JP7187878B2 - Electric motor control device and control method for vehicle - Google Patents

Description

The present disclosure relates to technology for controlling an electric motor in a vehicle equipped with the electric motor.

A technology is known that includes a microcontroller as a control unit that controls an actuator and a microcontroller monitoring unit as a monitoring unit that monitors the occurrence of an abnormality in the microcontroller, and executes fail-safe when an abnormality occurs inside the microcontroller. (For example, Patent Document 1).

JP 2016-147585 A

However, in the above technique, no consideration is given to fail-safe execution when redundant signals do not match. In general, if the redundancy signals do not match, a fail-safe is implemented and actuator operation is stopped. For example, in a vehicle equipped with an electric motor, if the fail-safe is executed due to a mismatch of redundancy signals, the vehicle stops and the vehicle cannot run for evacuation.

Therefore, in a vehicle in which the drive motor is controlled using the redundant signal, it is desired to enable limp-running even when the redundant signal does not match.

The present disclosure can be implemented as the following aspects.

A first aspect provides a control device for an electric motor in a vehicle. A control device for an electric motor in a vehicle according to a first aspect includes a detection signal determination unit that determines a high vehicle speed detection signal indicating a high vehicle speed among a plurality of detection signals input from a vehicle speed detection unit; a monitoring unit for determining a monitored target torque using a vehicle speed detection signal; a first control unit for determining a target torque as an output target of the electric motor using the determined high vehicle speed detection signal; and the target torque . and a fail-safe determination unit that determines execution of fail-safe for the electric motor using the monitored target torque .

According to the electric motor control device for a vehicle according to the first aspect, in a vehicle in which the control of the electric motor for driving is executed using the redundancy signal, the evacuation running is possible even when the redundancy signal does not match. can be

A second aspect provides a method for controlling an electric motor in a vehicle. A method for controlling an electric motor in a vehicle according to a second aspect determines a high vehicle speed detection signal indicating a high vehicle speed among a plurality of detection signals input from a vehicle speed detection unit, and uses the determined high vehicle speed detection signal. using the determined high vehicle speed detection signal to determine a target torque as an output target of the electric motor; and using the target torque and the monitoring target torque to provide a fail-safe for the electric motor. determining the execution of

According to the method for controlling an electric motor in a vehicle according to the second aspect, in a vehicle in which control of the electric motor for driving is executed using the redundancy signal, evacuation running is possible even when the redundancy signal does not match. can be The present disclosure can also be implemented as a control program for an electric motor in a vehicle or a computer-readable recording medium that records the program.

1 is an explanatory diagram showing an example of a vehicle equipped with the electric motor control device according to the first embodiment; FIG. 1 is a block diagram showing the functional configuration of a motor control device according to a first embodiment; FIG. FIG. 2 is a block diagram showing the functional configuration of a vehicle control unit according to the first embodiment; FIG. 3 is a block diagram showing the functional configuration of a monitoring unit according to the first embodiment; FIG. 4 is a flowchart showing a processing flow of detection signal determination processing executed by a detection signal determination unit according to the first embodiment; 4 is a flowchart showing a processing flow of target torque calculation processing executed by a vehicle control unit in the first embodiment; 4 is a flowchart showing a processing flow of monitoring processing executed by a monitoring unit according to the first embodiment; FIG. 4 is an explanatory diagram showing an example of a demand torque map used for determining demand torque; FIG. 4 is an explanatory diagram showing an example of a monitoring request torque map used for determining monitoring request torque; FIG. Explanatory drawing which shows an example of the map used in order to determine a detection threshold value. Explanatory drawing which shows an example of the map used in order to determine detection time. Explanatory drawing which shows the characteristic of the electric motor generator regarding an accelerator opening and a torque.

A control device for an electric motor in a vehicle and a method for controlling an electric motor in a vehicle according to the present disclosure will be described below based on several embodiments.

