JP6757494B2 - Motor control device - Google Patents

Description

The present invention relates to a motor control device for driving an electric motor by PWM (Pulse Width Modulation).

In a motor control device that vector-controls a three-phase electric motor, a two-phase current command value is calculated for each current control cycle. The two-phase voltage command value is calculated based on the deviation between the two-phase current command value and the two-phase current detection value. By converting this two-phase voltage command value into two-phase and three-phase using the rotation angle of the electric motor, the U-phase, V-phase, and W-phase phase voltage command values (three-phase voltage command values) are calculated. .. Then, a U-phase PWM signal, a V-phase PWM signal, and a W-phase PWM signal having a duty corresponding to the phase voltage command values of the U-phase, V-phase, and W-phase are generated and supplied to the three-phase inverter circuit.

By controlling the power elements constituting this inverter circuit by the U-phase PWM signal, the V-phase PWM signal, and the W-phase PWM signal, a voltage corresponding to the three-phase voltage command value is applied to the electric motor. .. As a result, the motor current flowing through the electric motor is controlled to be equal to the two-phase current command value.

Japanese Unexamined Patent Publication No. 1-50766

In a motor control device that vector-controls a three-phase electric motor, if the PWM signal frequency (PWM frequency) is increased, the motor voltage can be applied appropriately even in a system with a high motor rotation speed (rotation speed), and the motor can be smoothly applied. It becomes possible to rotate.
However, when the PWM frequency is increased, the PWM signal cycle (PWM cycle) may be smaller than the current control cycle. When the PWM cycle becomes smaller than the current control cycle, a plurality of PWM cycles are included in the current control cycle. When the rotation speed of the electric motor increases, the rotation angle of the electric motor changes significantly within the current control cycle, and the voltage applied to the electric motor deviates from the two-phase voltage command value. Then, the motor current flowing through the electric motor deviates from the two-phase current command value, and the controllability deteriorates.

An object of the present invention is to provide a motor control device capable of applying a voltage corresponding to a two-phase voltage command value to an electric motor with high accuracy even when the electric motor is driven at high speed.

The invention according to claim 1 includes a plurality of PWM cycles in the current control cycle, and the electric motor (18) is controlled based on a PWM signal generated in each PWM cycle in the current control cycle. A control device, a two-phase voltage command value generating means (42) that generates a two-phase voltage command value in a two-phase rotation coordinate system for each current control cycle, and the electric motor for each PWM cycle in the current control cycle. The motor rotation angle estimation means (51) for individually estimating the rotation angle of the motor and the two-phase voltage command value generated by the two-phase voltage command value generation means for a certain current control cycle are used for the motor rotation angle estimation means. By performing two-phase / three-phase conversion using the rotation angle of the electric motor for each PWM cycle in the current control cycle estimated by, the three-phase fixed coordinate system for each PWM cycle in the current control cycle The three-phase voltage command value calculation means (45) for calculating the phase voltage command value and the PWM maximum count number corresponding to the PWM frequency were set as the PWM maximum count number of the actual resolution, and the PWM maximum count number of the actual resolution was predeterminedly multiplied. Assuming that the maximum PWM count is the maximum high-resolution PWM count, the three-phase voltage command value of each PWM cycle within the current control cycle calculated by the three-phase voltage command value calculation means and the high-resolution PWM maximum count. It was calculated by the high-resolution PWM count calculation means (61) for calculating the high-resolution PWM count of each of the three phases for each PWM cycle in the current control cycle, and the high-resolution PWM count calculation means. Final PWM count generation means (62) that generates the final PWM count of each of the three phases for each PWM cycle based on the high resolution PWM count of each of the three phases for each PWM cycle in the current control cycle. ) and viewing including the said final PWM count generating means, when the PWM maximum count ratio resolution ratio of the high resolution for PWM maximum count number of the actual resolution, which is calculated by the high-resolution PWM count calculating means By dividing the high-resolution PWM count of each of the three phases for each PWM cycle in the current control cycle by the resolution ratio and truncating after the decimal point, each of the three phases for each PWM cycle in the current control cycle The actual resolution PWM count calculation means (63) for calculating the actual resolution PWM count of the phase and the total value of the high resolution PWM count for each PWM cycle in the current control cycle for each of the three phases are calculated by the resolution ratio. Divide and after the decimal point The difference calculation means (64) for calculating the difference between the value obtained by truncating the value and the total value of the actual resolution PWM count for each PWM cycle in the current control cycle, and the difference calculation means for each of the three phases. A difference distribution means that generates the final PWM count of each of the three phases for each PWM cycle by distributing the obtained difference to the actual resolution PWM count for each PWM cycle in the current control cycle. 65) is a motor control device including . The alphanumeric characters in parentheses represent the corresponding components and the like in the embodiments described later, but of course, the scope of the present invention is not limited to the embodiments. The same shall apply hereinafter in this section.

