JP2013252801A - Control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device capable of returning a function part to a normal state when an abnormality occurs in voltage value supplied to the function part.SOLUTION: A CPU 101 determines whether or not a voltage value of a driving voltage Vcc2 applied on a GDC 102 from a power source module 107 belongs to a first range, and executes initialization processing for initializing the driving of the GDC 102 when determining that the voltage value of the driving voltage Vcc2 does not belong to the first range.

Description

  The present invention relates to a control device.

  Generally, when starting the engine of a vehicle, cranking is performed (for example, refer patent document 1). Cranking means that a microcomputer mounted on the engine control device detects an ON input of a start switch, turns on a starter relay in a drive circuit, and supplies a voltage from a battery to the starter. As a result, the starter is driven and the vehicle engine is started.

  Since the voltage is supplied from the battery to the starter when the engine is started due to the cranking, the voltage supplied to a device other than the starter connected to the battery, for example, the vehicle-mounted device, etc. temporarily decreases rapidly. That is, since the voltage is supplied from the battery to the starter when the engine is started, the voltage supplied to the device that has already been supplied with the voltage by turning on the accessory power switch at the time when the voltage is supplied to the starter suddenly increases. To drop.

JP 2009-83654 A

  Some vehicle-mounted devices used by being mounted on a vehicle have various functions such as a navigation function. Among the functional units that realize these various functions, there are units (for example, a liquid crystal display unit) that are driven by a voltage supplied from a battery. The functional unit that is driven by being supplied with the voltage from the battery as described above may stop driving when the voltage supplied from the battery is reduced when the engine is started for the reason described above. In a conventional on-vehicle device, once the function is stopped, the function unit can return to the normal state even when the supply of voltage from the battery to the starter is stopped and the voltage supplied from the battery returns to the normal voltage value. There wasn't.

  The present invention has been made in view of the above-described circumstances, and provides a control device capable of returning a functional unit to a normal state when an abnormality occurs in a voltage value supplied to the functional unit. It is an object.

In order to achieve the above-described object, a control device according to the present invention is characterized by the following (1) to (4).
(1) a functional unit that is driven by applying a first drive voltage;
A control unit for controlling the functional unit;
A first drive voltage generator that applies an applied voltage from an external power source and applies the first drive voltage to the functional unit;
With
The control unit determines whether or not a voltage value of the first drive voltage applied from the first drive voltage generation unit to the functional unit belongs to a first range, and the first drive voltage If it is determined that the voltage value does not belong to the first range, an initialization process for initializing the driving of the functional unit is executed.
about.
(2) A control device configured as described in (1) above,
A second drive voltage generator for applying a second drive voltage to the controller by applying an applied voltage from an external power source and driving the controller;
The functional unit is driven by being applied with the first driving voltage having a voltage value belonging to the first range,
The control unit is driven by being applied with the second drive voltage having a voltage value belonging to a second range,
A normal applied voltage required to apply the first drive voltage belonging to the first range to the function unit is not applied to the first drive voltage generation unit, and belongs to the second range. When a normal applied voltage required to apply the second driving voltage to the control unit is applied to the second driving voltage generating unit, the second driving voltage generating unit moves from the second driving voltage generating unit to the second range. Whether the control unit to which the second driving voltage belongs belongs to whether the voltage value of the first driving voltage applied from the first driving voltage generation unit to the functional unit belongs to the first range. Determining whether or not the voltage value of the first drive voltage does not belong to the first range, an initialization process for initializing the drive of the functional unit is executed.
about.
(3) a functional unit that is driven by applying the first drive voltage;
A control unit for controlling the functional unit;
A first drive voltage generator that applies an applied voltage from an external power source and applies the first drive voltage to the functional unit;
The first drive voltage applied from the first drive voltage generation unit to the functional unit is detected, and it is determined whether or not the detected voltage value of the first drive voltage belongs to the first range. A determination unit that outputs a determination result to the control unit;
With
When the control unit receives from the determination unit the determination result when it is determined that the voltage value of the first drive voltage does not belong to the first range, the function unit is initially driven Execute initialization processing to
about.
(4) a functional unit that is driven by applying the first drive voltage;
A control unit for controlling the functional unit;
A first drive voltage generator that applies an applied voltage from an external power source and applies the first drive voltage to the functional unit;
With
The control unit converts the first drive voltage that is applied to the first drive voltage generator from the external power source, and the first drive voltage generator belongs to the first range. If the voltage value of the applied voltage does not belong to the normal range, the initialization process is executed. To
about.

