Parameter learning for permanent magnet synchronous motor drives

文档序号:1660160 发布日期:2019-12-27 浏览:25次 中文

阅读说明:本技术 永磁同步马达驱动器的参数学习 (Parameter learning for permanent magnet synchronous motor drives ) 是由 N·E·吉金斯基 P·普拉莫德 J·A·克莱瑙 于 2019-06-20 设计创作,主要内容包括:描述了用于估计永磁同步马达(PMSM)驱动器的机器参数的技术方案。示例方法包括基于马达速度值和马达电流值确定用于估计机器参数的区域。该方法还包括:响应于在该区域中的马达速度值和马达电流值,估计在估计的电压指令中的误差,并使用在估计的电压指令中的该误差估计机器参数。(Technical solutions for estimating machine parameters of a Permanent Magnet Synchronous Motor (PMSM) drive are described. An example method includes determining a region for estimating a machine parameter based on a motor speed value and a motor current value. The method further comprises the following steps: an error in the estimated voltage command is estimated in response to the motor speed value and the motor current value in the region, and a machine parameter is estimated using the error in the estimated voltage command.)

1. A method of estimating machine parameters of a Permanent Magnet Synchronous Motor (PMSM) drive, the method comprising:

determining a region for estimating a machine parameter based on the motor speed value and the motor current value; and

in response to the motor speed value and the motor current value in the region:

estimating an error in the estimated voltage command; and

estimating a machine parameter using the error in the estimated voltage command.

2. The method of claim 1, wherein the machine parameter is a circuit resistance of the PMSM driver.

3. The method of claim 1, wherein the machine parameter is a back electromotive force constant of the PMSM.

4. The method of claim 1, wherein estimating the machine parameter using the error in the estimated voltage command comprises using a closed loop calculation.

5. The method of claim 4, wherein the closed loop calculation calculates an error in the machine parameter, and the error in the machine parameter is combined with the machine parameter estimated using a temperature model.

6. The method of claim 1, wherein estimating the machine parameter using the error in the estimated voltage command comprises using an open loop calculation.

7. The method of claim 2, wherein the region for estimating resistance is when a motor speed value is less than or equal to a first threshold and when a motor current value is greater than or equal to a second threshold.

8. A method according to claim 3, wherein the region for estimating back emf is when a motor speed value is greater than or equal to a first threshold and when a motor current value is less than or equal to a second threshold.

9. A system, comprising:

a motor;

a motor control system that operates the motor using feedback control; and

a machine parameter learning system configured to estimate machine parameters of a motor control system, the estimation of the machine parameters including:

determining a region for estimating a machine parameter based on the motor speed value and the motor current value; and

in response to the motor speed value and the motor current value in the region:

estimating an error in the estimated voltage command; and

estimating a machine parameter using the error in the estimated voltage command.

10. The system of claim 9, wherein the machine parameter is resistance.

11. The system of claim 10, wherein the region for estimating resistance is when a motor speed value is less than or equal to a first threshold and when a motor current value is greater than or equal to a second threshold.

12. The system of claim 9, wherein the machine parameter is back electromotive force.

13. The system of claim 12, wherein the region for estimating back electromotive force is when a motor speed value is greater than or equal to a first threshold and when a motor current value is less than or equal to a second threshold.

14. The system of claim 9, wherein estimating a machine parameter using the error in the estimated voltage command comprises using one of a closed loop calculation and an open loop calculation.

15. A steering system, comprising:

a Permanent Magnet Synchronous Motor (PMSM) driver;

a current command generator that generates a motor current command of the PMSM driver corresponding to the input torque command; and

a parameter learning system configured to estimate machine parameters of a PMSM driver, the estimation of the machine parameters including:

determining a region for estimating a machine parameter based on the motor speed value and the motor current value; and

in response to the motor speed value and the motor current value in the region:

estimating an error in the estimated voltage command; and

estimating a machine parameter using the error in the estimated voltage command.

16. The steering system of claim 15, wherein the machine parameter is resistance.

17. The steering system of claim 16, wherein the region for estimating resistance is when a motor speed value is less than or equal to a first threshold and when a motor current value is greater than or equal to a second threshold.

