JP5621717B2 - Control device for automatic transmission - Google Patents

Description

  The present invention relates to a control device for an automatic transmission.

  Patent Document 1 discloses an apparatus for detecting an electrical failure in a circuit for driving a solenoid of an automatic transmission. This device cuts off the power to the solenoid when a failure is detected. In this technique, an electrical failure is detected by comparing a command signal from a microcomputer with a monitor signal from a solenoid drive circuit.

JP-A-1-169159

  In the configuration of the prior art, a failure in a circuit for a command signal from the microcomputer to the drive circuit and a failure in a circuit for a monitor signal from the drive circuit to the microcomputer cannot be distinguished. For this reason, even when only a circuit for the monitor signal has a failure, the energization to the solenoid is cut off. When only the monitor signal circuit is faulty, the automatic transmission may be able to perform its original function. That is, in the prior art, there is a possibility that the function of the automatic transmission is excessively limited.

  The present invention has been made in view of the above problems, and its purpose is to identify an abnormal portion of a circuit for driving a solenoid of an automatic transmission and to take appropriate countermeasures according to the abnormal portion. It is to provide a control device for an automatic transmission that can be used.

  The present invention employs the following technical means to achieve the above object.

According to the first aspect of the present invention, the energization state of the actuator (5) of the automatic transmission is adjusted according to the command signal (S1c) output from the control means (61, 261), and the actuator (5) In a control device for an automatic transmission including a drive circuit (62, 262) that outputs a monitor signal (S1m) indicating an energized state toward a control means, based on a command signal (S1c) and a monitor signal (S1m), The circuit determination means (61a) for determining an abnormality in the electric circuit including the signal transmission circuit for the command signal and the signal transmission circuit for the monitor signal, and the actual gear ratio of the automatic transmission (4) become the target gear ratio. by determining whether or not, determines function determination means for determining whether the normal function of the actuator is abnormal (61b), it is determined abnormal electric circuit by the circuit determination means and function determination And when an abnormality of the actuator functions by stages is determined, it is determined abnormality of the electric circuit by the circuit determining means, and in response to a case where the functions by determining means normal actuator function is determined, different countermeasures treatment respectively The countermeasure treatment means (61c) which provides is provided.

According to this configuration, the control device for the automatic transmission includes control means, a drive circuit, and an actuator for the automatic transmission. The control means outputs a command signal. The drive circuit adjusts the energization state of the actuator of the automatic transmission according to the command signal. Furthermore, the drive circuit outputs a monitor signal indicating the energization state of the actuator to the control means. The control means can include a circuit determination means, a function determination means, and a countermeasure treatment means. The circuit determination means determines an abnormality of the electric circuit including the command signal transmission circuit and the monitor signal transmission circuit based on the command signal and the monitor signal. The function determining means determines whether the function of the actuator is normal or abnormal based on the actual gear ratio of the automatic transmission and the target gear ratio . The countermeasure processing means provides different countermeasures depending on the abnormality. Here, the case where an abnormality of the electric circuit is determined and the abnormality of the function of the actuator is determined is different from the case where the abnormality of the electric circuit is determined and the normality of the function of the actuator is determined. Countermeasures are provided. As a result, an abnormal state can be identified by a combination of circuit determination and function determination, and countermeasures can be provided according to the abnormal state.

  According to a second aspect of the present invention, the countermeasure processing means determines the first corresponding to the abnormality of the signal transmission circuit of the command signal when the abnormality of the electric circuit is determined and the abnormality of the function of the actuator is determined. A countermeasure (108) is provided, and when the abnormality of the electric circuit is determined and the function of the actuator is determined to be normal, the second countermeasure (105) corresponding to the abnormality of the signal transmission circuit of the monitor signal It is characterized by providing. According to this configuration, when it is predicted that there is an abnormality in the signal transmission circuit of the command signal, the first countermeasure for dealing with the abnormality is provided. Further, when it is predicted that there is an abnormality in the signal transmission circuit of the monitor signal, a second countermeasure measure corresponding to the abnormality is provided.

  According to a third aspect of the present invention, the first countermeasure action (108) is to stop control of the automatic transmission by a command signal, and the second countermeasure action (105) is to control the automatic transmission by a command signal. It is the continuation of. According to this configuration, when it is predicted that there is an abnormality in the signal transmission circuit of the command signal, the control of the automatic transmission by the command signal is stopped. Further, when it is predicted that there is an abnormality in the signal transmission circuit of the monitor signal, the control of the automatic transmission by the command signal is continued despite the abnormality of the electric circuit. As a result, it is possible to avoid taking excessive measures such that normal control of the automatic transmission is stopped.

The invention according to claim 4 is further provided in the drive circuit (62, 262), and is provided in the drive circuit and signal determination means (62a) for determining abnormality of the command signal input to the drive circuit. The control switching means (62b) for controlling the energization state of the actuator by alternative control when an abnormality of the signal is determined without responding to the command signal. According to this configuration, the abnormality of the command signal is determined in the drive circuit. Furthermore, switching to alternative control that does not depend on the command signal is performed in the drive circuit. For this reason, the drive according to the command signal can be switched to an alternative drive without interrupting the control of the actuator. In addition, when the command signal is abnormal, the actuator can be continuously driven by alternative control, so that it is possible to avoid excessive measures such as stopping the normal control of the automatic transmission.