In the control device configured as described in (1) above, when the control unit determines that the voltage value of the first drive voltage applied from the first drive voltage generation unit to the functional unit does not belong to the first range. First, an initialization process for initializing the drive of the functional unit is executed. Thus, when the voltage value of the first drive voltage applied to the function unit does not belong to the first range, the drive of the function unit is initialized.
In the control device having the configuration (2), a normal applied voltage required to apply the first drive voltage belonging to the first range to the functional unit is not applied to the first drive voltage generating unit, and When a normal applied voltage required to apply the second drive voltage belonging to the second range to the control unit is applied to the second drive voltage generator, the first drive voltage generator to the functional unit When the voltage value of the applied first drive voltage does not belong to the first range, an initialization process for initializing the drive of the functional unit is executed. Thus, when the voltage value of the first drive voltage applied to the function unit does not belong to the first range, the drive of the function unit is initialized.
In the control device having the configuration (3), when the determination unit determines that the voltage value of the first drive voltage applied from the first drive voltage generation unit to the function unit does not belong to the first range. First, an initialization process for initializing the drive of the functional unit is executed. Thus, when the voltage value of the first drive voltage applied to the function unit does not belong to the first range, the drive of the function unit is initialized.
In the control device having the above configuration (4), when the control unit determines that the voltage value of the applied voltage applied from the external power supply to the first drive voltage generation unit does not belong to the normal range, An initialization process for initializing the drive of the unit is executed. As a result, when the voltage value of the applied voltage applied from the external power supply to the first drive voltage generation unit does not belong to the normal range, the drive of the functional unit is initialized.

  According to the control device of the present invention, it is possible to provide a control device capable of returning the function unit to a normal state when an abnormality occurs in the voltage value supplied to the function unit.

  The present invention has been briefly described above. Furthermore, the details of the present invention will be further clarified by reading through a mode for carrying out the invention described below (hereinafter referred to as “embodiment”) with reference to the accompanying drawings. .

FIG. 1 is a block diagram illustrating a hardware configuration example of the display device 100 according to the first embodiment. FIG. 2 is a time chart illustrating an example of changes in the voltage value and the reset signal in each unit of the display device 100 illustrated in FIG. 1. FIG. 3 is a block diagram showing a hardware configuration example of a conventional display device 200 shown as a comparative example. FIG. 4 is a time chart showing an example of changes in voltage value and reset signal in each part of the conventional display device 200 shown in FIG. FIG. 5 is a block diagram illustrating a hardware configuration example of the display device 300 according to the second embodiment. FIG. 6 is a block diagram illustrating a hardware configuration example of the display device 400 according to the third embodiment.

  Specific embodiments relating to a display device realized by including a control device according to the present invention will be described below with reference to the drawings.

(First embodiment)
The display device 100 according to the first embodiment is mounted on a vehicle such as an automobile, for example, and has an information presentation function for presenting various types of information to a user.

FIG. 1 is a block diagram illustrating a hardware configuration example of the display device 100 according to the first embodiment.
As shown in FIG. 1, a display device 100 includes a microcomputer (CPU: Central Processing Unit) 101, a graphic display controller (GDC) 102, and a liquid crystal display (TFT-LCD: Thin Film Transistor Liquid Crystal Display). 103, a power supply IC (Integrated Circuit) 104, an interface (I / O) 105, an interface 106, and a power supply module 107. Below, each of these structures is demonstrated first.