18. The steering system of claim 15, wherein the machine parameter is back electromotive force.

19. The steering system of claim 18, wherein the region for estimating back electromotive force is when a motor speed value is greater than or equal to a first threshold and when a motor current value is less than or equal to a second threshold.

20. The steering system of claim 15, wherein estimating a machine parameter using the error in the estimated voltage command includes using one of a closed loop calculation and an open loop calculation.

Technical Field

The present application relates generally to Permanent Magnet Synchronous Motor (PMSM) drives, and more particularly to those used in systems such as Electric Power Steering (EPS) systems.

Background

In general, a motion control system such as an EPS generates torque using an electric drive system. For example, in the case of EPS, an electric drive is used to provide the driver with assistance for steering the vehicle. In one or more examples, an electric drive system employs a torque-controlled PMSM to provide assistance torque to a driver. The torque control of the PMSM is performed indirectly by adjusting the motor current. Current control of the motor current is performed using a feedback control architecture with measured current in a synchronous rotating reference frame using Field Oriented Control (FOC) theory. Feedback control generally has good steady-state tracking performance, dynamic response, high bandwidth, and satisfactory interference suppression, and thus, feedback current control is the most widely used technique in the industry to control a multiphase ac motor.

Machine parameter estimates, such as back-emf constants and motor circuit resistances, are used to determine an optimal current command given a torque command, machine speed, and DC link voltage. Furthermore, in some cases, the current regulator gain is designed as a direct function of the estimated machine parameters to achieve satisfactory dynamic response characteristics of the motor torque and current control system. Machine parameters are also used in motor control systems for several other functions including signal observers, stability enhancement functions, etc. Machine parameters vary greatly throughout the operating region of the PMSM drive system and throughout the life of the EPS system.

Disclosure of Invention

Technical solutions for estimating machine parameters of a Permanent Magnet Synchronous Motor (PMSM) drive are described. An example method includes determining a region for estimating a machine parameter based on a motor speed value and a motor current value. The method further comprises the following steps: an error in the estimated voltage command is estimated in response to the motor speed value and the motor current value in the region, and a machine parameter is estimated using the error in the estimated voltage command.

According to one or more embodiments, a system includes a motor, a motor control system that operates the motor using feedback control, and a machine parameter learning system that estimates machine parameters of the motor control system. The estimating of the machine parameter includes determining a region for estimating the machine parameter based on the motor speed value and the motor current value. The estimating further comprises: an error in the estimated voltage command is estimated in response to the motor speed value and the motor current value in the region, and a machine parameter is estimated using the error in the estimated voltage command.

In accordance with one or more embodiments, a steering system includes a Permanent Magnet Synchronous Motor (PMSM) driver and a current command generator that generates a motor current command for the PMSM driver corresponding to an input torque command. The steering system also includes a parameter learning system that estimates machine parameters of the PMSM driver. The estimating of the machine parameter includes determining a region for estimating the machine parameter based on the motor speed value and the motor current value. The estimating further comprises: an error in the estimated voltage command is estimated in response to the motor speed value and the motor current value in the region, and a machine parameter is estimated using the error in the estimated voltage command.

These and other advantages and features will become more apparent from the following description taken in conjunction with the accompanying drawings.

Drawings

The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other features and advantages of the invention will be apparent from the following detailed description taken in conjunction with the accompanying drawings, in which:

FIG. 1 is an exemplary embodiment of an electric power steering system according to one or more embodiments.

FIG. 2 depicts a block diagram of a motor control system with online parameter learning in accordance with one or more embodiments;

FIG. 3 provides a visual representation in a torque speed plane for a region of learning parameters;

FIGS. 4A and 4B depict a flowchart of an example method for determining regions to learn/estimate machine parameters in accordance with one or more embodiments;

FIG. 5 depicts a block diagram of a parameter learning module in accordance with one or more embodiments; and

FIG. 6 depicts a block diagram of an operational flow of estimating or learning machine parameters according to one or more embodiments.

Detailed Description

As used herein, the terms module and sub-module refer to one or more processing circuits (e.g., an Application Specific Integrated Circuit (ASIC), an electronic circuit, a processor (shared, dedicated, or group) and memory that execute one or more software or firmware programs, a combinational logic circuit, and/or other suitable components that provide the described functionality.