In this configuration, the rotation angle of the electric motor for each PWM cycle in the current control cycle is estimated individually, and the two-phase voltage command value for the current control cycle is set to the rotation of the electric motor for each PWM cycle in the current control cycle. The three-phase voltage command value for each PWM cycle in the current control cycle is calculated by performing two-phase / three-phase conversion using the angle estimated value. Then, since the final PWM count of each phase is calculated using the three-phase voltage command value for each PWM cycle, the voltage corresponding to the two-phase voltage command value can be obtained even when the electric motor is driven at high speed. It will be possible to apply it to an electric motor with high accuracy.

Further, in this configuration, the three-phase voltage command value of each PWM cycle in the current control cycle and the high resolution PWM maximum count number larger than the actual resolution PWM maximum count number are used, and each in the current control cycle is used. The high-resolution PWM count of each phase with respect to the PWM cycle is calculated, and the final PWM count according to the actual resolution is generated from this high-resolution PWM count. Therefore, since the final PWM count that reflects the high-resolution PWM count can be obtained, even when the electric motor is driven at high speed, the voltage corresponding to the two-phase voltage command value can be applied to the electric motor with higher accuracy. It becomes possible to apply.

In the invention according to claim 2 , the difference distribution means sets the resolution ratio to the actual resolution PWM count among the actual resolution PWM counts for each PWM cycle in the current control cycle for each of the three phases. a multiplier values, is configured to distribute preferentially the difference from what the difference between the high-resolution PWM count corresponding to the PWM period is large, a motor control device according to claim 1.

In the invention according to claim 3 , assuming that the number of the PWM cycles included in the current control cycle is N, the high resolution PWM maximum count is a value obtained by multiplying the actual resolution PWM maximum count by N. The motor control device according to claim 1 or 2 .

FIG. 1 is a schematic view showing a schematic configuration of an electric power steering device according to an embodiment of the present invention. FIG. 2 is a block diagram showing an electrical configuration of the ECU. FIG. 3 is a schematic diagram illustrating the configuration of the electric motor. FIG. 4 is a schematic diagram showing the relationship between the PWM signal cycle Tc and the current control cycle Ta. FIG. 5 is a graph showing a setting example of the assist current value Ia ^{* with} respect to the detected steering torque T. FIG. 6 is a block diagram showing a configuration of a PWM duty calculation unit. FIG. 7A is a table showing specific examples such as the first PWM count Ci'of the U phase for 10 PWM cycles calculated by the first PWM count calculation unit, and FIG. 7B is calculated by the second PWM count calculation unit 63. It is a table which shows the specific example of the 10th 2nd PWM count Ci and the like, and FIG. 7C is a table which shows the specific example of the U phase PWM count Cfi for each PWM cycle after the difference distribution. FIG. 8 shows the difference (Ci'-Ci) between the values Ci · N obtained by multiplying the second PWM count Ci of the U phase for each PWM cycle by the resolution ratio N and the first PWM count Ci'of the U phase corresponding to the PWM cycle. -It is a table showing a specific example of N).

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a schematic view showing a schematic configuration of an electric power steering device to which the motor control device according to the embodiment of the present invention is applied.
The electric power steering device (EPS) 1 is a steering wheel 2 as a steering member for steering a vehicle, and a steering mechanism that steers the steering wheel 3 in conjunction with the rotation of the steering wheel 2. 4 and a steering assist mechanism 5 for assisting the steering of the driver are provided. The steering wheel 2 and the steering mechanism 4 are mechanically connected via a steering shaft 6 and an intermediate shaft 7.

The steering shaft 6 includes an input shaft 8 connected to the steering wheel 2 and an output shaft 9 connected to the intermediate shaft 7. The input shaft 8 and the output shaft 9 are rotatably connected to each other via a torsion bar 10.
A torque sensor 11 is arranged in the vicinity of the torsion bar 10. The torque sensor 11 detects the steering torque T applied to the steering wheel 2 based on the relative rotational displacement amounts of the input shaft 8 and the output shaft 9. In this embodiment, the steering torque T detected by the torque sensor 11 is, for example, the torque for steering to the right is detected as a positive value, and the torque for steering to the left is a negative value. It is assumed that the larger the absolute value is detected, the larger the steering torque is.