The invention according to claim 5 is characterized in that the signal determining means (62a) determines abnormality based on the voltage level of the command signal. According to this configuration, it is possible to determine abnormality of the command signal based on the voltage level of the command signal.

According to the sixth aspect of the present invention, the backup signal (S1b) corresponding to the command signal is provided from the control means to the drive circuit, and the control switching means (62b) The energized state is controlled. According to this configuration, when the abnormality of the command signal is determined in the drive circuit, the energization state of the actuator is controlled according to the backup signal. For this reason, the drive according to the command signal can be switched to the drive according to the backup signal without interrupting the control of the actuator.

  Note that the reference numerals in parentheses described in the claims and the above-described means indicate the correspondence with the specific means described in the embodiments described later as one aspect, and are technical terms of the present invention. It does not limit the range.

1 is a block diagram showing an automatic transmission system for a vehicle according to a first embodiment to which the present invention is applied. It is a block diagram which shows the whole control apparatus of 1st Embodiment. It is a block diagram which shows a part of control apparatus of 1st Embodiment. It is a flowchart which shows the action | operation of the control apparatus of 1st Embodiment. It is a table | surface which shows the signal state of each part of 1st Embodiment. It is a table | surface which shows the gear change state of the automatic transmission of 1st Embodiment. It is a wave form diagram which shows the action | operation of the drive circuit of 1st Embodiment. It is a wave form diagram which shows the action | operation of the control apparatus of 1st Embodiment. It is a block diagram which shows the whole control apparatus which concerns on 2nd Embodiment to which this invention is applied. It is a block diagram which shows a part of control apparatus of 2nd Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Further, in the following embodiments, a correspondence relationship may be indicated by adding reference numerals that differ only by a hundreds to the parts corresponding to the matters described in the preceding embodiment, and redundant description may be omitted. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

(First embodiment)
FIG. 1 is a block diagram showing a vehicular automatic transmission system 1 according to a first embodiment to which the present invention is applied. The vehicle automatic transmission system 1 is mounted on a vehicle such as a four-wheeled vehicle. The power source 2 can include an internal combustion engine and / or an electric motor. The vehicle includes drive wheels 3. The power output from the power source 2 is transmitted to the drive wheels 3 to drive the vehicle. An automatic transmission 4 is provided in a power transmission path between the power source 2 and the wheels 3. The automatic transmission 4 shifts the rotation of the output shaft of the power source 2 and transmits it to the drive wheels 3. The automatic transmission 4 can include a torque converter and a multistage or continuously variable speed reducer. The automatic transmission 4 includes a hydraulic control system for controlling a plurality of hydraulic pressures for adjusting the engagement states of the plurality of engagement elements. The automatic transmission 4 includes an actuator 5 including a plurality of valves for controlling a hydraulic control system and changing a gear ratio. The actuator 5 includes an on-off type solenoid that switches the hydraulic pressure with a linear solenoid that controls the line pressure of the hydraulic control system. The automatic transmission 4 is a so-called fail-safe valveless type automatic transmission that does not include a mechanical fail-safe valve.

  The vehicle automatic transmission system 1 includes a control device 6. The control device 6 is an electronic control device. The control device 6 controls the automatic transmission 4 so as to provide a gear ratio according to the instruction of the occupant and to provide a gear ratio according to the traveling state of the vehicle. The control device 6 controls the actuator 5 so as to obtain a target gear ratio. Specifically, the control device 6 adjusts the energization state to the plurality of solenoids so as to obtain a target gear ratio. Furthermore, the control device 6 provides an abnormality detection unit that detects an abnormality in the drive circuits of the plurality of solenoids, and a fail-safe unit that executes countermeasures corresponding to the detected abnormality. The vehicular automatic transmission system 1 includes a rotation speed sensor 7 for detecting the rotation speed transmitted from the power source 2 to the automatic transmission 4, that is, the input rotation speed Nin of the automatic transmission 4. Further, the vehicle automatic transmission system 1 includes a rotation speed sensor 8 for detecting the rotation speed transmitted from the automatic transmission 4 to the drive wheels 3, that is, the output rotation speed Nout of the automatic transmission 4. The input rotation speed Nin and the output rotation speed Nout detected by the rotation speed sensors 7 and 8 are input to the control device 6.

  FIG. 2 is a block diagram showing the entire control device 6 according to the first embodiment. The control device 6 is provided by a microcomputer provided with a computer-readable storage medium. The storage medium stores a computer-readable program. The storage medium can be provided by a memory. The program is executed by the control device 6 to cause the control device 6 to function as a device described in this specification, and to cause the control device 6 to function so as to execute the control method described in this specification. The means provided by the control device 6 can also be referred to as a functional block or module that achieves a predetermined function.

  The control device 6 adjusts the energization state to the plurality of solenoids SL1, SL2, SL3, SL4, S1, and S2 as the actuator 5. Solenoids SL1, SL2, SL3, and SL4 are linear solenoids. Solenoids S1 and S2 are on-off type solenoids. Solenoids S1 and S2 also serve as fail-safe solenoids. The fail safe solenoid can control the automatic transmission 4 to a predetermined fail safe state by setting it to a predetermined energized state. In the fail-safe state, the gear ratio of the automatic transmission 4 is fixed to a predetermined gear ratio. The control device 6 includes a CPU 61 and a plurality of drive circuits 62. A drive circuit 62 is provided corresponding to each of the plurality of solenoids SL1-SL4, S1, S2. The drive circuit 62 is a packaged semiconductor integrated circuit.