First embodiment:
As shown in FIG. 1, an electric motor control device 100 for a vehicle according to the first embodiment is mounted on a vehicle 50 and used. The control device 100 includes a vehicle control section 10 as a first control section, a monitoring section 20 and a motor-generator control section 40 as a second control section. Note that the motor-generator control unit 40 may not be included in the control device 100 . Vehicle 50 further includes motor generator 41 , accelerator opening sensor 31 , vehicle speed sensor 32 , shift position sensor 33 and running mode switch 34 . A vehicle 50 in the first embodiment is an electric vehicle having a motor generator 41 as a drive source. The motor-generator 41 is, for example, an AC three-phase motor controlled by an inverter included in the motor-generator control unit 40, and can function as a motor or a generator. It should be noted that the embodiments in this specification, including the first embodiment, are not limited to electric vehicles equipped with a motor-generator, but are series hybrids equipped with an electric motor operated by electric power generated by an internal combustion engine and electric power from a battery as a drive source. It can be applied to an electric vehicle provided with an electric motor in place of the motor generator 41 . Note that the vehicle 50 does not have a transmission, and the output torque of the electric motor-generator 41 with respect to the accelerator opening is in a monotonous proportional relationship.

The accelerator opening sensor 31 is a sensor that detects the amount of depression of the accelerator pedal as an opening, that is, a rotation angle, and the detected accelerator opening Acc is output as an accelerator opening signal.

The vehicle speed sensor 32 is a vehicle speed detection unit that detects the rotational speed of the wheels 51 and can be provided for each wheel 51 . The vehicle speed signal indicating the vehicle speed V output from the vehicle speed sensor 32 is a pulse wave indicating a voltage value proportional to the wheel speed or an interval corresponding to the wheel speed. By using the detection signal from the vehicle speed sensor 32, information such as the vehicle speed and the traveled distance of the vehicle can be obtained.

The shift position sensor 33 is a sensor that detects the position of the shift lever, such as parking P, reverse R, neutral N and drive D. Based on the detection signal from shift position sensor 33 , vehicle control unit 10 can determine forward or reverse movement of vehicle 50 . The shift lever may determine shift positions by mechanical movement or by electrical switching. The position of the shift lever may include various positions such as brake B and manual M.

The running mode switch 34 is a switch for setting the output characteristics of the torque output by the motor generator 41 . The running mode Mo selected/set by the running mode switch 34 is output as a running mode signal. As the driving mode, for example, modes such as eco, normal, and sports/power can be set. The eco mode is a mode that emphasizes the energy efficiency of the vehicle 50, that is, electricity consumption over output, the sport mode is a mode that emphasizes the driving performance of the vehicle 50, that is, output rather than electricity consumption, and the normal mode is an eco mode. This is an intermediate mode between the normal mode and the sports mode.

As shown in FIG. 2, the vehicle control unit 10 receives a running mode signal, which is a non-redundancy signal. On the other hand, an accelerator opening signal and a vehicle speed signal, which are redundant signals, are input to the monitoring unit 20 . The redundancy signal is a signal that is input from the sensor to the detection signal determining section 20a via a plurality of signal lines, for example, two signal lines. A non-redundant signal is a signal that is input from the sensor to the vehicle control unit 10 through a single signal line. In this embodiment, the monitoring unit 20 is provided with the detection signal determination unit 20 a , so that the accelerator opening signal and the vehicle speed signal are input to the monitoring unit 20 . The detection signal determination unit 20 a may be provided in the vehicle control unit 10 or may be provided separately from the vehicle control unit 10 and the monitoring unit 20 . The non-redundancy signal may include, in addition to the driving mode signal, a 1-pedal mode signal indicating selection of a 1-pedal mode that enables acceleration/deceleration and strong braking by operating the accelerator pedal. For example, the sensor has a dual detection element, a signal processing circuit and an output section, a single detection element, a signal processing circuit and a dual output section, a single detection element, a signal circuit and a dual output section. It may be made redundant.

In the vehicle control unit 10, the target torque Tt, which is the output target of the motor generator 41, is calculated using the accelerator opening Acc, the vehicle speed Vh, and the running mode Mo input from the detection signal determination unit 20a. , is input to the monitoring unit 20 and the motor-generator control unit 40 . In monitoring unit 20, monitoring target torque Ttw is calculated using accelerator opening Acc and vehicle speed Vh input from detection signal determining unit 20a. The monitoring unit 20 inputs a fail-safe signal F/S to the motor-generator control unit 40 when determining that an abnormality has occurred in the vehicle control unit 10 according to the comparison result between the monitored target torque Ttw and the target torque Tt. . The failsafe signal F/S instructs the motor-generator control unit 40 to set the output torque of the motor-generator 41 to the creep torque [N·m] or 0 [Nm]. is a signal to execute The motor-generator control unit 40 inputs the M/G control signal to the motor-generator 41 to control the output torque of the motor-generator 41 so as to achieve the target torque Tt from the vehicle control unit 10 . The motor-generator control unit 40 controls the output torque of the motor-generator 41 to creep torque [N·m] or 0 [N·m] according to the fail-safe signal F/S from the monitoring unit 20 .