The steering mechanism 4 includes a rack and pinion mechanism including a pinion shaft 13 and a rack shaft 14 as a steering shaft. A steering wheel 3 is connected to each end of the rack shaft 14 via a tie rod 15 and a knuckle arm (not shown). The pinion shaft 13 is connected to the intermediate shaft 7. The pinion shaft 13 rotates in conjunction with the steering of the steering wheel 2. A pinion 16 is connected to the tip (lower end in FIG. 1) of the pinion shaft 13.

The rack shaft 14 extends linearly along the left-right direction of the automobile. A rack 17 that meshes with the pinion 16 is formed in the middle portion of the rack shaft 14 in the axial direction. The pinion 16 and the rack 17 convert the rotation of the pinion shaft 13 into an axial movement of the rack shaft 14. The steering wheel 3 can be steered by moving the rack shaft 14 in the axial direction.

When the steering wheel 2 is steered (rotated), this rotation is transmitted to the pinion shaft 13 via the steering shaft 6 and the intermediate shaft 7. Then, the rotation of the pinion shaft 13 is converted into the axial movement of the rack shaft 14 by the pinion 16 and the rack 17. As a result, the steering wheel 3 is steered.
The steering assist mechanism 5 includes an electric motor 18 for steering assistance and a deceleration mechanism 19 for transmitting the output torque of the electric motor 18 to the steering mechanism 4. The electric motor 18 is provided with a rotation angle sensor 23 including, for example, a resolver for detecting the rotation angle of the rotor of the electric motor 18. The speed reduction mechanism 19 includes a worm shaft 20 and a worm gear mechanism including a worm wheel 21 that meshes with the worm shaft 20.

The worm shaft 20 is rotationally driven by the electric motor 18. Further, the worm wheel 21 is integrally rotatably connected to the steering shaft 6. The worm wheel 21 is rotationally driven by the worm shaft 20.
When the worm shaft 20 is rotationally driven by the electric motor 18, the worm wheel 21 is rotationally driven and the steering shaft 6 is rotated. Then, the rotation of the steering shaft 6 is transmitted to the pinion shaft 13 via the intermediate shaft 7. The rotation of the pinion shaft 13 is converted into the axial movement of the rack shaft 14. As a result, the steering wheel 3 is steered. That is, the steering wheel 3 is steered by rotationally driving the worm shaft 20 by the electric motor 18.

The vehicle is provided with a vehicle speed sensor 24 for detecting the vehicle speed V. The steering torque T detected by the torque sensor 11, the vehicle speed V detected by the vehicle speed sensor 24, the output signal of the rotation angle sensor 23, and the like are input to the ECU (Electronic Control Unit) 12. The ECU 12 controls the electric motor 18 based on these input signals.

FIG. 2 is a block diagram showing an electrical configuration of the ECU 12.
The ECU 12 includes a microcomputer 31 and a drive circuit (inverter circuit) 32 that is controlled by the microcomputer 31 and supplies electric power to the electric motor 18. Two current sensors 33 and 34 are provided on the power supply line for connecting the drive circuit 32 and the electric motor 18. These current sensors 33 and 34 are provided so as to be able to detect the phase current flowing through two of the three power supply lines for connecting the drive circuit 32 and the electric motor 18. ..

The electric motor 18 is, for example, a three-phase brushless motor, and includes a rotor 100 as a field and stator windings 101, 102, 103 of U-phase, V-phase, and W-phase, as shown graphically in FIG. It includes a stator 105.
Three-phase fixed coordinates (UVW coordinate system) are defined with the U-axis, V-axis, and W-axis in the directions of the stator windings 101, 102, and 103 of each phase. A two-phase rotating coordinate system (dq coordinate system) in which the d-axis (pole axis) is taken in the magnetic pole direction of the rotor 100 and the q-axis (torque axis) is taken in the direction perpendicular to the d-axis in the rotation plane of the rotor 100. Real rotating coordinate system) is defined. In the dq coordinate system, only the q-axis current contributes to the torque generation of the rotor 100. Therefore, the d-axis current may be set to zero and the q-axis current may be controlled according to a desired torque. The rotation angle (electrical angle) θ of the rotor 100 is the rotation angle of the d-axis with respect to the U-axis. The dq coordinate system is an actual rotating coordinate system that follows the rotor rotation angle θ. By using this rotor rotation angle θ, coordinate conversion between the UVW coordinate system and the dq coordinate system can be performed.