  The CPU 61 has a terminal COM for outputting a command signal for energization of a target solenoid. The CPU 61 provides a control unit that outputs a command signal. Each drive circuit 62 receives a command signal, and provides a corresponding solenoid with an energized state according to the command signal. For example, the drive circuit of the linear solenoid SL1 energizes the linear solenoid SL1 with a current corresponding to the command signal output from the CPU 61. For example, the drive circuit for the on / off type solenoid S1 turns on or off the energization of the solenoid S1 in accordance with a command signal output from the CPU 61.

  The drive circuit 62 generates and outputs a monitor signal indicating the energization state of the corresponding solenoid. The CPU 61 has a terminal MON for receiving and inputting a monitor signal output from the drive circuit 62.

  Further, the CPU 61 has a terminal BAK for outputting a backup signal. The backup signal is a signal corresponding to the command signal. In this embodiment, the command signal is output from the terminal COM as an analog signal in which 1.0 V corresponds to the off state (0%) and 4.0 V corresponds to the on state (100%). On the other hand, the backup signal is output from the terminal BAK as a digital signal in which 0.0 V corresponds to the off state (0%) and 5.0 V corresponds to the on state (100%).

  FIG. 3 is a block diagram illustrating a part of the control device 6 according to the first embodiment. In the figure, the components of the CPU 61 corresponding to the on / off type solenoid S1, the drive circuit 62, and the power supply circuit are shown. Hereinafter, the configuration and functions for fail-safe will be described using the on-off solenoid S1 as a representative example. The following description is also applied to the other solenoids SL1-SL4, S2 within the applicable range.

  The CPU 61 includes basic control means for outputting the energization state of the solenoid S1 necessary for providing the requested shift state as a command signal S1c from the terminal COM. Further, the CPU 61 includes backup control means for generating a backup signal S1b corresponding to the command signal S1c and outputting it from the terminal BAK.

  Further, the CPU 61 includes a circuit determination unit 61a. The circuit determination means 61a determines whether the electric circuit including the signal transmission circuit for the command signal S1c and the signal transmission circuit for the monitor signal S1m is normal or abnormal. The circuit determination means 61a determines that the electric circuit is normal based on whether or not they have a predetermined correspondence based on the command signal S1c output from the terminal COM and the monitor signal S1m input to the terminal MON. Or is abnormal. For example, when the command signal S1c indicates an on state and the monitor signal S1m indicates an on state, the circuit determination unit 61a determines that the electric circuit is normal. Even when the command signal S1c indicates an off state and the monitor signal S1m indicates an off state, it is determined that the electric circuit is normal. On the other hand, when the command signal S1c indicates an on state and the monitor signal S1m indicates an off state, it is determined that the electric circuit is abnormal. Even when the command signal S1c indicates an off state and the monitor signal S1m indicates an on state, the electric circuit is determined to be abnormal. However, the circuit determination unit 61a cannot identify which of the signal transmission circuit for the command signal S1c and the signal transmission circuit for the monitor signal S1m is abnormal.

  The CPU 61 includes function determination means 61b. The function determination unit 61b determines whether or not the actuator 5 that is a control target by the drive circuit 62 normally functions. That is, the function determining means 61b determines whether or not the solenoid S1 is performing the requested function, and in other words, whether or not the entire drive system including the solenoid S1 and the drive circuit 62 is functioning normally. judge. Here, the function determination is executed depending on whether or not the automatic transmission 4 provides the requested irregularity ratio. That is, the function determination means 61b determines that the actuator 5 and the gear ratio that should be provided according to the operating state of the actuator 5 instructed by the CPU 61 are the same as the gear ratio that is actually provided by the automatic transmission 4. It is determined that the solenoid S1 included therein is normal. On the other hand, the function determination means 61b determines that the actuator 5 and the solenoid S1 included therein are abnormal when the gear ratio to be provided is different from the gear ratio actually provided.

  Here, when the circuit determination unit 61a determines that the abnormality of the electric circuit is determined, the function determination unit 61b executes the determination process. By combining the determination result of the circuit determination unit 61a and the determination result of the function determination unit 61b, two cases can be identified. The first case is a case where the requested gear ratio is actually provided by the normal functioning of the actuator 5 even though the abnormality of the electric circuit is determined. In this case, it is considered that the command signal S1c is normally transmitted and the drive circuit 62 and the solenoid S1 are functioning normally. Therefore, it is considered that the abnormality of the electric circuit is caused by the abnormality of the signal transmission circuit of the monitor signal S1m. The second case is a case where the abnormality of the electric circuit is determined, and at the same time, the actuator 5 does not function normally and the requested gear ratio is not actually provided. In this case, it is considered that the command signal S1c is not normally transmitted and the drive circuit 62 and the solenoid S1 are not functioning normally. Therefore, it is considered that the abnormality of the electric circuit is caused by the abnormality of the signal transmission circuit of the command signal S1c. In this way, it is possible to identify which of the signal transmission circuit for the command signal S1c and the signal transmission circuit for the monitor signal S1m is abnormal.