As shown in FIG. 3, the vehicle control unit 10 includes a central processing unit (CPU) 11, a memory 12, an input/output interface 13, and a bus . CPU 11, memory 12 and input/output interface 13 are connected via bus 14 so as to be bidirectionally communicable. The memory 12 includes a memory such as a ROM that nonvolatilely and read-only stores a target torque calculation program P1 for calculating the target torque, and a memory that can be read and written by the CPU 11 such as a RAM. The memory 12 further stores a requested torque map M1 used for calculating the requested torque. The required torque map M1 is a map that associates the accelerator opening and the required torque according to the driving mode, and a plurality of maps are prepared for each vehicle speed. The CPU 11 expands the target torque calculation program P1 stored in the memory 12 into a readable/writable memory and executes it to calculate the required torque, and uses the forward or reverse signal from the shift position sensor 33 to calculate the target torque Tt. to decide. The CPU 11 may be a single CPU, a plurality of CPUs executing each program, or a multi-core type CPU capable of simultaneously executing a plurality of programs.

The input/output interface 13 is connected to a shift position sensor 33, a running mode switch 34, a monitoring section 20, and a motor-generator control section 40 via signal lines. Detection signals are input from the shift position sensor 33 and the driving mode switch 34 . Detection signals from the accelerator opening sensor 31 and the vehicle speed sensor 32 are input to the input/output interface 13 via the monitoring section 20, that is, the detection signal determination section 20a.

As shown in FIG. 4, the monitoring unit 20 includes a central processing unit (CPU) 21, a memory 22, an input/output interface 23, and a bus . The CPU 21, memory 22 and input/output interface 23 are connected via a bus 24 so as to be able to communicate bidirectionally. The memory 22 is a memory, such as a ROM, for non-volatile and read-only storage of a monitoring program P2 for calculating the required torque for monitoring, determining abnormality of the vehicle control unit 10 and determining execution of fail-safe, and the CPU 21 . A memory, such as a RAM, that can be read and written by the . The memory 22 further stores a monitoring torque map M2 used for calculating the monitoring demand torque. The monitoring torque map M2 is a map that associates the accelerator opening and the required torque, and a plurality of maps are prepared for each vehicle speed. In addition, the monitoring torque map M2 is associated with a plurality of required torques that can be set according to the running mode Mo, that is, the output characteristic with the largest required torque among the output torque characteristics of the motor generator 41. . The CPU 21 expands the monitoring program P2 stored in the memory 22 into a readable/writable memory and executes it, thereby calculating the required torque for monitoring, and using the forward or reverse signal from the shift position sensor 33 to calculate the target torque to be monitored. Ttw is determined, and the target torque Tt and the monitored target torque Ttw are compared to determine execution of fail-safe. The CPU 21 can also function as a detection signal determining section 20a that executes the monitoring program P2 stored in the memory 22 and determines the vehicle speed signal indicating the higher vehicle speed out of the two vehicle speed signals. The detection signal determination unit 20a may determine which detection signal to use among the accelerator opening signals input from the two signal lines. The CPU 21 may be a single CPU, a plurality of CPUs executing each program, or a multi-core type CPU capable of simultaneously executing a plurality of programs.

An accelerator opening sensor 31, a vehicle speed sensor 32, a shift position sensor 33, a vehicle controller 10, and a motor generator controller 40 are connected to the input/output interface 23 via signal lines. Detection signals are input from the accelerator opening sensor 31 , the vehicle speed sensor 32 and the shift position sensor 33 . Redundancy signals are input to the monitoring unit 20 from the accelerator opening sensor 31 and the vehicle speed sensor 32 via two signal lines, respectively. A detection signal from the accelerator opening sensor 31 may be input to the vehicle control unit 10 .

Detection signal determination processing executed by the control device 100 according to the first embodiment, specifically, the detection signal determination unit 20a in the monitoring unit 20 will be described. The processing routine shown in FIG. 5 is repeatedly executed at predetermined time intervals, for example, from the time the vehicle control system is started to the time it is stopped, or from the time the start switch is turned on until the start switch is turned off.