Returning to FIG. 2, the microcomputer 31 includes a CPU and a memory (ROM, RAM, non-volatile memory, etc.), and functions as a plurality of functional processing units by executing a predetermined program. .. The plurality of function processing units include an assist current value setting unit 41, a current command value setting unit 42, a current deviation calculation unit 43, a PI (proportional integration) control unit 44, and a two-phase / three-phase conversion unit 45. , PWM duty calculation unit (PWM Duty calculation unit) 46, PWM output unit 47, three-phase / two-phase conversion unit 48, rotation angle calculation unit 49, rotation speed calculation unit 50, and rotation angle estimation unit 51. And are included.

As shown in FIG. 4, the PWM signal cycle (hereinafter, referred to as “PWM cycle”) Tc is smaller than the current control cycle Ta. In this embodiment, Tc is 1/10 of Ta. In other words, the PWM cycle Tc for 10 cycles is included in the current control cycle Ta. The first cycle of the PWM cycle Tc for 10 cycles may be referred to as the 0th cycle, and the subsequent cycles may be referred to as the 1, 2, ... 8, 9th cycles. Further, the cycle number of the PWM cycle may be represented by i (i = 0, 1, 2, ..., 9). The number of current control cycle Ta included in the current control cycle Ta is represented by N. In this embodiment, N = 10.

The number of PWM clocks corresponding to the PWM cycle Tc is called the actual resolution PWM maximum count number Cmax. For example, when the number of PWM clocks of the computer is 100 [MHz] and the frequency of the PWM signal (hereinafter referred to as “PWM frequency”) is 100 [kHz], the maximum PWM count number Cmax of the actual resolution is 100,000,000 × (1 / 100,000) = 1000. The resolution of the voltage applied to the electric motor 18 (stepped width of applied voltage; hereinafter referred to as "voltage resolution Vr") is Vr = Vb, where Cmax is the maximum PWM count and Vb is the power supply voltage of the drive circuit 32. It is represented by ÷ Cmax. Therefore, the actual voltage resolution Vr is Vb / 1000 [V / LSB]. The smaller the value of the voltage resolution Vr, the finer the step size of the applied voltage and the higher the voltage resolution. In other words, the larger the value of the voltage resolution Vr, the coarser the step size of the applied voltage and the lower the voltage resolution.

In the following, a value obtained by multiplying the actual resolution PWM maximum count number Cmax by a predetermined value may be referred to as a high resolution PWM maximum count number Cmax'. In this embodiment, the value obtained by multiplying the actual resolution PWM maximum count number Cmax by N (N is the number of PWM cycle Tc included in the current control cycle Ta) is defined as the high resolution PWM maximum count number Cmax'. To do. Therefore, in this embodiment, the ratio of the high resolution PWM maximum count number Cmax'to the actual resolution PWM maximum count number Cmax (resolution ratio: Cmax'/ Cmax) is N. In this embodiment, the resolution ratio (Cmax'/ Cmax) is treated as N.

Returning to FIG. 2, the rotation angle calculation unit 49 calculates the rotation angle θ (electric angle) of the rotor of the electric motor 18 for each current control cycle Ta based on the output signal of the rotation angle sensor 23. The rotor rotation angle θ calculated by the rotation angle calculation unit 49 is given to the three-phase / two-phase conversion unit 48, the rotation speed calculation unit 50, and the rotation angle estimation unit 51. In this embodiment, the timing at which the rotor rotation angle θ is acquired (detected) is the same as the timing at which two phase currents of the motor phase currents (I _U , _IV , I _W ) are detected. To do.

The rotation speed calculation unit 50 calculates the rotation speed ω of the rotor of the electric motor 18 by time-differentiating the rotor rotation angle θ calculated by the rotation angle calculation unit 48. The rotation speed ω calculated by the rotation speed calculation unit 50 is given to the rotation angle estimation unit 51.
The rotation angle estimation unit 51 estimates the rotor rotation angle θi (θ0 to θ9) at the start of each PWM cycle Tc included in the next current control cycle Ta based on the following equation (1).

θ0 = θ + ω ・ Ta
θ1 = θ0 + ω ・ Tc
θ2 = θ1 + ω ・ Tc
...
θ8 = θ7 + ω ・ Tc
θ9 = θ8 + ω ・ Tc… (1)
The rotor rotation angle θi (θ0 to θ9) estimated by the rotation angle estimation unit 51 is given to the two-phase / three-phase conversion unit 45.