  The CPU 61 includes countermeasure processing means 61c that executes countermeasure measures according to the abnormal state identified by combining the determination result of the circuit determination means 61a and the determination result of the function determination means 61b. Here, different countermeasures are executed and provided depending on whether there is an abnormality in the signal transmission circuit of the command signal S1c and an abnormality in the signal transmission circuit of the monitor signal S1m. The countermeasure processing unit 61c stops the output of the command signal S1c when there is an abnormality in the signal transmission circuit of the command signal S1c. Further, the CPU 61 stops normal control of the automatic transmission 4 and shifts the automatic transmission 4 to the fail safe mode. On the other hand, if the signal transmission circuit for the monitor signal S1m is abnormal, the countermeasure processing unit 61c continues to output the command signal S1c. As a result, normal control of the automatic transmission 4 is continued even if the signal transmission circuit for the monitor signal S1m is abnormal. However, the countermeasure processing means 61c gives a warning to the driver of the vehicle. For example, a vehicle diagnosis, a display for prompting repair, or a notification notifying the presence of an abnormality is executed.

  The drive circuit 62 is supplied with a power supply + B from a battery mounted on the vehicle. The power supply circuit includes a smoothing capacitor C, a pull-up resistor R, and a reverse connection diode D. The power supply + B supplies power to the plurality of power supply terminals VCC of the drive circuit 62. The terminal GND of the drive circuit 62 is connected to the ground potential.

  The drive circuit 62 has a terminal IN1 for inputting the command signal S1c and a terminal IN2 for inputting the backup signal S1b. Further, the drive circuit 62 has a terminal DG for outputting the monitor signal S1m, and a power terminal OUT for supplying power to the solenoid S1. As described above, the drive circuit 62 includes a basic drive circuit that provides a basic function of outputting the output current S1out corresponding to the command signal S1c from the terminal OUT. Further, the drive circuit 62 includes a monitor circuit that provides a monitor function for outputting a monitor signal S1m indicating the state of the output current S1out output from the terminal OUT from the terminal DG.

  Furthermore, in this embodiment, the drive circuit 62 includes a signal determination unit 62a that determines abnormality of the command signal S1c. The drive circuit 62 includes control switching means 62b that selects and provides either the command signal S1c or the backup signal S1b to the basic drive circuit according to the determination result provided from the signal determination means 62a. The control switching means 62b gives the command signal S1c to the basic drive circuit when the command signal S1c is normal, and gives the backup signal S1b to the basic drive circuit when the command signal S1c is abnormal. Therefore, when the command signal S1c is normal, the drive circuit 62 provides the energization state according to the command signal S1c to the solenoid S1, and when the command signal S1c is abnormal, the drive circuit 62 sets the energization state according to the backup signal S1b to the solenoid. Provide to S1.

  FIG. 4 is a flowchart showing the operation of the control device 6 of the first embodiment. In the figure, processing for providing the circuit determination means 61a, the function determination means 61b, and the countermeasure treatment means 61c is shown. The process 101 is repeatedly executed at a predetermined cycle. In step 102, the command signal S1c is output from the terminal COM. In step 103, the monitor signal S1m is input from the terminal MON. In step 104, it is determined whether or not the signal state of the terminal COM matches the signal state of the terminal MON. If the signal state of the terminal COM matches the signal state of the terminal MON, that is, if the command signal S1c and the monitor signal S1m have a predetermined correspondence, the process proceeds to step 105 and the output of the command signal S1c is continued. To do. As a result, normal control of the automatic transmission 4 is continued. When the signal state of the terminal COM does not match the signal state of the terminal MON, that is, when the command signal S1c and the monitor signal S1m are not in a predetermined correspondence relationship, the process proceeds to step 106.

  In step 106, the actual gear ratio is detected. The actual gear ratio can be detected from the rotational speeds Nin and Nout detected by the rotational speed sensors 7 and 8. A ratio Nout / Nin between the rotational speeds Nin and Nout is calculated as a detection ratio indicating an actual gear ratio. In step 107, the required ratio, which is the speed ratio requested by the CPU 61, is compared with the detection ratio.

  If the requested ratio is equal to the detection ratio, that is, if the requested transmission ratio is actually provided, the process proceeds to step 105. In this case, it is considered that the signal transmission circuit for the monitor signal S1m is abnormal because the actuator 5 is functioning normally despite the abnormality in the electric circuit. In step 105, the output of the command signal S1c is continued, and the normal control of the automatic transmission 4 is continued. As a result, it is avoided that the normal control of the automatic transmission 4 is stopped only due to an abnormality in the additional circuit of the signal transmission path of the monitor signal S1m. In other words, excessive fail-safety can be avoided.

  If the required ratio and the detection ratio are not equal, that is, if the requested transmission ratio is not actually provided, the routine proceeds to step 108. In this case, there is an abnormality in the electric circuit, and since the actuator 5 is not functioning normally, it is considered that there is an abnormality in the signal transmission circuit of the command signal S1c. In step 108, the output of the command signal S1c is stopped, and the above-described failsafe control is executed.