It should be noted that various features described herein facilitate improving a motor control system. The description herein uses an electric power steering system (EPS) as an example of using a motor control system that is improved using and/or implementing various features described herein. However, the solution described herein is not limited to electric power steering systems, but is applicable to any other system such as industrial motors, biomechanical devices, automated driving assistance systems or any other electric machine using a motor control system.

Reference will now be made to the drawings in which the technical solutions will be described with reference to specific embodiments, without limiting the technical solutions. FIG. 1 is an exemplary embodiment of an electric power steering system (EPS)40 suitable for practicing the disclosed embodiments. The steering mechanism 36 is a rack-and-pinion type system, and includes a rack (not shown) located within the housing 50 and a pinion (also not shown) located below the gear housing 52. As an operator input (hereinafter, indicated as turning the steering wheel 26 (e.g., a hand-held steering wheel, etc.)), the upper steering shaft 29 turns, and the lower steering shaft 51 connected to the upper steering shaft 29 through the universal joint 34 turns the pinion. Rotation of the pinion gear moves the rack, which moves tie rods 38 (only one shown) which in turn moves knuckles 39 (only one shown), which knuckles 39 turn steerable wheels or tires 44 (only one shown).

Electric power assisted steering assistance is provided by a control arrangement generally indicated by reference numeral 24 and comprising the controller 16 and an electric machine 19, the electric machine 19 comprising a permanent magnet synchronous motor and hereinafter indicated as motor 19. The controller 16 is powered by the vehicle power supply 10 via line 12. The controller 16 receives a vehicle speed signal 14 from a vehicle speed sensor 17 indicative of the vehicle speed. The steering angle is measured by a position sensor 32 (the position sensor 32 may beAn optically encoded sensor, a variable resistance sensor, or any other suitable type of position sensor) and provides a position signal 20 to the controller 16. The motor speed may be measured using a tachometer or any other device and transmitted as a motor speed signal 21 to the controller 16. Can be represented by omegamIs measured, calculated, or a combination of both. For example, motor speed ωmCan be calculated as a change in motor position theta measured by the position sensor 32 over a specified time interval. For example, it can be according to equation ωmDividing motor speed ω by Δ θ/Δ tmIs determined as the derivative of the motor position, θ, where Δ t is the sample time and Δ θ is the change in position during the sample interval. Alternatively, the motor speed may be derived from the motor position as a time rate of change of position. It should be appreciated that there are many well known methods for performing the derivative function.

When the steering wheel 26 is turned, the torque sensor 28 senses the torque applied to the steering wheel 26 by the vehicle operator. The torque sensor 28 may include a torsion bar (not shown) and a variable resistance type sensor (also not shown) that outputs a variable torque signal 18 to the controller 16 relative to the amount of torsion on the torsion bar. Although this is a torque sensor, any other suitable torque sensing device used with known signal processing techniques may be used. In response to various inputs, the controller sends commands 22 to the electric motor 19, and the electric motor 19 provides torque assistance to the steering system via the worm 47 and worm gear 48, thereby providing torque assistance for vehicle steering.

It should be noted that although the disclosed embodiments are described by way of reference to motor control for electric power steering applications, it should be understood that these references are merely illustrative and that the disclosed embodiments may be applied to any motor control application that employs an electric motor, such as steering, valve control, and the like. Further, the references and descriptions herein are applicable to many forms of parameter sensors, including but not limited to torque, position, velocity, and the like. It should also be noted that references herein to an electric machine include, but are not limited to, a motor, which will be referred to below in a non-limiting context for the sake of brevity and simplicity.