The assist current value setting unit 41 sets the assist current value Ia ^* for each current control cycle Ta based on the detected steering torque T detected by the torque sensor 11 and the vehicle speed V detected by the vehicle speed sensor 24. An example of setting the assist current value Ia ^{* with} respect to the detected steering torque T is shown in FIG. As for the detected steering torque T, for example, the torque for steering to the right is taken to a positive value, and the torque for steering to the left is taken to a negative value. Further, the assist current value Ia ^* is set to a positive value when the steering assist force for rightward steering should be generated from the electric motor 18, and the steering assist force for leftward steering should be generated from the electric motor 18. Sometimes it is a negative value. The assist current value Ia ^* takes a positive value with respect to a positive value of the detected steering torque T and takes a negative value with respect to a negative value of the detected steering torque T.

When the detected steering torque T is a minute value in the range of −T1 to T1 (for example, T1 = 0.4 N ・ m) (torque dead zone), the assist current value Ia ^* is set to zero. When the detected steering torque T is a value outside the range of −T1 to T1, the assist current value Ia ^* is set so that the larger the absolute value of the detected steering torque T, the larger the absolute value. To torque. Further, the assist current value Ia ^* is set so that the larger the vehicle speed V detected by the vehicle speed sensor 24, the smaller the absolute value thereof. As a result, the steering assist force is increased during low-speed travel, and the steering assist force is decreased during high-speed travel.

The current command value setting unit 42 sets the current value to be passed through the coordinate axes of the dq coordinate system as the current command value based on the assist current value Ia ^* set by the assist current value setting unit 41. Specifically, the current command value setting unit 42 refers to the d-axis current command value I _d ^* and the q-axis current command value I _q ^* (hereinafter, collectively referred to as “two-phase current command value I _dq ^* ”. ) Is set. More specifically, the current command value setting unit 42 sets the q-axis current command value I _q ^* to the assist current value Ia ^* set by the assist current value setting unit 41, while the d-axis current command value I _d. ^{Let *} be zero. The two-phase current command value I _dq ^* set by the current command value setting unit 42 is given to the current deviation calculation unit 43.

First, the three-phase / two-phase converter 48 uses the two-phase currents detected by the current sensors 33 and 34 to determine the U-phase current I _U , the V-phase current _IV, and the W-phase current I _W (hereinafter, these). When generically referred to, "three-phase detection current I _UVW ") is calculated. Then, the three-phase / two-phase conversion unit 48 uses the three-phase detection current I _UVW of the _UVW coordinate system as the two-phase detection currents I _d and I _q of the dq coordinate system (hereinafter collectively referred to as “two-phase detection current I _dq ”. ) Is converted into coordinates. For this coordinate conversion, the rotor rotation angle θ calculated by the rotation angle calculation unit 49 is used.

The current deviation calculation unit 43 calculates the deviation of the d-axis detection current I _d with respect to the d-axis current command value I _d ^* and the deviation of the q-axis detection current I _q with respect to the q-axis current command value I _q ^* . These deviations are given to the PI control unit 44.
The PI control unit 44 performs a PI calculation on the current deviation calculated by the current deviation calculation unit 43, thereby performing a two-phase voltage command value V _dq ^* (d-axis voltage command value V _d ^*) to be applied to the electric motor 18. The q-axis voltage command value V _q ^* ) is generated. This two-phase voltage command value V _dq ^* is given to the two-phase / three-phase conversion unit 45.

The two-phase / three-phase conversion unit 45 stores the rotation angle estimation values θ0 to θ9 for the next current control cycle Ta given by the rotation angle estimation unit 51 over a plurality of current control cycles. The two-phase / three-phase conversion unit 45 receives the two-phase voltage command value V _dq ^* calculated by the PI control unit 44 in the current current control cycle Ta by the rotation angle estimation unit 51 in the previous current control cycle Ta. By performing two-phase / three-phase conversion using the calculated rotation angle estimated values θ0 to θ9, respectively, the three-phase voltage command value V _UVW ^* for each PWM cycle Tc included in the current control cycle Ta is calculated. To do. The three-phase voltage command value V _UVW ^* consists of a U-phase voltage command value V _U ^* , a V-phase voltage command value V _V ^*, and a W-phase voltage command value V _W ^* . As a result, the three-phase voltage command value V _UVW ^* for each PWM cycle Tc included in the current control cycle Ta can be obtained.

The three-phase voltage command value V _UVW ^* for each PWM cycle Tc included in the current current control cycle Ta obtained by the two-phase / three-phase conversion unit 45 is given to the PWM duty calculation unit 46.
The PWM duty calculation unit 46 determines the U-phase PWM count (PWM duty) and V-phase for each PWM cycle Tc based on the three-phase voltage command value V _UVW ^* for each PWM cycle Tc included in the current control cycle Ta. A PWM count and a W-phase PWM count are generated and given to the PWM output unit 47. Details of the operation of the PWM duty calculation unit 46 will be described later.