  FIG. 5 is a table showing signal states of the respective parts of the first embodiment. In the figure, the signal state of each terminal is shown for each abnormality such as disconnection or failure of the electric circuit. Here, the signal transmission circuit of the command signal S1c is called a command line. The signal transmission circuit for the monitor signal S1m is called a monitor line. As shown in the figure, when a disconnection (open) and / or a short (short circuit) occurs in the command line or the monitor line, a mismatch may occur between the signal state of the terminal COM and the signal state of the terminal MON. Therefore, in the circuit determination means 61a and step 104 described above, the abnormality of the electric circuit including the command line and the monitor line is determined by detecting the mismatch of the signal states as illustrated.

  FIG. 6 is a table showing a shift state of the automatic transmission 4 according to the first embodiment. In the drawing, the energization states of the solenoids SL1-SL4, S1, and S2 are shown for each gear ratio, that is, in the shift state from the first speed to the sixth speed. In the figure, ◯ indicates the energization on state, and x indicates the energization off state. As shown in the figure, the combination of energization states of the solenoids is different for each gear ratio. The CPU 61 knows the gear ratio, that is, the gear position requested by itself and instructed by the command signal. On the other hand, the detection ratio indicates the actual gear ratio, that is, the gear position. Therefore, by comparing these, it is determined whether or not the electric circuit including the drive circuit 62 is functioning normally. Such a determination corresponds to the function provided by step 106 and step 107. Therefore, such a determination is executed when the signal state of the terminal COM does not match the signal state of the terminal MON, that is, when the command signal S1c and the monitor signal S1m are not in a predetermined correspondence relationship. When the command signal S1c and the monitor signal S1m are not in a predetermined correspondence relationship, that is, when some abnormality in the signal line is detected, for example, the following determination is possible. When the CPU 61 requests driving at the third speed and the detection ratio indicates the gear ratio at the third speed, the command signal is normally transmitted, but the monitor signal is not normally transmitted. That is, it can be determined that there is an abnormality in the monitor line. On the other hand, when the CPU 61 requests driving at the third speed, if the detection ratio indicates the gear ratio at the fifth speed, the command signal is likely not transmitted normally, that is, the command line It can be determined that there is a high possibility of abnormality.

  FIG. 7 is a waveform diagram showing the operation of the signal determination means 62a provided in the drive circuit 62 of the first embodiment. Command signal S1c is switched between on-voltage Von and off-voltage Voff when the electric circuit is normal. On the other hand, when there is an abnormality in the electric circuit, the voltage of the command signal S1c reaches the upper limit value and the lower limit value of the electric circuit. For example, when the command signal S1c reaches 5.0V that is the upper limit voltage or 0.0V that is the lower limit voltage, it can be determined that there is an abnormality in the electric circuit. The signal determination means 62a has a threshold value VH set between the ON voltage Von and the upper limit voltage, and a threshold value VL set between the OFF voltage Voff and the lower limit voltage. When the voltage of the command signal S1c exceeds the threshold value VH, the signal determination unit 62a determines that the command signal S1c is abnormal, that is, an electrical circuit is abnormal. When the voltage of the command signal S1c falls below the threshold value VL, the signal determination unit 62a determines whether the command signal S1c is abnormal, that is, an electrical circuit is abnormal. As described above, the signal determination unit 62a determines the abnormality of the electric circuit depending on whether or not the voltage level of the command signal S1c is within the predetermined range VL-VH.

  FIG. 8 is a waveform diagram showing an operation example of the control device 6 of the first embodiment. FIG. 8A shows the voltage level of the terminal COM, that is, the command signal S1c output from the CPU 61. FIG. 8B shows the voltage level of the terminal IN1, that is, the command signal S1c input to the drive circuit 62. FIG. 8C shows the voltage level of the terminal BAK, that is, the backup signal S1b output from the CPU 61. FIG. 8D shows the voltage level of the terminal DG, that is, the monitor signal S1m output from the drive circuit 62. FIG. 8E shows the voltage level of the terminal OUT, that is, the output current S1out supplied from the drive circuit 62 to the solenoid S1.

  Between time t0 and time t1, the device functions normally. At this time, the drive circuit 62 executes energization to the solenoid S1 in response to the command signal S1c.

  At time t1, disconnection occurs in the signal transmission circuit (command line) of the command signal S1c. As a result, the voltage level of the terminal IN1 is lowered to 0.0V. The decrease in the voltage level of the terminal IN1 is detected by the signal determination unit 62a. In response to this, the control switching means 62b switches the internal function of the drive circuit 62 so that the drive circuit 62 executes energization to the solenoid S1 in response to the backup signal S1b. As a result, the output current S1out is controlled in accordance with the backup signal S1b. The monitor signal S1m changes so as to coincide with the command signal S1c and the backup signal S1b. For example, when the command signal S1c and the backup signal S1b are switched at time t2, the output current S1out is also switched accordingly.

  At time t3, the disconnection is repaired and the normal state is restored. At this time, the signal determination unit 62a detects the return of the voltage level of the terminal IN1. In response to this, the control switching means 62b switches the internal function of the drive circuit 62 so that the drive circuit 62 executes energization to the solenoid S1 in response to the command signal S1c. As a result, the output current S1out is controlled in accordance with the command signal S1c. As a result, the device functions normally between time t3 and time t4.

