Extended Sliding Mode Disturbance Observer-Based Sensorless Control of IPMSM for Medium and High-Speed Range Considering Railway Application

Woldegiorgis, Abebe Teklu; Ge, Xinglai; Li, Songtao; Hassan, Mannan

doi:10.1109/access.2019.2957274

Cited by 37 publications

(21 citation statements)

References 43 publications

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“…The augmented model defined in (13) is obtained by placing (10) and (12) together in matrix form [32]:…”

Section: Conventional Gpcmentioning

confidence: 99%

“…A high error in the angular position estimation produces a high torque ripple that may lead to motor drive malfunctions [6]. Many sensorless techniques were proposed to estimate the angular position without using position sensors [7][8][9][10]. However, most sensorless techniques depend on motor parameters whose values cannot be measured accurately.…”

Section: Introductionmentioning

confidence: 99%

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Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

2021

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High-performance motor drives that operate in harsh conditions require an accurate and robust angular position measurement to correctly estimate the speed and reduce the torque ripple produced by angular estimation error. For that reason, a resolver is used in motor drives as a position sensor due to its robustness. A resolver-to-digital converter (RDC) is an observer used to get the angular position from the resolver signals. Most RDCs are based on angle tracking observers (ATOs). On the other hand, generalized predictive control (GPC) has become a powerful tool in developing controllers and observers for industrial applications. However, no GPC-based RDC with zero steady-state error during constant speed operation has been proposed. This paper proposes an RDC based on the second-order difference GPC (SOD-GPC). In SOD-GPC, the second-order difference operator is applied to design a GPC model with two embedded integrators. Thus, the SOD-GPC is used to design a type-II ATO whose steady-state angle estimation error tends to zero during constant speed operation. Simulation and experimental results prove that the proposed RDC system has better performance than other literature approaches.

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“…The augmented model defined in (13) is obtained by placing (10) and (12) together in matrix form [32]:…”

Section: Conventional Gpcmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

2021

View full text Add to dashboard Cite

show abstract

“…For each ATO configuration, two tests were performed: without adding noise to the resolver outputs, and adding a noise (zero mean and 0.0002 variance) to the resolver outputs. Figures 9,10,11, 12 and 13 show the angle estimation error for each simulation test. Table 3 shows the root mean square error (RMSE) and the error settling time (the time required for the error signal to achieve its steady-state value) for each simulation test.…”

Section: Parameters Valuesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

Estrabis¹,

Gentil²,

Cordero³

2021

Preprint

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High-performance motor drives that operate in harsh conditions require an accurate and robust angular position measurement to correctly estimate the speed and reduce the torque ripple produced by angular estimation error. For that reason, a resolver is used in motor drives as a position sensor due to its robustness. A resolver-to-digital converter (RDC) is an observer used to get the angular position from the resolver signals. Most RDCs are based on angle tracking observers (ATOs). On the other hand, generalized predictive control (GPC) has become a powerful tool in developing controllers and observers for industrial applications. However, no GPC-based RDC with zero steady-state error during constant speed operation was proposed. This paper proposes an RDC based on a second-order difference GPC (SOD-GPC). In SOD-GPC, the second-order difference operator is applied to design a GPC model with two embedded integrators. Thus, the SOD-GPC is used to design a type-II ATO whose steady-state angle estimation error tends to zero during constant speed operation. Simulation and experimental results prove that the proposed RDC system has better performance than other literature approaches.

show abstract

“…The first is that the HF current is extracted by a constant bandwidth BPF, and a LPF is necessary to filter the noise in speed information, which will cause phase lag and decrease the dynamic performance, and this is not the best for wider speed range. [15], [16]. Mostly, the dead-time effect, which will cause the position error fluctuation in both the position error and the speed error [17], [18] is tackled as a problem in pulsating signal injection method as well.…”

Section: Introductionmentioning

confidence: 99%

Dual Quasi-Resonant Controller Position Observer Based on High Frequency Pulse Voltage Injection Method

Mao

et al. 2020

IEEE Access

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This paper proposed a dual quasi-resonant controller position observer for conventional pulsating high frequency voltage injection method. The proposed position observer can not only improve the dynamic performance of the sensorless control, but can also compensate the position error fluctuation caused by the dead-time effect. To improve the dynamic performance, the digital bandpass filter in the traditional position observer used to extract high frequency current response is replaced by a quasi-resonant controller firstly. Moreover, an improved Luenberger observer without lowpass filter, which is usually used in traditional position observer to filter the noise in speed information, is adopted in the new position observer. Therefore, dynamic performances can be improved. Then, to reduce the sixth harmonic in the magnitude of position error and speed error caused by the dead-time effect, a frequency adaptive quasi-resonant controller is connected in parallel with the proportional-integral controller in the Luenberger observer. The experiment results verify that the proposed observer can reduce the position estimation error not only in steady state operation conditions, but in variable speed and variable load conditions, and the speed variation range can be widened as well.

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Extended Sliding Mode Disturbance Observer-Based Sensorless Control of IPMSM for Medium and High-Speed Range Considering Railway Application

Cited by 37 publications

References 43 publications

Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

Development of a Resolver-to-Digital Converter Based on Second-Order Difference Generalized Predictive Control

Dual Quasi-Resonant Controller Position Observer Based on High Frequency Pulse Voltage Injection Method

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