The PWM output unit 47 outputs a U-phase PWM signal, a V-phase PWM signal, and a W-phase PWM signal having a duty corresponding to the U-phase PWM count, the V-phase PWM count, and the W-phase PWM count for each PWM cycle Tc. Generate and supply to the drive circuit 32.
The drive circuit 32 includes a three-phase inverter circuit corresponding to U-phase, V-phase, and W-phase. By controlling the power element constituting this inverter circuit by the PWM signal given from the PWM output unit 47, the voltage corresponding to the three-phase voltage command value V _UVW ^* for each PWM cycle Tc is generated in each phase of the electric motor 18. It will be applied to the stator windings 101, 102, 103.

The current deviation calculation unit 43 and the PI control unit 44 constitute a current feedback control means. By the action of this current feedback control means, the motor current flowing through the electric motor 18 is controlled so as to approach the two-phase current command value I _dq ^* set by the current command value setting unit 42.
Hereinafter, the operation of the PWM duty calculation unit 46 will be described in detail.

FIG. 6 is a block diagram showing the configuration of the PWM duty calculation unit 46.
The PWM duty calculation unit 46 includes a first PWM count calculation unit (high resolution PWM count calculation means) 61 and a final PWM count generation unit 62. The PWM duty calculation unit 46 calculates the PWM count of the U phase, the PWM count of the V phase, and the PWM count of the W phase for each PWM cycle Tc, but the calculation method of the PWM count of each phase is the same. , Only the method of calculating the U-phase PWM count will be described.

The first PWM count calculation unit 61 uses the U-phase voltage command value V _U ^* for each PWM cycle in the current control cycle obtained by the two-phase three-phase conversion unit 45 and the high-resolution PWM maximum count number Cmax'. Then, the U-phase high-resolution PWM count (hereinafter referred to as "first PWM count Ci'") is calculated for each PWM cycle in the current control cycle.
The first PWM count Ci'of the U phase for a certain PWM cycle is calculated based on the following equation (2), where V _U ^* is the U phase voltage command value for the PWM cycle.

Ci'= V _U ^* × (Cmax'/ Vb)
= V _U ^* × (10,000 / Vb)… (2)
In the above equation (2), Vb is the power supply voltage of the drive circuit 32.
In order to facilitate understanding, FIG. 7A shows a specific example of the U-phase first PWM count Ci'for 10 PWM cycles (cycle numbers 0 to 9) calculated by the first PWM count calculation unit 61. ..

The final PWM count generation unit 62 is a U for each PWM cycle in the current control cycle based on the first PWM count Ci'of the U phase for each PWM cycle in the current control cycle calculated by the first PWM count calculation unit 61. The final PWM count of the phase (hereinafter referred to as "final PWM count Cfi") is generated. The final PWM count generation unit 62 includes a second PWM count calculation unit (actual resolution PWM count calculation means) 63, a difference calculation unit 64, and a difference distribution unit 65.

The second PWM count calculation unit 63 divides the U-phase first PWM count Ci'for each PWM cycle in the current control cycle calculated by the first PWM count calculation unit 61 by the resolution ratio (Cmax'/ Cmax = N). , The actual resolution PWM count of the U phase (hereinafter referred to as "second PWM count Ci") for each PWM cycle in the current control cycle is calculated by truncating the part after the decimal point.

Assuming that the first PWM count of the U phase for a certain PWM cycle is Ci', the second PWM count Ci of the U phase for the PWM cycle is calculated based on the following equation (3). However, the numbers after the decimal point are truncated.
Ci = Ci'÷ N… (3)
When the ten first PWM counts Ci'calculated by the first PWM count calculation unit 61 are shown in FIG. 7A, the ten second PWM counts Ci calculated by the second PWM count calculation unit 63 are shown in FIG. 7B. Will be.

The difference calculation unit 64 will be described. Let ΣCi' be the total value of the first PWM count Ci'of the U phase for each PWM cycle in the current control cycle calculated by the first PWM count calculation unit 61. The total value ΣCi'is divided by the resolution ratio N, and the value rounded down to the nearest whole number is defined as ΣCi'/ N. Let ΣCi be the total value of the second PWM count Ci of the U phase for each PWM cycle in the current control cycle calculated by the second PWM count calculation unit 63. The difference calculation unit 64 calculates the difference (ΣCi'/ N-ΣCi) between ΣCi'/ N and ΣCi.