  At time t4, a short circuit occurs in the signal transmission circuit (command line) of the command signal S1c. As a result, the voltage level of the terminal IN1 rises to 5.0V. An increase in the voltage level of the terminal IN1 is detected by the signal determination means 62a. In response to this, the control switching means 62b switches the internal function of the drive circuit 62 so that the drive circuit 62 executes energization to the solenoid S1 in response to the backup signal S1b. As a result, the output current S1out is controlled in accordance with the backup signal S1b. The monitor signal S1m changes so as to coincide with the command signal S1c and the backup signal S1b. For example, when the command signal S1c and the backup signal S1b are switched at time t5, the output current S1out is also switched accordingly.

  At time t6, the short circuit is repaired and the normal state is restored. At this time, the signal determination unit 62a detects the return of the voltage level of the terminal IN1. In response to this, the control switching means 62b switches the internal function of the drive circuit 62 so that the drive circuit 62 executes energization to the solenoid S1 in response to the command signal S1c. As a result, the output current S1out is controlled in accordance with the command signal S1c. As a result, after time t6, the device functions normally.

  As described above, in this embodiment, in addition to the command signal S1c, a backup signal S1b having the same information as the command signal S1c but having a different signal property and a different signal transmission circuit is output from the CPU 61 to the drive circuit 62. It was configured as follows. Further, the drive circuit 62 is provided with a signal determination means 62a for determining whether the command signal S1c is abnormal. When the command signal S1c is abnormal, the drive circuit 62 is configured to drive the solenoid S1 in response to the backup signal S1b instead of the command signal S1c. . As a result, even if an abnormality occurs in the signal transmission circuit of the command signal S1c, the drive of the solenoid can be continued in response to the backup signal S1b.

  Further, it is possible to switch between the command signal S1c and the backup signal S1b in the drive circuit 62, and as a result, quick switching is possible. If an abnormality is detected in the CPU 61 and the CPU 61 instructs the drive circuit 62 to switch from the command signal S1c to the backup signal S1b, the output takes a value that does not correspond to the command for a long time required for such processing. It becomes. More specifically, the CPU 61 includes (1) a processing step for detecting a mismatch between the command signal S1c and the monitor signal S1m, (2) a processing step for determining a circuit abnormality based on the mismatch, and (3 And a processing step of transmitting a trigger signal for instructing switching from the command signal S1c to the backup signal S1b from the CPU 61 to the drive circuit 62 based on the abnormality determination. The drive circuit 62 is provided with a circuit that receives the trigger signal and performs switching from the command signal S1c to the backup signal S1b. In such a configuration, the CPU 61 indicates the output current S1out, which is the operating state of the actuator, and it is abnormal until the monitor signal S1m input to the terminal MON becomes different from the command signal S1c output from the terminal COM. Cannot be recognized. Furthermore, until the CPU 61 transmits a trigger signal and the drive circuit 62 executes switching from the command signal S1c to the backup signal S1b, the state in which the command signal S1c output to the terminal COM does not match the output current S1out continues. As the trigger signal, a signal line dedicated to the trigger signal may be provided, or an existing signal line, for example, a signal line for the backup signal S1b may be used. On the other hand, according to this embodiment, since an abnormality is detected based on the analog signal level of the command signal S1c input to IN1 in the drive circuit 62, the output current S1out does not correspond to the command signal S1c. Even if not, abnormality detection is possible by the drive circuit 62. When the signal transmission circuit for the command signal S1c is normal, the command signal S1c output from the CPU 61 to the terminal COM and the output current S1out indicating the operating state of the actuator have a predetermined correspondence relationship. On the other hand, when the signal transmission circuit of the command signal S1c is abnormal, the signal can be switched in the drive circuit 62. Therefore, the backup signal S1b output from the CPU 61 to the terminal BAK and the output current S1out indicating the operating state of the actuator have the predetermined correspondence. It should be noted that the signal determination means 62a and the control switching means 62b provided in the drive circuit 62 are such that the command signal S1c and the CPU 61 that the CPU 61 outputs to the terminal COM even if the signal transmission circuit of the command signal S1c becomes abnormal. The command signal S1c is switched to the backup signal S1b with a sufficiently fast response so that the backup signal S1b output to the output signal S1b does not differ from the output current S1out indicating the operating state of the actuator. As a result, the abnormality can be detected earlier, and the switching from the command signal S1c to the backup signal S1b is executed without the command signal S1c output from the CPU 61 to the terminal COM being different from the output current S1out indicating the operating state of the actuator. be able to.

  Further, the CPU 61 determines whether or not the automatic transmission 4 is normally shifted to perform a normal function in addition to determining an abnormality of the electric circuit based on the comparison between the command signal S1c and the monitor signal S1m. The abnormal part of the electric circuit is estimated by using the function judgment together. As a result, it is possible to take appropriate countermeasures that differ depending on the abnormal part. In particular, in the embodiment, when the signal transmission circuit (command line) of the command signal S1c is abnormal, the output of the command signal S1c is stopped and the normal control of the automatic transmission 4 is stopped. On the other hand, when there is an abnormality in the signal transmission circuit of the monitor signal S1m, normal control of the automatic transmission 4 is continued without stopping the output of the command signal S1c. Thereby, it is possible to execute an appropriate countermeasure according to the abnormal part of the electric circuit.

