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A controller of a power converter has: an average loss calculator (202) calculating an average loss in a semiconductor device; and a partial temperature variation estimation part (204), while regarding the semiconductor device as a thermal network including at least one combination of a thermal resi

A controller of a power converter has: an average loss calculator (202) calculating an average loss in a semiconductor device; and a partial temperature variation estimation part (204), while regarding the semiconductor device as a thermal network including at least one combination of a thermal resistance and a thermal time constant, estimating a partial temperature variation of the combination from a loss in the semiconductor device and the combination of the thermal resistance and the thermal time constant. The partial temperature variation estimation part (204) estimates an average temperature from the loss, the thermal resistance, and the thermal time constant; extracts a pulsation envelope temperature exceeding the maximum value of a pulsation temperature dependent on the average loss and the pulsation frequency; and estimates a temperature variation in the semiconductor device by adding the average temperature and the pulsation envelope temperature.

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1. A controller of a power converter comprising: an average loss calculator configured to calculate an average loss in a semiconductor device in a period of carrying out an estimation calculation of a temperature of the semiconductor device; anda partial temperature variation estimation part configu

1. A controller of a power converter comprising: an average loss calculator configured to calculate an average loss in a semiconductor device in a period of carrying out an estimation calculation of a temperature of the semiconductor device; anda partial temperature variation estimation part configured to, while regarding the semiconductor device as a thermal network including at least one combination of a thermal resistance and a thermal time constant, estimate a partial temperature variation of the combination from a loss in the semiconductor device and the combination of the thermal resistance and the thermal time constant, whereinthe partial temperature variation estimation part comprises: an average temperature estimation part configured to estimate an average temperature from the loss, the thermal resistance, and the thermal time constant; anda pulsation envelope temperature extraction filter configured to extract, by use of the thermal resistance, the thermal time constant, and a pulsation frequency of the loss, a pulsation envelope temperature exceeding the maximum value of a pulsation temperature dependent on the average loss and the pulsation frequency, andthe partial temperature variation estimation part estimates a temperature variation in the semiconductor device by adding the average temperature and the pulsation envelope temperature. 2. The controller of a power converter according to claim 1, wherein the partial temperature variation estimation part estimates, while regarding the semiconductor device as a thermal network including two or more combinations of a thermal resistance and a thermal time constant, the partial temperature variation for each combination from the loss and the combination of the thermal resistance and the thermal time constant, and the controller further comprises a device temperature variation estimation part configured to estimate a temperature variation in the semiconductor device by combining the partial temperature variations estimated for the respective combinations. 3. The controller of a power converter according to claim 1, wherein the pulsation envelope temperature extraction filter extracts the pulsation envelope temperature by extracting a partial filter for each frequency component by performing a Fourier series expansion for a loss waveform of the semiconductor device, and combining results of calculations using the extracted filters,the partial filter for each of the frequency components is configured on the basis of a thermal resistance, a thermal time constant, and a frequency corresponding to the frequency component, andthe pulsation envelope temperature extraction filter combines filter outputs of the respective frequency components according to a Fourier coefficient in the Fourier series expansion. 4. The controller of a power converter according to claim 3, wherein the partial filters each comprises: a phase advance compensator dependent on a thermal time constant; anda gain dependent on a thermal resistance, a thermal time constant, and a frequency of each of the partial filters,the gain is set smaller with a smaller thermal resistance, set smaller with a larger thermal time constant, and set smaller with a higher frequency of each of the partial filters. 5. The controller of a power converter according to claim 4, wherein the partial filters each further comprises a low-pass filter having the cutoff frequency dependent on a thermal time constant and a frequency of each of the partial filters, and the cutoff frequency is set lower with a larger thermal time constant, and set lower with a lower frequency of each of the partial filters. 6. The controller of a power converter according to claim 5, wherein a total of gains of the partial filters is used as a gain included in each of the partial filters, andthe low-pass filter included in each of the partial filters uses the cutoff frequency being an average weighted by the gains of the respective partial filters. 