In the control system 24 as shown, the controller 16 uses torque, position, speed, etc. to calculate a command to deliver the desired output power. The controller 16 is provided in communication with various systems and sensors of the motor control system. The controller 16 receives signals from each of the system sensors, quantifies the received information, and provides output command signals in response thereto, in this example, to the motor 19, for example. The controller 16 is configured to generate a corresponding voltage from an inverter (not shown, may optionally be combined with the controller 16 and referred to herein as the controller 16) such that when applied to the motor 19, a desired torque or position is generated. In one or more examples, controller 24 operates in a feedback control mode as a current regulator to generate instructions 22. Alternatively, in one or more examples, controller 24 operates in a feed forward control mode to generate instructions 22. Since these voltages are related to the position and speed of the motor 19 and the desired torque, the position and/or speed of the rotor and the torque applied by the driver are determined. The position encoder is connected to the steering shaft 51 to detect the angular position θ. The encoder may sense the rotational position based on optical detection, magnetic field changes, or other methods. Typical position sensors include potentiometers, resolvers, synchronizers, encoders, and the like, as well as combinations comprising at least one of the foregoing. The position encoder outputs a position signal 20, which position signal 20 is indicative of the angular position of the steering shaft 51, and thus of the motor 19.

The desired torque may be determined by one or more torque sensors 28, with the torque sensors 28 transmitting torque signals 18 indicative of the applied torque. One or more exemplary embodiments include such a torque sensor 28 and the torque signal 18 derived from such a torque sensor 28, as they may be responsive to a flexible torsion bar, a T-bar, a spring, or similar device (not shown) configured to provide a response indicative of the applied torque.

In one or more examples, the temperature sensor 23 is located at the motor 19. Preferably, the temperature sensor 23 is configured to directly measure the temperature of the sensing portion of the motor 19. The temperature sensor 23 transmits a temperature signal 25 to the controller 16 to facilitate the processing and compensation specified herein. Typical temperature sensors include thermocouples, thermistors, thermostats, and the like, as well as combinations comprising at least one of the foregoing sensors, which when properly placed, provide a calibratable signal proportional to a particular temperature.

The position signal 20, the speed signal 21, the torque signal 18, and the like are applied to the controller 16. The controller 16 processes all of the input signals to generate values corresponding to each of these signals to generate rotor position values, motor speed values, and torque values that may be used for processing in the algorithms specified herein. Measurement signals such as those mentioned above are also typically linearized, compensated, and filtered as necessary to enhance the characteristics of the acquired signal or to eliminate undesirable characteristics. For example, the signal may be linearized to increase processing speed or to handle a large signal dynamic range. In addition, frequency or time based compensation and filtering may be employed to eliminate noise or avoid undesirable spectral characteristics.

To perform the prescribed functions and desired processing, and the calculations that result therefrom (e.g., identification of motor parameters, control algorithms, etc.), the controller 16 can include, but is not limited to, a processor, a computer, a DSP, a memory, a storage device, registers, timing, interrupts, communication interfaces, and input/output signal interfaces, among others, as well as combinations comprising at least one of the foregoing. For example, the controller 16 may include input signal processing and filtering to enable accurate sampling and conversion of or acquisition of such signals from the communication interface. Additional features of the controller 16 and some of the processes are discussed in detail later herein.

As previously mentioned, estimation of machine parameters such as back emf constants and motor circuit resistance are critical to the operation of torque and current control of the PMSM. The parameter estimation is used to determine an optimal current command given the torque command, machine speed, and DC link voltage. Furthermore, in some cases, the current regulator gain is designed as a direct function of the estimated machine parameters to achieve satisfactory dynamic response characteristics of the motor torque and current control system. Machine parameters are also used in motor control systems for several other functions including signal observers, stability enhancement functions, etc. Machine parameters vary greatly throughout the operating region of the PMSM drive system and throughout the life of the EPS system. Therefore, accurate estimation of machine parameters is crucial for optimal functioning of the PMSM drive system.

Typically, machine parameters are estimated using a feed forward approach that involves the use of a model of parameter variation. Specifically, a temperature change model with estimated temperatures of the magnets, windings, and inverter switches is used to estimate the machine back emf or torque constant, as well as the motor circuit resistance. The magnetic saturation model is also used to account for variations in magnet strength with load.

The solution described herein provides an online learning technique for PMSM parameters during feedback current control operation, thereby addressing the technical challenges of estimating PMSM parameters during feedback control. In one or more examples, the solutions described herein estimate PMSM parameters by using final and estimated voltage commands as inputs to different learning algorithms to estimate machine parameters, particularly to estimate back emf constants and motor circuit resistances.