In the examples of FIGS. 7A and 7B, the total value ΣCi'of the 10 first PWM counts Ci'is 51432, which is divided by the resolution ratio (N in this embodiment), and the value rounded down to the nearest whole number is 5143. Become. Further, the total value ΣCi of the 10 second PWM counts Ci is 5138. Therefore, these differences (ΣCi'/ N-ΣCi) are 5.
The difference distribution unit 65 distributes the difference calculated by the difference calculation unit 64 to the second PWM count Ci of the U phase calculated by the second PWM count calculation unit 63. For example, the difference distribution unit 65 is a value Ci obtained by multiplying the second PWM count by the resolution ratio N of the U-phase second PWM count Ci for each PWM cycle in the current control cycle calculated by the second PWM count calculation unit 63. -The difference is preferentially distributed from the one having the largest difference between N and the first PWM count Ci'corresponding to the PWM cycle.

In the examples of FIGS. 7A and 7B, the difference between the values Ci · N obtained by multiplying the second PWM count Ci of the U phase for each PWM cycle by the resolution ratio N and the first PWM count Ci'of the U phase corresponding to the PWM cycle. (Ci'-Ci · N) is as shown in FIG. From FIG. 8, among the 0th to 9th PWM cycles, the upper 5 cycles having a large difference (Ci'-Ci · N) are the 0, 1, 3, 5 and 8th cycles. Therefore, in the second PWM count Ci of FIG. 7B, 1 is added to each of the second PWM count Ci of the 0th, 1st, 3rd, 5th, and 8th cycles. As a result, the U-phase PWM count (final U-phase PWM count) Cfi for each PWM cycle after the difference distribution is as shown in FIG. 7C. The total value of Cfi, ΣCfi, is 5143, which is the same value as ΣCi'/ N. That is, when the difference (Ci'-Ci · N) and the difference (Ci'-Cfi · N) are compared in each PWM cycle, the difference (Ci'-Cfi · N) is compared with the difference (Ci'-Ci · N). N) is smaller, and Cfi / N can reflect Ci'more than Ci / N, which means that the three-phase voltage command value can be reflected more.

In the above embodiment, the rotor rotation angle θi for each PWM cycle in the current control cycle is estimated, and the two-phase voltage command value V _dq ^* is converted into two-phase / three-phase using the rotor rotation angle estimated value θi for each PWM cycle. By doing so, the three-phase voltage command value V _UVW ^* for each PWM cycle is calculated. Then, since the PWM count (PWM duty) of each phase is calculated using the three-phase voltage command value V _UVW ^* for each PWM cycle, the two-phase voltage command value V is calculated even when the electric motor is driven at high speed. It becomes possible to apply a voltage corresponding to _dq ^* to the electric motor with high accuracy.

Further, in the above-described embodiment, each PWM cycle is used by using a high-resolution PWM maximum count Cmax'which is larger than the actual resolution PWM maximum count Cmax and a three-phase voltage command value V _UVW ^* for each PWM cycle. The high-resolution PWM count (first PWM count Ci') of each phase is calculated with respect to the above, and the final PWM count Cfi according to the actual resolution is generated from the first PWM count. Therefore, since the final PWM count reflecting the high-resolution PWM count Ci'can be obtained, the voltage corresponding to the two-phase voltage command value V _dq ^* is higher even when the electric motor is driven at high speed. It will be possible to apply it to the electric motor with high accuracy.

In the above-described embodiment, 10 PWM cycles Tc are included in the current control cycle Ta, but the number of PWM cycles Tc included in the current control cycle Ta may be any number as long as it is 2 or more. ..
In the above-described embodiment, the difference distribution unit 65 sets the resolution ratio N to the second PWM count of the U-phase second PWM count Ci for each PWM cycle in the current control cycle calculated by the second PWM count calculation unit 63. The difference is preferentially distributed from the one having the largest difference between the multiplied values Ci · N and the first PWM count Ci ′ corresponding to the PWM cycle. However, the difference distribution unit 65 may distribute the U-phase second PWM count Ci and the difference on average for each PWM cycle in the current control cycle calculated by the second PWM count calculation unit 63. Further, the difference distribution unit 65 concentrates the difference on the second PWM count of a part of the U-phase second PWM count Ci for each PWM cycle in the current control cycle calculated by the second PWM count calculation unit 63. It may be distributed.

Further, in the above embodiment, the final PWM count generation unit 62 is composed of the second PWM count calculation unit 63, the difference calculation unit 64, and the difference distribution unit 65, but the final PWM count generation unit 62 is the first PWM count. The high-resolution PWM count Ci'of each phase for each PWM cycle in the current control cycle calculated by the calculation unit 61 is divided by the resolution ratio and rounded off to the nearest whole number, so that each PWM cycle in the current control cycle is rounded off. It may be configured to generate the final PWM count for each phase with respect to.