The CPU 21 acquires vehicle speeds V1 and V2 (km/h) input from the vehicle speed sensor 32 to the input/output interface 23 via two signal lines (step S100). The CPU 21 determines the higher vehicle speed out of the vehicle speed V1 and the vehicle speed V2. In this embodiment, the CPU 21 determines whether or not the vehicle speed V1 is greater than the vehicle speed V2 (step S102). The vehicle speed Vh, that is, the vehicle speed to be used in subsequent processing is determined (step S104), and this processing routine ends. When it is determined that V1 is not V1>V2, that is, V1≤V2 (step S102: No), the CPU 21 sets the vehicle speed V2 to the high vehicle speed Vh (step S106), and terminates this processing routine. In step S102, instead of determining whether V1>V2, it may be determined whether V1≧V2. In this embodiment, the determination is simplified by making a determination including the case of V1=V2 in step S102. Either vehicle speed V1 or V2 may be determined as the high vehicle speed Vh. The determined high vehicle speed Vh is used when calculating the required torque Ta and the monitored required torque Taw in the vehicle control unit 10 and the monitoring unit 20 .

A target torque determination process executed by the control device 100 according to the first embodiment, specifically the vehicle control unit 10, will be described. The processing routine shown in FIG. 6 is repeatedly executed at predetermined time intervals, for example, from the time the vehicle control system is started to the time it is stopped, or from the time the start switch is turned on until the start switch is turned off.

The CPU 11 acquires the accelerator opening Acc, the vehicle speed Vh through the detection signal determination process, and the running mode Mo (step S200). The CPU 11 calculates the required torque Ta using the acquired accelerator opening Acc, vehicle speed Vh, travel mode Mo, and the required torque map M1 (step S202). For example, as shown in FIG. 8, the required torque map M1 has a characteristic line L1 when the driving mode Mo is eco and a characteristic line L2 when the driving mode Mo is sports. The characteristic lines L1 and L2 may be corrected according to the vehicle speed V, or a plurality of characteristic lines L1 and L2 may be prepared for each predetermined vehicle speed V. A plurality of torque maps M1 may be prepared for each predetermined vehicle speed V. FIG. The CPU 11 determines whether or not the shift position signal SP from the shift position sensor 33 indicates reverse R (step S204). When the shift position signal SP=R, the CPU 11 determines that the target torque Tt=-required torque Ta (step S206), and terminates this processing routine. On the other hand, when the shift position signal SP.noteq.R, the CPU 11 determines that the target torque Tt=the required torque Ta (step S208), and terminates this processing routine. The determined target torque Tt is input to the monitoring unit 20 and the motor-generator control unit 40 .

A monitoring target torque determination process executed by the control device 100 according to the first embodiment, specifically by the monitoring unit 20 will be described. The processing routine shown in FIG. 7 is repeatedly executed at predetermined time intervals, for example, from the time the vehicle control system is started to the time it is stopped, or from the time the start switch is turned on until the start switch is turned off. Further, when the monitoring unit 20 performs processing for determining execution of fail-safe, that is, processing for comparing the target torque Tt and the monitored target torque Ttw, the monitoring unit 20 functions as a fail-safe determining unit. Furthermore, apart from the monitoring unit 20, a fail-safe determining unit that executes a comparison process between the target torque Tt and the monitored target torque Ttw may be provided.

The CPU 21 acquires the accelerator opening Acc and the vehicle speed Vh through the detection signal determination process (step S300). The CPU 21 uses the obtained accelerator opening Acc and vehicle speed Vh and the monitoring torque map M2 to calculate the monitored torque request Taw (step S302). As shown in FIG. 9, the monitoring torque map M2 has the largest output torque among the output characteristics of the motor generator 41 set by the running mode Mo, that is, the output torque corresponding to the accelerator opening Acc is the largest. It has a characteristic line L2 corresponding to sport, which is a large output characteristic. Further, the characteristic line L2 shows that the torque difference with respect to the target torque Tt determined by the vehicle control unit 10 in accordance with other output characteristics of the motor generator 41 set by the driving mode Mo is greater when the accelerator is turned on than when the accelerator is turned off. It has the property of growing. The reason for using such an output characteristic or characteristic line L2 is that the monitoring unit 20 calculates the monitoring request torque Taw without using the driving mode signal, and when the driving mode Mo is set to sport, an abnormality occurs. This is to prevent erroneous detection. In FIG. 9, in order to facilitate understanding of abnormality determination, an upper limit threshold line G1 indicating a torque threshold for determining that an abnormality has occurred in the vehicle control unit 10 by the monitoring unit 20 is shown. A dashed line indicates a characteristic line L1 that is used to determine the required torque Ta when the running mode Mo is eco. The upper threshold line G1 is a line obtained by adding the detection threshold α to each torque value on the characteristic line L2, and the torque value of the upper threshold line G1 is represented by Ttw+α. In the above description, the output torque is synonymous with the monitored request torque Taw and the monitored target torque Ttw.