FIG. 2 depicts a block diagram of a motor control system with online parameter learning in accordance with one or more embodiments. The system 100 includes a torque control system 110 for the PMSM 19. The torque control system 110 may also be referred to as a current control system of the PMSM 19. The torque control system 110 receives the motor parameter estimates from the parameter estimation system 120. The torque control system 110 also receives a desired output torque generated by the PMSM 19. The torque control system 110 may include a feedforward parameter estimator 130, where the feedforward parameter estimator 130 estimates one or more operating parameters, such as machine resistanceConstant of counter electromotive forceIn d-axisMachine inductanceAnd machine inductance in the q-axisIn one or more examples, the estimate may be based on a temperature (θ) of the machine, the temperature being a value measured or estimated using a sensor. Torque control system 110 also includes a current reference generator 135, which current reference generator 135 determines a current reference that is sent as an input to current regulator 140. The current reference generator 135 calculates the motor current referenceTo generate the desired motor electrical torque while satisfying the voltage limit constraints. The voltage calculation module 145 calculates an estimated voltage value using the motor current reference(s) ((And) The estimated voltage value is forwarded to the parameter estimation system 120. In one or more examples, the calculated voltage value is a feed-forward voltage command value.

The current reference generator 135 receives as inputs the operating conditions including the following parameters: motor speed (omega)m) DC link voltage (V)ecu) And torque command (T)c) And the output of the feedforward parameter estimator 130. The feedforward parameter estimator approximates the machine parameters using a parametric variation model having temperature and magnetic saturation (including, in some cases, a thermal model for predicting part temperature) and a predetermined calibrationThe following steady state machine equation is used to determine the current reference (command) sent to the current regulator 140, where m is a feed forward estimate of the modulation index.

Wherein, when using line-to-line delineation of a machine model,andnote that the wave number in the above equation represents the estimated machine parameter. Solving equation 1 to determine the desired amount of current T to be achievedc. Equations 2-4 determine whether the desired torque can be achieved using the available voltage. If the desired torque command cannot be achieved, the current reference command module 135 solves the reference current such that T is minimizedcAnd a modified torque command. Equations 1-4 represent the model of the machine when using the estimated parameters, while equations 5-7 below are the actual machine characteristics (including dynamics), where N ispIs the number of poles of the PMSM motor 19.

Te=cKeIq+crNp(Ld-Lq)IqId...(5)

Wherein the content of the first and second substances,Teis the actual electromagnetic torque, IdAnd IqIs the actual machine current, Ke,R,Ld,LqAre the actual machine parameters. According to one or more embodiments described herein, the estimated machine inductance is assumed to be accurate, and online determination or learning of motor circuit resistance and back-emf voltage (or torque) constants is performed using the estimated machine inductance. At steady state and low frequency transient behavior (where the derivative of the two currents is approximately zero, i.e.) Meanwhile, due to the presence of the high bandwidth feedback regulator 140, it can be assumed thatThe current regulator 140 is a multiple-input multiple-output PI based control scheme that ensures that a reference current is tracked, and in one or more examples, the reference current is substantially equal to the actual measured value. The relationship between actual and commanded electromagnetic torques with actual and estimated machine parameters is shown in equation 8 below.

Using equations 6-7 and 2-3, the relationship between the estimated and actual parameters from the final and feed-forward q-axis voltage commands can be expressed as follows.

In view of the above assumptions, and based on equation 9, the resistance estimation error has a linear relationship with the error observed in the q-axis voltage. This can also be said for a constant error in back emf voltage (or torque). By using the error in voltage, the proposed invention converges on accurate estimated parameters through an open-loop or closed-loop learning scheme.

The open-loop learning scheme is a computationally-based approach to account for inaccuracies in the feed-forward parameter estimation. Equation 10, simplified with assumptions made for the inductance estimate, is as follows:

based on equation 10, it can be determined when the motor parameter estimates are independent of each other. For example, when the motor 19 approaches a stall conditionThe following equation holds.

Equation 10 above may be rearranged, written as:

when the current through the motor is sufficiently low, i.e.ThenThis leads to the following equation.