  The CPU 101 as the control unit executes a program prepared in advance and performs various processes necessary for realizing the functions of the display device 100. For example, a command for determining the display content of the liquid crystal display 103 is output to the GDC 102 to control the display content of the liquid crystal display 103. Further, the CPU 101 outputs an ON signal to the power supply module 107 from the port P2, and causes the power supply module 107 to apply a drive voltage Vcc2 described later to the GDC 102. Further, the CPU 101 outputs an ON signal to the power supply module 107 from each of the port P3 and the port P4, and causes the power supply module 107 to apply a drive voltage Vcc3 and a drive voltage Vcc4 described later to the GDC 102. Further, the CPU 101 outputs a reset signal RST2 for resetting the data held in the GDC 102 to an initial value from the port P0 to the GDC 102, and causes the GDC 102 to execute data reset processing. More specifically, the CPU 101 switches between a high signal and a low signal as the reset signal RST2 and outputs the signal to the GDC 102, and causes the GDC 102 to execute a reset process using a switching point from the low signal to the high signal as a trigger. The CPU 101 is driven by applying a drive voltage Vcc1 from a power supply IC 104 described later. The CPU 101 in the first embodiment is driven when the rated voltage is 3V DC and the voltage value of the applied drive voltage Vcc1 is in the range of 2.9V to 3.1V (second range). . In the following description, all voltages referred to in the present specification are all DC voltages unless explicitly stated that they are AC voltages. The CPU 101 receives a reset signal RST1 from the power supply IC 104. When the received reset signal RST1 is switched from a low signal to a high signal, the CPU 101 initializes driving of the entire display device 100 including the CPU 101. In addition, the CPU 101 receives an ignition switch on / off signal from the port P <b> 5 via the interface 105. In addition, the CPU 102 receives a CAN signal including various information related to the vehicle from the communication network (CAN: Controller Area Network) on the vehicle via the interface 106. CPU101 determines the display content of the liquid crystal display 103 using the various information regarding the said vehicle.

  The CPU 101 receives the voltage value of the drive voltage Vcc2 applied to the GDC 102 from the port P1. The CPU 101 determines whether or not the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 belongs to the first range based on the drive voltage Vcc2 received from the port P1, and the voltage value of the drive voltage Vcc2 Is determined not to belong to the first range, an initialization process for initializing the drive of the GDC 102 is executed. Details of this initialization process will be described later.

  The GDC 102 as a functional unit displays graphic elements representing various information presented to the user on the screen of the liquid crystal display 103 in accordance with various commands input from the CPU 101. That is, the GDC 102 is a functional unit for exhibiting an information presentation function. The GDC 102 is driven by applying a driving voltage Vcc2, a driving voltage Vcc3, and a driving voltage Vcc4 in this order from a power supply module 107 described later. The GDC 102 in the first embodiment has a rated voltage of 5V, and the applied drive voltage Vcc2, drive voltage Vcc3, and drive voltage Vcc4 have voltage values of 4.9V to 5.1V (first range). Drive in case. The GDC 102 receives a reset signal RST2 from the CPU 101. The GDC 102 resets the held data to the initial value when the received reset signal RST2 is switched from the low signal to the high signal. That is, when the GDC 102 detects that the reset signal RST2 is switched from the low signal to the high signal after the drive voltage Vcc2, the drive voltage Vcc3, and the drive voltage Vcc4 whose voltage values belong to the first range are applied in this order, Data reset processing is executed and driving is started. In other words, the drive voltage Vcc2, the drive voltage Vcc3, and the drive voltage Vcc4 whose voltage values belong to the first range are applied according to the predetermined order as the power-on sequence, and the accepted reset signal RST2 is changed from the low signal to the high signal. Only when the signal is switched, the GDC 102 starts to drive normally.

  The liquid crystal display 103 has a color display screen in which a large number of minute display cells constituted by liquid crystal devices are arranged in the X direction and the Y direction. By individually controlling the display states of a large number of minute display cells for each cell, desired information such as graphics, characters, images, etc. can be displayed on the two-dimensional display screen.

