.01 times the time constant of the thermal impedance of the switching devices of the multiphase inverter. 14 . The method of claim 1 : wherein the at least one desired output parameter includes a modulation index value K MI , and an angle value 0; and wherein the high frequency injected phase duty ratios d2 a (θ), d2 b (θ) and d c (θ) for phases a, b and c of the multiphase inverter are computed according to the following equations: d 2 a (θ)= K MI COS(θ)− Ki COS( K HF θ), d 2 b (θ)= K MI COS(θ−2π/3)− Ki COS( K HF θ), and d 2 c (θ)= K MI COS(θ+2π/3)− Ki COS( K HF θ); wherein Ki is less than 1; and wherein K HF is greater than or equal to 50. 15 . The method of claim 14 , comprising: when the fundamental output frequency of the multiphase inverter is greater than or equal to the non-zero threshold frequency, using the at least one electronic processor: determining ( 132 ) a maximum duty ratio dmax of the high frequency injected phase duty ratios d2 a (θ), d2 b (θ) and d2 c (θ), determining ( 132 ) a minimum duty ratio dmin of the high frequency injected phase duty ratios d2 a (θ), d2 b (θ) and d2 c (θ), setting the offset value to 1−dmax if |dmax|>|dmin|, setting the offset value to −1−dmin if |dmax|≦|dmin|, and computing the offset phase duty ratios d OFSTa (θ), d OFSTb (θ) and d OFSTc (θ) according to the following equations: d OFSTa (θ)= d 2 a (θ)+ do, d OFSTb (θ)= d 2 b (θ)+ do , and d OFSTc (θ)= d 2 c (θ)+ do; wherein the inverter switching control signals are generated using discontinuous pulse width modulation at least partially according to the offset phase duty ratios d OFSTa (θ), d OFSTb (θ) and d OFSTc (θ) using a triangle wave carrier having a range from −1 to +1. 16 . The method of claim 15 , wherein K HF is greater than or equal to 100. 17 . The method of claim 14 , wherein K HF is greater than or equal to 100. 18 . A non-transitory computer readable medium with computer executable instructions for controlling a multiphase inverter, the computer readable medium comprising computer executable instructions for: when a fundamental output frequency of the multiphase inverter is less than a non-zero threshold frequency, computing a plurality of high frequency injected phase duty ratios at least partially according to at least one desired output parameter and a common mode frequency corresponding to a common mode period less than a time constant of a thermal impedance of switching devices of the multiphase inverter; when the fundamental output frequency of the multiphase inverter is less than the non-zero threshold frequency, selectively computing a plurality of offset phase duty ratios at least partially according to the high frequency injected phase duty ratios and an offset value; and when the fundamental output frequency of the multiphase inverter is less than the non-zero threshold frequency, generating inverter switching control signals using discontinuous pulse width modulation at least partially according to the offset phase duty ratios. 19 . An apparatus for controlling a multiphase inverter, comprising: an electronic memory; and