  Further, in this embodiment, even if there is an abnormality in the command line, the drive according to the backup signal S1b is continued by the signal determination means 62a and the control switching means 62b provided in the drive circuit 62. A normal monitor signal S1m is output from the terminal DG. For this reason, it is avoided that the command signal S1c is stopped by the circuit determination means 61a in the CPU 61. As a result, it is possible to avoid taking countermeasures excessively due to an abnormality in the electric circuit.

  Further, even if a situation occurs in which the command signal S1c and the monitor signal S1m do not coincide with each other, when the functional normality is still determined by the function determination unit 61b, the output of the command signal S1c is continued. The normal control of the automatic transmission 4 is continued. This prevents the CPU 61 from stopping the command signal S1c. As a result, it is possible to avoid taking countermeasures excessively due to an abnormality in the electric circuit.

  On the other hand, when a situation occurs in which the command signal S1c and the monitor signal S1m do not coincide with each other, and when a functional abnormality is determined by the function determining unit 61b, an appropriate measure such as output stoppage by the countermeasure processing unit 61c. Measures are taken.

  Furthermore, in this embodiment, the solenoid S1 also serves as a fail-safe solenoid. Therefore, when only the monitor line is abnormal, excessive countermeasures for the fail-safe solenoid S1 are avoided, and the drive of the solenoid S1 is continued. As a result, the function stop of the fail-safe solenoid is suppressed, and the number of cases where the function is maintained can be increased.

  As described above, the control device 6 adjusts the energization state of the actuator 5 of the automatic transmission 4 in accordance with the command signal S1c output from the control means 61 and the monitor signal indicating the energization state of the actuator 5. A drive circuit 62 that outputs S1m toward the control means 61 is provided. Furthermore, the control device 6 can include a circuit determination unit 61a, a function determination unit 61b, and a countermeasure treatment unit 61c. The circuit determination means 61a determines an abnormality in an electric circuit including the signal transmission circuit for the command signal S1c and the signal transmission circuit for the monitor signal S1m based on the command signal S1c and the monitor signal S1m. The function determination unit 61b determines whether the function of the actuator 5 is normal or abnormal. The countermeasure processing means 61c provides different countermeasures depending on the abnormality. Here, depending on the case where the abnormality of the electric circuit is determined and the abnormality of the function of the actuator 5 is determined, and the case where the abnormality of the electric circuit is determined and the normality of the function of the actuator 5 is determined, Different countermeasures are provided. As a result, an abnormal state can be identified by a combination of circuit determination and function determination, and countermeasures can be provided according to the abnormal state.

  The countermeasure processing means 61c provides the first countermeasure 108 corresponding to the abnormality of the signal transmission circuit of the command signal S1c when the abnormality of the electric circuit is determined and the abnormality of the function of the actuator 5 is determined. . The countermeasure processing unit 61c provides a second countermeasure 105 corresponding to the abnormality of the signal transmission circuit of the monitor signal S1m when the abnormality of the electric circuit is determined and the function of the actuator 5 is determined to be normal. . The first countermeasure 108 is to stop the control of the automatic transmission 4 by the command signal S1c, and the second countermeasure 105 is to continue the control of the automatic transmission 4 by the command signal S1c. The function determination unit 61b determines whether the function of the actuator 5 is normal or abnormal depending on whether or not the actual transmission ratio (detection ratio) of the automatic transmission 4 is at a target transmission ratio (required ratio).

  Furthermore, the drive circuit 62 can be provided with signal determination means 62a for determining an abnormality of the command signal S1c input to the drive circuit 62. The drive circuit 62 can be provided with a control switching means 62b for controlling the energization state of the actuator 5 by alternative control without responding to the command signal S1c when the abnormality of the command signal S1c is determined. Thereby, the drive according to the command signal S1c can be switched to an alternative drive without interrupting the control of the actuator 5. In addition, when the command signal S1c is abnormal, the drive of the actuator 5 can be continued by alternative control, so that it is possible to avoid taking countermeasures such that normal control of the automatic transmission 4 is stopped.

  The signal determination means 62a can be configured to determine abnormality based on the voltage level of the command signal S1c. The backup signal S1b corresponding to the command signal S1c is configured to be supplied from the control unit 61 to the drive circuit 62, and the control switching unit 62b is configured to control the energization state of the actuator 5 in accordance with the backup signal S1b. can do.

(Second Embodiment)
FIG. 9 is a block diagram showing the entire control device 206 according to the second embodiment to which the present invention is applied. FIG. 10 is a block diagram illustrating a part of the control device 206 according to the second embodiment.

  In the preceding embodiment, high reliability is realized by using the command signal S1c and the backup signal S1b. Instead, this embodiment employs a configuration that does not employ the backup signal S1b.

  In this embodiment, a CPU 261 and a plurality of drive circuits 262 are employed. The CPU 261 does not output a backup signal. The CPU 261 does not include the terminal BAK. Further, the drive circuit 262 does not have a configuration that responds to a backup signal. The drive circuit 262 does not include the terminal IN2. Furthermore, the drive circuit 262 does not include a signal determination unit and a control switching unit.