The CPU 21 determines whether or not the shift position signal SP from the shift position sensor 33 indicates reverse R (step S304). When the shift position signal SP=R, the CPU 11 determines that the monitored target torque Ttw=--monitored required torque Taw (step S306). When the shift position signal SP≠R, the CPU 21 determines that the monitoring target torque Ttw=monitoring request torque Taw (step S308). The CPU 21 sets the detection threshold α (step S310). The detection threshold value α is a threshold value for determining whether or not an abnormality has occurred in the vehicle control unit 10 using the target torque Tt and the monitoring target torque Ttw. , is defined as a characteristic line L3 and is set according to the vehicle speed V. In this embodiment, as the vehicle speed V increases, the detection threshold α also increases.

The CPU 21 sets the detection time t according to the accelerator operation (step S312). The accelerator operation can also be referred to as an operation mode of the accelerator, and for example, the accelerator opening Acc is used as a parameter for determining the operation mode of the accelerator. In this embodiment, the detection time t is set shorter as the accelerator opening Acc increases in order to suppress an increase in the vehicle acceleration G and promote a reduction in the vehicle acceleration G, as will be described later. More specifically, it is set by the characteristic line L4 shown in FIG. 11 and the accelerator opening Acc. In general, the operating range in which the accelerator opening Acc is fully opened is limited, and so-called half throttle and partial throttle are frequently used. Therefore, in the present embodiment, the characteristic line L4 is defined so that the detection time t is substantially the same when the predetermined accelerator opening Acc is exceeded. , the detection time t is defined to be short when the accelerator opening Acc is not 0, that is, when the accelerator is on.

The CPU 21 determines whether or not the difference between the target torque Tt and the monitored target torque Ttw is equal to or greater than the detection threshold value α, that is, whether or not Tt−Ttw≧α (step S314). When the CPU 21 determines that Tt−Ttw≧α (step S314: Yes), it determines that there is a possibility that some abnormality has occurred in the vehicle control unit 10, and increments the count value C by one. ie, C=C+1 (step S316). On the other hand, when the CPU 21 determines that Tt−Ttw≧α is not true, that is, Tt−Ttw<α (step S314: No), the CPU 21 determines that there is no abnormality in the vehicle control unit 10, and the count value Clear C, that is, set C=0 (step S318). The CPU 21 determines whether or not the count value C is equal to or greater than the detection time t, that is, whether or not C≧t (step S320), and when it is determined that C≧t (step S320: Yes). , the execution of fail-safe is determined (step S322), and this processing routine ends. When the CPU 21 determines that C≧t does not hold, that is, C<t (step S320: No), it ends this processing routine without deciding to execute the fail-safe. Note that the count value C can be regarded as a time corresponding to the execution interval time of the processing routine shown in FIG. When the monitoring unit 20 decides to execute the fail-safe, it outputs a fail-safe signal F/S to the motor-generator control unit 40 to set the output torque of the motor-generator 41 to the creep torque [N·m] or 0 Let it be [N·m].

According to the control device 100 according to the first embodiment described above, even if the two detection signals input from the vehicle speed sensor 32 to the monitoring unit 20 do not match, the fail-safe is not executed immediately. The high vehicle speed Vh, which is the signal value of the high vehicle speed detection signal indicating the high vehicle speed, is used to calculate the required torque Ta and the monitored required torque Taw, that is, the target control value and the monitored target torque Ttw. can be made possible. Specifically, conventionally, when redundant signals, for example, signals input from the vehicle speed sensor to the control unit via two signal lines, do not match, processing using the detection signal from the vehicle speed sensor is immediately performed. Aborting failsafe was running. As a result, the drive control of the motor generator is stopped, and the vehicle 50 becomes unable to run and stops. On the other hand, in the control device 100 according to the first embodiment, the target torque Tt and the monitored target torque Ttw are calculated using the high vehicle speed Vh indicating a high vehicle speed. As long as an abnormality is not determined in the processing, even if the redundancy signals do not match, the motor generator 41 can be driven to allow the vehicle 50 to continue running. Here, the motor-generator 41 has a characteristic that the torque decreases as the rotation speed increases. When the vehicle does not have a transmission, the electric motor generator 41 generates torque corresponding to the high vehicle speed line L5 and torque corresponding to the low vehicle speed line L6 for a constant accelerator opening, as indicated by the symbol Gd in FIG. be smaller than Therefore, when the high vehicle speed detection signal is used, the torque of the motor generator 41 can be reduced compared to when the low vehicle speed detection signal is used, and unexpected behavior and acceleration of the vehicle 50 can be suppressed or prevented. It is possible to continue driving while the vehicle is moving, and the driver can perform evacuation driving.