Referring to FIG. 2, the parameter estimation system 120 includes a parameter learning module 122 in accordance with one or more embodiments. In one or more examples, parameter learning module 122 uses parameter learning described herein and converges to an accurate feed forward parameter estimate based on equations 11 and 13. It should be noted that the parameter learning module 122 may be used in different examples, such as in embodiments where parameter learning is performed in an open-loop manner. The feedforward parameter estimator 130 uses the learned parameter values Δ R and Δ KeTo obtain a final parameter estimate. The parameter estimation system 120 further includes parametericsA learning region determining module 124, the parameter learning region determining module 124 determining when to learn each parameter based on the conditions for deriving both equation 11 and equation 13. In the embodiments described herein, the parameter learning region determination module 124 uses a commanded or reference current value, but it should be noted that in other embodiments, actual motor current measurements may be used.

FIG. 3 provides a visual representation in a torque speed plane for a region of learning parameters. Area 310 indicates whenThe state of time, and can be used to learn the machine resistance using equation 11. Region 320 represents a state when the torque command is small, and thereforeAnd can be used to learn the back electromotive force constant using equation 13. Note that instead of using a torque velocity plane, a current velocity plane may be used. In that case, based on one or more current values (which may be commanded or measured) on the q-axis and/or the d-axis, a region of convergence may be determined.

Fig. 4A and 4B depict a flowchart of an example method for determining a region for learning/estimating machine parameters in accordance with one or more embodiments. These methods may be implemented or performed by the parameter learning enablement module 124. In one or more examples, the methods may be performed by control module 26 as a result of executing computer-executable instructions stored on a computer storage device.

The method helps to determine the convergence region of parameter learning. It should be noted that while some particular embodiments of the learning region are described herein, in other examples, the method may be extended to make the learning algorithm more robust to operating conditions. For example, the rate of change of a variable such as speed or current may be used to determine a rapidly changing operating condition, where learning may be disabled.

As shown in FIG. 4A, the method includes basing the method on motor speed (ω)m) Absolute value of (d) and a reference current in the q-axisTo determine whether to learn the back electromotive force (K)e) Machine parameters. If the motor speed is greater than (or equal to) the first predetermined threshold ωm1(based on x in FIG. 31) And if the reference q-axis current is less than (or equal to) a second predetermined threshold Iq1(based on y in FIG. 31) The method initiates a counter electromotive force (K) at 432, 434, and 436e) And (4) learning machine parameters. If either condition is not satisfied, the back electromotive force learning is not started.

Further, as shown in FIG. 4B, the method includes basing the method on the motor speed ωmAbsolute value of (d) and reference q-axis currentTo determine whether to learn a machine circuit resistance (R) machine parameter. If the motor speed is less than (or equal to) the third predetermined threshold ωm2(based on x in FIG. 32) And if the reference q-axis current is greater than (or equal to) a fourth predetermined threshold Iq2(based on y in FIG. 32) The method initiates learning the resistance (R) parameter at 442, 444, and 446. If the condition is not satisfied, resistance learning is not initiated.

In one or more examples, the parameter learning enablement module 124 provides two flags, one indicating whether back emf constant learning is enabled and the other indicating whether resistance learning is enabled. The value of the flag is set according to the method described above, with the flag set to TRUE at 436 and 446, and set to FALSE otherwise. In other examples, the parameter learning initiation is indicated in any other manner, such as sending a control signal, etc.

The flags are provided to a parameter learning module 122, and the parameter learning module 122 estimates machine parameter values based on the corresponding flag states.

FIG. 5 depicts a block diagram of a parameter learning module in accordance with one or more embodiments. FIG. 5 also depicts an operational flow of a method for learning parameter values in accordance with one or more embodiments. The method may be implemented or performed by the parameter learning module 122. In one or more examples, the method may be performed as a result of executing computer-executable instructions stored on a computer storage device.

The parameter learning module 122 includes a resistance learning module 510 and a back emf learning module 520. It should be noted that in other examples, the parameter learning module 122 may include other components or different components than those described herein to perform closed-loop parameter learning.

The closed-loop parameter learning technique utilizes the same convergence region as for the open-loop strategy. Except that a regulator is used to obtain the machine parameter estimation error. Parameter learning module 122 in closed-loop method for feed-forward estimation of q-axis voltageAnd the actual q-axis voltage (V)q) The difference between applies a regulator (including an integrator). This ensures that the estimated machine parameters converge to the actual parameters.