Further, in the above embodiment, the value obtained by multiplying the actual resolution PWM maximum count number Cmax by N (N is the number of PWM cycle Tc included in the current control cycle Ta) is defined as the high resolution PWM maximum count number Cmax'. Although it is set, the high resolution is obtained by multiplying the actual resolution PWM maximum count number Cmax by a predetermined number (a value larger than 1) different from the number N of the PWM cycle Tc included in the current control cycle Ta. It may be set as the PWM maximum count number Cmax'of.

In the above embodiment, the case where the present invention is applied to the motor control device of the electric power steering device has been described, but the present invention can also be applied to the motor control device used other than the electric power steering device.
In addition, various design changes can be made within the scope of the matters described in the claims.

12 ... ECU, 18 ... Electric power steering device, 32 ... Drive circuit, 45 ... Two-phase / three-phase conversion unit, 46 ... PWM duty calculation unit, 50 ... Motor rotation speed calculation unit, 51 ... Rotation angle estimation unit, 61 ... 1st PWM count calculation unit, 62 ... final PWM count generation unit, 63 ... 2nd PWM count calculation unit, 64 ... difference calculation unit, 65 ... difference distribution unit

Claims (3)

A motor control device in which a plurality of PWM cycles are included in the current control cycle, and the electric motor is controlled based on a PWM signal generated in each PWM cycle in the current control cycle.
A two-phase voltage command value generating means that generates a two-phase voltage command value in a two-phase rotating coordinate system for each current control cycle,
A motor rotation angle estimating means for individually estimating the rotation angle of the electric motor for each PWM cycle in the current control cycle, and
The two-phase voltage command value generated by the two-phase voltage command value generating means for a certain current control cycle is used by the electric motor for each PWM cycle within the current control cycle estimated by the motor rotation angle estimating means. A three-phase voltage command value calculation means that calculates a three-phase voltage command value of a three-phase fixed coordinate system for each PWM cycle in the current control cycle by performing two-phase / three-phase conversion using the rotation angle.
Assuming that the maximum PWM count number corresponding to the PWM frequency is the PWM maximum count number of the actual resolution and the PWM maximum count number obtained by multiplying the PWM maximum count number of the actual resolution by a predetermined value is the PWM maximum count number of the high resolution, the three-phase voltage Using the three-phase voltage command value of each PWM cycle in the current control cycle calculated by the command value calculation means and the high-resolution PWM maximum count number, each of the three phases for each PWM cycle in the current control cycle. High-resolution PWM count calculation means for calculating the high-resolution PWM count of the phase,
The final PWM of each of the three phases for each PWM cycle is based on the high resolution PWM count of each of the three phases for each PWM cycle in the current control cycle calculated by the high resolution PWM count calculation means. and a final PWM count generator that generates a count seen including,
The final PWM count generation means is
Assuming that the ratio of the high-resolution PWM maximum count to the actual-resolution PWM maximum count is the resolution ratio, each of the three phases for each PWM cycle in the current control cycle calculated by the high-resolution PWM count calculation means. Real-resolution PWM count calculation that calculates the actual-resolution PWM count of each of the three phases for each PWM cycle in the current control cycle by dividing the high-resolution PWM count of the phase by the resolution ratio and rounding down after the decimal point. Means and
For each of the three phases, the total value of the high-resolution PWM count for each PWM cycle in the current control cycle is divided by the resolution ratio, and the value after the decimal point is rounded down and each PWM cycle in the current control cycle. A difference calculation means for calculating the difference from the total value of the actual resolution PWM count with respect to
For each of the three phases, the difference obtained by the difference calculation means is distributed to the actual resolution PWM count for each PWM cycle in the current control cycle, so that each of the three phases for each PWM cycle The motor control device according to the description, which includes a differential distribution means for generating a final PWM count . The difference distribution means calculates the value obtained by multiplying the actual resolution PWM count by the resolution ratio among the actual resolution PWM counts for each PWM cycle in the current control cycle for each of the three phases, and the PWM cycle. corresponding difference between the high-resolution PWM count that is configured to distribute the difference preferentially from those large, the motor control device according to claim 1. According to claim 1 or 2 , assuming that the number of the PWM cycles included in the current control cycle is N, the high-resolution PWM maximum count is a value obtained by multiplying the actual-resolution PWM maximum count by N. The motor control device described.

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