  The CPU 61 executes the same process as in FIG. As a result, it is possible to take appropriate countermeasures that differ depending on the abnormal part. In particular, in this embodiment, when the signal transmission circuit (command line) of the command signal S1c is abnormal, the output of the command signal S1c is stopped and the normal control of the automatic transmission 4 is stopped. On the other hand, when there is an abnormality in the signal transmission circuit of the monitor signal S1m, normal control of the automatic transmission 4 is continued without stopping the output of the command signal S1c. Thereby, it is possible to execute an appropriate countermeasure according to the abnormal part of the electric circuit.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. The structure of the said embodiment is an illustration to the last, Comprising: The scope of the present invention is not limited to the range of these description. The scope of the present invention is indicated by the description of the scope of claims, and further includes meanings equivalent to the description of the scope of claims and all modifications within the scope.

  For example, in the above embodiment, the present invention is applied to the configuration related to the solenoid S1. Instead of this or in addition to this, the present invention may be applied to solenoids SL1, SL2, SL3, SL4, S2, and the like.

  Moreover, in the said embodiment, this invention was applied to the automatic transmission 4 which is not provided with a mechanical fail safe valve. Alternatively, the present invention may be applied to an automatic transmission that includes a mechanical fail-safe valve. The fail safe valve controls the automatic transmission 4 to a fail safe state when the actuator 5 is not controlled. In the fail-safe state, for example, the hydraulic control system is switched to a predetermined state, and the automatic transmission 4 is controlled to a predetermined shift state. In this configuration, when the output of the command signal S1c is stopped, the shift state of the automatic transmission 4 is controlled to a predetermined shift state by a mechanical fail-safe valve provided in the hydraulic control system. However, by adopting the configuration of the above embodiment, when only the signal transmission circuit for the monitor signal S1m is abnormal, normal control is continued without stopping the output of the command signal S1c. A fail-safe condition due to a typical fail-safe valve is avoided.

  In the above embodiment, the abnormality of the command signal S1c is determined based on the voltage level of the command signal S1c. Instead, the command signal S1c may be a high-frequency signal that switches periodically, and the abnormality of the command signal S1c may be determined based on the frequency of the command signal S1c.

  Further, the means and functions provided by the control device can be provided by software only, hardware only, or a combination thereof. For example, the control device may be configured by an analog circuit.

  DESCRIPTION OF SYMBOLS 1 Automatic transmission system for vehicles, 2 Power source, 3 Drive wheel, 4 Automatic transmission, 5 Actuator (solenoid), SL1, SL2, SL3, SL4, S1, S2 Solenoid, 6 Control device, 61 CPU, 62 Drive circuit 61a circuit determination means, 61b function determination means, 61c countermeasure treatment means, 62 drive circuit, 62a signal determination means, 62b control switching means, 7 rotation speed sensor, 8 rotation speed sensor, S1c command signal, S1b backup signal, S1m monitor Signal, S1out output current, Nin input rotation speed, Nout output rotation speed.

Claims (6)

In accordance with the command signal (S1c) output from the control means (61, 261), the energization state of the actuator (5) of the automatic transmission is adjusted, and the monitor signal (S1m indicating the energization state of the actuator (5) ) In a control device for an automatic transmission including a drive circuit (62, 262) that outputs the control signal to the control means,
Circuit determining means (61a) for determining an abnormality in an electric circuit including the signal transmission circuit for the command signal and the signal transmission circuit for the monitor signal based on the command signal (S1c) and the monitor signal (S1m); ,
A function determination means (61b) for determining whether the function of the actuator is normal or abnormal by determining whether or not the actual gear ratio of the automatic transmission (4) is at a target gear ratio ;
When the circuit determination unit determines that the abnormality of the electric circuit is determined, and the function determination unit determines the abnormality of the function of the actuator, the circuit determination unit determines the abnormality of the electric circuit, and the function depending on the case where the normal is determined in function of the actuator by determining means, the control device for an automatic transmission, characterized in that it comprises a protection treatment means to provide different measures treatment respectively (61c). The countermeasure processing means is:
When the abnormality of the electric circuit is determined and the abnormality of the function of the actuator is determined, a first countermeasure (108) corresponding to the abnormality of the signal transmission circuit of the command signal is provided,
When the abnormality of the electric circuit is determined and the normality of the function of the actuator is determined, a second countermeasure (105) corresponding to the abnormality of the signal transmission circuit of the monitor signal is provided. The control device for an automatic transmission according to claim 1. The first countermeasure measure (108) is a stop of control of the automatic transmission by the command signal,
3. The automatic transmission control device according to claim 2, wherein the second countermeasure measure (105) is continuation of control of the automatic transmission by the command signal. Furthermore, a signal determination means (62a) provided in the drive circuit (62, 262) for determining an abnormality of the command signal input to the drive circuit;
Control switching means (62b) provided in the drive circuit and configured to control the energization state of the actuator by alternative control without responding to the command signal when it is determined that the command signal is abnormal. The control device for an automatic transmission according to any one of claims 1 to 3 , characterized in that: The control apparatus for an automatic transmission according to claim 4 , wherein the signal determination means (62a) determines abnormality based on a voltage level of the command signal. A backup signal (S1b) corresponding to the command signal is configured to be supplied from the control means to the drive circuit,
The automatic transmission control device according to claim 4 or 5 , wherein the control switching means (62b) controls an energization state of the actuator in accordance with the backup signal.

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