A common failure of the vehicle speed sensor 32 is disconnection of a signal line. Since the vehicle speed signal becomes 0 km/h due to a disconnection of the signal line, the controller 100 according to the first embodiment can detect an abnormality in the vehicle speed sensor 32 even if the signal line is disconnected. It is possible to continue driving while notifying the driver, and the driver can carry out evacuation driving or entering the garage for repair.

Other embodiments:
(1) In the above embodiment, the monitoring unit 20 included in the control device 100 functions as a fail-safe determining unit. does not have to be provided. That is, a failsafe determination device may be provided separately from the control device 100 . The advantages of the control device 100 according to the first embodiment can be obtained without the fail-safe decision function.

(2) In the above embodiment, two signal lines connecting the vehicle speed sensor 32 and the monitoring unit 20 are used. good. Even in this case, if the high vehicle speed detection signal indicating the highest vehicle speed is used, the advantage of the first embodiment can be obtained.

(3) In the above embodiment, the CPU 11 executes the target torque calculation program P1 and the CPU 21 executes the monitoring program P2, whereby the vehicle control unit 10 and the monitoring unit 20 are realized in software. It may be implemented in hardware by programmed integrated or discrete circuits.

Although the present disclosure has been described above based on the embodiments and modifications, the above-described embodiments of the present invention are intended to facilitate understanding of the present disclosure, and do not limit the present disclosure. This disclosure may be modified and modified without departing from its spirit and scope of the claims, and this disclosure includes equivalents thereof. For example, the technical features in the embodiments and modifications corresponding to the technical features in each form described in the Summary of the Invention are used to solve some or all of the above problems, or In order to achieve some or all of the effects, it is possible to appropriately replace or combine them. Also, if the technical features are not described as essential in this specification, they can be deleted as appropriate. For example, the controller for an electric motor in a vehicle according to the first aspect is used as an application example 1,
Application Example 2: The electric motor control device for a vehicle according to Application Example 1 further comprises:
A controller for an electric motor in a vehicle, comprising a fail-safe determination unit that determines execution of fail-safe for the electric motor using the target torque and the monitored target torque.
Application Example 3: The controller for the electric motor in the vehicle according to Application Example 2 further comprises:
Control of an electric motor in a vehicle, comprising: a second control unit that controls the electric motor, the second control unit that stops the electric motor in response to a decision to execute the fail-safe by the fail-safe decision unit. Device.
can be

DESCRIPTION OF SYMBOLS 10... Vehicle control part 20... Monitoring part 20a... Detection signal determination part 40... Motor generator control part 41... Motor generator 50... Vehicle P1... Target torque calculation program P2... Monitoring program 100... Control device.

Claims (3)

A control device (100) for an electric motor (41) in a vehicle (50),
a detection signal determination unit (20a) for determining a high vehicle speed detection signal indicating a high vehicle speed among a plurality of detection signals input from the vehicle speed detection unit (32);
a monitoring unit (20) for determining a monitoring target torque using the determined high vehicle speed detection signal;
a first control unit (10) for determining a target torque, which is an output target of the electric motor, using the determined high vehicle speed detection signal ;
A control device for an electric motor in a vehicle, comprising: a fail-safe determining section (20) that determines execution of fail-safe for the electric motor using the target torque and the monitored target torque . The control device for an electric motor in a vehicle according to claim 1 further comprises:
a second control unit (40) for controlling the electric motor, the second control unit for stopping the electric motor in accordance with the decision to execute the fail-safe by the fail-safe decision unit; Motor controller. A method for controlling an electric motor in a vehicle, comprising:
determining a high vehicle speed detection signal indicating a high vehicle speed from among a plurality of detection signals input from the vehicle speed detection unit;
determining a monitored target torque using the determined high vehicle speed detection signal;
determining a target torque as an output target of the electric motor using the determined high vehicle speed detection signal ;
A method of controlling an electric motor in a vehicle, comprising determining execution of fail-safe for the electric motor using the target torque and the monitored target torque .

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