For example, the resistance learning module 510 receives a q-axis voltage (V)q) And estimated q-axis voltageAnd the difference between the two is calculated at 512. This difference represents the error in the q-axis voltage that is fed to the PI controller 515 and processed by the PI controller 515 to calculate the error (Δ R) in the machine resistance value that is used to update/learn/estimate the machine resistance (al;)In one or more examples, PI controller 515 uses a first scaling factor (K) at 514p) The calculated difference is scaled by a scaling factor, which may be a gain factor of PI controller 515. At the same time, another scaling factor (K) is used at 516i) To scale the difference, which may be an adjustment factor of PI controller 515. The scaled differences are summed at 517 and the sum is output as the error in the machine resistance value (Δ R).

It should be noted that the error in the machine circuit resistance value (Δ R) is calculated only when resistance learning is enabled, as indicated by the corresponding flag from the parameter learning enablement module 124.

In a similar manner, if back emf learning is enabled, the back emf learning module 520 calculates the error in back emf as indicated by the corresponding flag from the parameter learning initiation module 124.

The back EMF learning module 520 receives the q-axis voltage (V)q) And estimated q-axis voltageAnd the difference between the two is calculated at 522. This difference represents the error in the q-axis voltage, which is then processed by PI controller 525 to calculate the error in the back emf value (Δ K)e) The error is used to learn and update the estimated back EMF valueIn one or more examples, PI controller 525 uses a first scaling factor (K) at 524p) The calculated difference is scaled by a scaling factor, which may be a gain factor of PI controller 525. At the same time, another scaling factor (K) is used at 526i) To scale the difference, which may be an adjustment factor of PI controller 525. The scaled differences are summed 527 and the sum is taken as the error in the back emf value (ak)e) And (6) outputting.

Both the resistance learning module 510 and the back emf learning module 520 use closed loop operation to drive the respective errors (Δ R and Δ Ke) to substantially zero. The calculated error value is further combined with a feed forward estimate that may be calculated, for example using a temperature-based model, a magnetic model, or any other technique.

FIG. 6 depicts a block diagram of an operational flow of estimating or learning machine parameters according to one or more embodiments. A closed loop estimate of the error in the machine parameter is used to calculate the machine parameter value. In the depicted example, the back electromotive force constant (Δ K) is based on the estimatione) The calculated machine parameter is the back-emf constantIt should be understood that a similar configuration may be used for any other machine parameter to be calculated, such as estimated motor circuit resistance

As described herein, an error in the estimated back emf constant is calculated (e.g., fig. 5). Calculating machine parameters includes using nominal values, such as nominal back-emf constant 710 and thermal coefficient 720, etc., and temperature estimate 730, etc. Note that the thermal coefficient is a thermal coefficient of the thermosensitive material of the calculated parameter (for example, a temperature coefficient of resistivity of copper of the motor resistance). At 750, the difference in the nominal temperature 740 is multiplied by the temperature estimate 730, the thermal coefficient 720, and the sum of the errors in the nominal back emf value 710 and the estimated back emf constant. The nominal temperature 740 is the temperature at which the magnet thermal coefficient 720 is determined. At 760, the result of the multiplication is added to the sum of the nominal back emf constant value 710 and the estimation error, which is output as the back emf constant at 770.

Similar configurations and structures may be used to calculate the motor circuit resistance (R), and the structure is not repeated here.

Accordingly, the techniques described herein facilitate calculating a final machine resistance estimated using one or more embodiments described herein in conjunction with existing feed forward parameter estimation.

The solution described herein facilitates closed-loop and open-loop parameter learning techniques that address the technical challenges of parameter variations between components and over time. Some other advantages provided by the solutions described herein include reduced motor control development time for vehicles, part specific bar code labeling and line end time and cost savings of tools. As described herein, estimation of machine parameters is critical to the operation of torque and current control of the PMSM, particularly in the case of a steering system.

While the subject matter has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the subject matter is not limited to such disclosed embodiments. Rather, the technical solution can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the technical solution. Additionally, while various embodiments of the technology have been described, it is to be understood that aspects of the technology may include only some of the described embodiments. Accordingly, the technical solutions should not be considered as being limited by the foregoing description.

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