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On Dynamic Modeling of PCM-Controlled Converters - Buck Converter as an Example

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On Dynamic Modeling of PCM-Controlled Converters - Buck Converter as an Example. / Suntio, Teuvo.

In: IEEE Transactions on Power Electronics, Vol. 33, No. 6, 2018.

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Suntio, Teuvo. / On Dynamic Modeling of PCM-Controlled Converters - Buck Converter as an Example. In: IEEE Transactions on Power Electronics. 2018 ; Vol. 33, No. 6.

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@article{592593bc393c42d6b2ccc43ab12ed315,
title = "On Dynamic Modeling of PCM-Controlled Converters - Buck Converter as an Example",
abstract = "Peak-current-mode (PCM) control was published first time in open literature in 1976. The observed peculiar behavior caused by the application of PCM-control in a power electronic converter have fascinated the researchers to attempting to capture the dynamics associated to it. It is commonly assumed that the peculiar phenomena originate from the sampling process in the PCM control. A resistor is usually connected as a load, when modeling the converter dynamics and during the frequencyresponse measurements. The load resistor will actually dominate the frequency responses and hide the real dynamics associated to PCM control. Other measurement problems will arise from the non-modeled circuit elements dominating, especially, the highfrequency dynamic behavior of the converters. Because of these problems, the PCM models are not usually properly validated. The investigations, in this paper, show that: i) the PCM models have to be accurate also at the low frequencies for ensuring, for example, stable design of output-current-feedback-controlled converters, ii) the high low-frequency accuracy can be obtained only by means of duty-ratio gain becoming infinite at the mode limit, iii) the highfrequency accuracy of the PCM models can be obtained by means of different high-frequency extensions, iv) the key for the PCM modeling lies in the proper duty-ratio constraints, and v) the highfrequency magnitude and phase behaviors are caused by the second-harmonic-mode operation of the converter due to the frequency-response-measurement injection signal. The main objective of this paper is to show that such a modeling technique, which fully matches the above criteria, has been developed already in early 1990's and later elaborated for more general form. Validation of the dynamic models is performed by simulation, where the converter and its operational environment are perfectly known. The load-resistor effect is removed computationally for performing the complete validation. A PCM-controlled buck converter is used as an example.",
keywords = "Control systems, duty-ratio constraints, dynamic modeling, Frequency conversion, Frequency measurement, harmonicmode operation, Integrated circuit modeling, Load modeling, PCM control, Phase change materials, Switching frequency",
author = "Teuvo Suntio",
year = "2018",
doi = "10.1109/TPEL.2017.2737679",
language = "English",
volume = "33",
journal = "IEEE Transactions on Power Electronics",
issn = "0885-8993",
publisher = "Institute of Electrical and Electronics Engineers",
number = "6",

}

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TY - JOUR

T1 - On Dynamic Modeling of PCM-Controlled Converters - Buck Converter as an Example

AU - Suntio, Teuvo

PY - 2018

Y1 - 2018

N2 - Peak-current-mode (PCM) control was published first time in open literature in 1976. The observed peculiar behavior caused by the application of PCM-control in a power electronic converter have fascinated the researchers to attempting to capture the dynamics associated to it. It is commonly assumed that the peculiar phenomena originate from the sampling process in the PCM control. A resistor is usually connected as a load, when modeling the converter dynamics and during the frequencyresponse measurements. The load resistor will actually dominate the frequency responses and hide the real dynamics associated to PCM control. Other measurement problems will arise from the non-modeled circuit elements dominating, especially, the highfrequency dynamic behavior of the converters. Because of these problems, the PCM models are not usually properly validated. The investigations, in this paper, show that: i) the PCM models have to be accurate also at the low frequencies for ensuring, for example, stable design of output-current-feedback-controlled converters, ii) the high low-frequency accuracy can be obtained only by means of duty-ratio gain becoming infinite at the mode limit, iii) the highfrequency accuracy of the PCM models can be obtained by means of different high-frequency extensions, iv) the key for the PCM modeling lies in the proper duty-ratio constraints, and v) the highfrequency magnitude and phase behaviors are caused by the second-harmonic-mode operation of the converter due to the frequency-response-measurement injection signal. The main objective of this paper is to show that such a modeling technique, which fully matches the above criteria, has been developed already in early 1990's and later elaborated for more general form. Validation of the dynamic models is performed by simulation, where the converter and its operational environment are perfectly known. The load-resistor effect is removed computationally for performing the complete validation. A PCM-controlled buck converter is used as an example.

AB - Peak-current-mode (PCM) control was published first time in open literature in 1976. The observed peculiar behavior caused by the application of PCM-control in a power electronic converter have fascinated the researchers to attempting to capture the dynamics associated to it. It is commonly assumed that the peculiar phenomena originate from the sampling process in the PCM control. A resistor is usually connected as a load, when modeling the converter dynamics and during the frequencyresponse measurements. The load resistor will actually dominate the frequency responses and hide the real dynamics associated to PCM control. Other measurement problems will arise from the non-modeled circuit elements dominating, especially, the highfrequency dynamic behavior of the converters. Because of these problems, the PCM models are not usually properly validated. The investigations, in this paper, show that: i) the PCM models have to be accurate also at the low frequencies for ensuring, for example, stable design of output-current-feedback-controlled converters, ii) the high low-frequency accuracy can be obtained only by means of duty-ratio gain becoming infinite at the mode limit, iii) the highfrequency accuracy of the PCM models can be obtained by means of different high-frequency extensions, iv) the key for the PCM modeling lies in the proper duty-ratio constraints, and v) the highfrequency magnitude and phase behaviors are caused by the second-harmonic-mode operation of the converter due to the frequency-response-measurement injection signal. The main objective of this paper is to show that such a modeling technique, which fully matches the above criteria, has been developed already in early 1990's and later elaborated for more general form. Validation of the dynamic models is performed by simulation, where the converter and its operational environment are perfectly known. The load-resistor effect is removed computationally for performing the complete validation. A PCM-controlled buck converter is used as an example.

KW - Control systems

KW - duty-ratio constraints

KW - dynamic modeling

KW - Frequency conversion

KW - Frequency measurement

KW - harmonicmode operation

KW - Integrated circuit modeling

KW - Load modeling

KW - PCM control

KW - Phase change materials

KW - Switching frequency

U2 - 10.1109/TPEL.2017.2737679

DO - 10.1109/TPEL.2017.2737679

M3 - Article

VL - 33

JO - IEEE Transactions on Power Electronics

JF - IEEE Transactions on Power Electronics

SN - 0885-8993

IS - 6

ER -