7. The controller of a power converter according to claim 3, wherein the pulsation envelope temperature extraction filter extracts the pulsation envelope temperature by combining results of calculations using partial filters of only a primary frequency component among partial filters of respective frequency components extracted by performing the Fourier series expansion on the loss waveform of the semiconductor device. 8. The controller of a power converter according to claim 3, wherein the partial filters each comprises: a gain dependent on a thermal resistance, a thermal time constant, and a pulsation frequency;a low-pass filter having a cutoff frequency dependent on a thermal time constant; anda secondary filter having a natural frequency dependent on a thermal time constant and a pulsation frequency,the gain is set smaller with a smaller thermal resistance, set smaller with a larger thermal time constant, and set smaller with a higher pulsation frequency,the cutoff frequency is set lower with a larger thermal time constant, andthe natural frequency is set lower with a larger thermal time constant, and set lower with a lower pulsation frequency. 9. The controller of a power converter according to claim 1, wherein in an inverter including a plurality of semiconductor devices, when a thermal network and an average loss is able to be regarded as being common to all of the semiconductor devices, a temperature estimated for an arbitrarily selected semiconductor device is set as a temperature of a semiconductor device having the highest temperature among the plurality of semiconductor devices. 10. The controller of a power converter according to claim 1, wherein in an inverter including a plurality of semiconductor devices, a temperature estimated for a semiconductor device arbitrarily selected from among semiconductor devices having a common thermal network and average loss is set as a temperature of the semiconductor devices having the common thermal network and average loss, andthe controller carries out estimation calculations for the number of semiconductor devices different in at least one of a thermal network and an average loss to thereby obtain the temperature of the semiconductor device having the highest temperature among the plurality of semiconductor devices included in the inverter. 11. The controller of a power converter according to claim 1, wherein the partial temperature variation estimation part further comprises a limiter configured to output a pulsation envelope temperature extracted by the pulsation envelope temperature extraction filter while setting a predetermined limit value. 12. The controller of a power converter according to claim 11, wherein the limiter comprises a upper limiter configured to output the pulsation envelope temperature in a limited manner by setting an upper limit value,the upper limit value is obtained as an output variation amount of the pulsation envelope temperature when the pulsation frequency is zero, by using the average loss and a value of the pulsation envelope temperature in the last calculation period, andthe value of the pulsation envelope temperature in the last calculation period is sequentially updated by a value outputted from the upper limiter. 13. The controller of a power converter according to claim 11, wherein the limiter comprises a lower limiter configured to output the pulsation envelope temperature in a limited manner by setting a lower limit value,the lower limit value is obtained as an output variation amount of the pulsation envelope temperature corresponding to a phase in which temperature is maximized when the average loss decreases, by using the average loss and the value of the pulsation envelope temperature in the last calculation period, andthe value of the pulsation envelope temperature in the last calculation period is sequentially updated by a value outputted from the lower limiter. 14. The controller of a power converter according to claim 13, wherein the limiter further comprises a upper limiter configured to output the pulsation envelope temperature in a limited manner by setting an upper limit value,the upper limit value is obtained as an output variation amount of the pulsation envelope temperature when the pulsation frequency is zero, by using the average loss and the value of the pulsation envelope temperature in the last calculation period, andthe value of the pulsation envelope temperature in the last calculation period is sequentially updated by a value outputted from the upper limiter. 15. A controller of a power converter comprising: average loss calculation means for calculating an average loss in a semiconductor device in a period of carrying out an estimation calculation of a temperature of the semiconductor device; andpartial temperature variation estimation means for, while regarding the semiconductor device as a thermal network including at least one combination of a thermal resistance and a thermal time constant, estimating a partial temperature variation of the combination from a loss in the semiconductor device and the combination of the thermal resistance and the thermal time constant, whereinthe partial temperature variation estimation means comprises: average temperature estimation means for estimating an average temperature from the loss, the thermal resistance, and the thermal time constant; andpulsation envelope temperature extraction filter means for extracting, by use of the thermal resistance, the thermal time constant, and a pulsation frequency of the loss, a pulsation envelope temperature exceeding the maximum value of a pulsation temperature dependent on the average loss and the pulsation frequency, andthe partial temperature variation estimation means estimates a temperature variation in the semiconductor device by adding the average temperature and the pulsation envelope temperature.