  The power supply IC 104 is driven by applying an applied voltage + B from a battery (not shown) mounted on a vehicle as an external power supply, and applies a drive voltage Vcc1 for driving the CPU 101 to the CPU 101. The power supply IC 104 in the first embodiment operates normally when the voltage value of the applied voltage + B applied is in the range of 5.5V to 40V (fourth range), and drives the CPU 101. A drive voltage Vcc1 having a voltage value (for example, 3 V) belonging to the range of 2 is applied to the CPU 101. However, although the voltage value of the applied voltage + B applied from the battery is normally 12V, there is a possibility that it may decrease to, for example, 7V when the engine is started (at the time of reduction) due to the influence of the cranking described above. When the voltage of the applied voltage + B decreases in this way, the voltage value (7V) of the applied voltage + B at the time of the decrease belongs to the fourth range. Therefore, the power supply IC 104 uses the voltage of the applied voltage + B applied from the battery. Even if the value drops to 7V, it operates normally. That is, the power supply IC 104 applies the drive voltage Vcc1 of the voltage value belonging to the second range, which drives the CPU 101, even when the voltage value of the applied voltage + B applied from the battery drops to 7V. . Further, the power supply IC 104 outputs a reset signal RST1 that initializes driving of the CPU 101 to the CPU 101. More specifically, the power supply IC 104 switches between a high signal and a low signal as the reset signal RST1 and outputs it to the CPU 101.

  The power supply module 107 is driven by applying an applied voltage + B from a battery which is an external power supply common to the power supply IC 104. The power supply module 107 applies a drive voltage Vcc2 for driving the GDC 102 to the GDC 102 when an ON signal is received from the CPU 101 via the port P2. The power supply module 107 in the first embodiment operates normally when the voltage value of the applied voltage + B applied is in the range of 9.0 V to 16 V (third range), and drives the GDC 102. A drive voltage Vcc <b> 2 having a voltage value (for example, 5 V) belonging to the first range is applied to the GDC 102. Therefore, since the voltage value (7V) of the applied voltage + B at the time of the reduction does not belong to the third range, the power supply module 107 is configured so that when the voltage value of the applied voltage + B applied from the battery is reduced to 7V, It does not work properly. That is, when the voltage value of the applied voltage + B applied from the battery drops to 7V, the power supply module 107 applies to the GDC 102 the drive voltage Vcc2 that does not belong to the first range, for example, the voltage value is 0V. Further, when the power supply module 107 accepts an ON signal from the CPU 107 via the port P3 and the port P4, the power supply module 107 applies a drive voltage Vcc3 and a drive voltage Vcc4 for driving the GDC 102 corresponding to the ON signal to the GDC 102. To do. The power supply module 107 according to the first embodiment drives the GDC 102 when the applied voltage + B is applied from the battery, and drives the drive voltage Vcc3 having a voltage value (for example, 5 V) belonging to the first range. The voltage Vcc4 is applied to the GDC 102.

Next, a specific operation of the display device 100 will be described with reference to FIG.
FIG. 2 is a time chart illustrating an example of changes in the voltage value and the reset signal in each unit of the display device 100 illustrated in FIG. 1. More specifically, FIG. 2 shows, in order from the top, the voltage applied by the battery + B, the drive voltage Vcc1 applied to the CPU 101, the reset signal RST1 input to the CPU 101, the drive voltage Vcc2 applied to the GDC 102, and the GDC The time series data shows an example of changes in the drive voltage Vcc3 applied, the drive voltage Vcc4 applied to the GDC102, the reset signal RST2 input to the GDC102, and the drive voltage Vcc2 received by the CPU 101 from the port P1. Symbol t1 indicates time t1 when the CPU 101 starts driving, symbol t2 indicates time t2 when the GDC 102 starts driving, and symbol t3 indicates when the voltage value of the applied voltage + B is lower than 12V in the normal time. A time t3 when the voltage is decreased to 7V is indicated, and a reference t4 indicates a time t4 when the voltage value of the applied voltage + B is restored from 7V when the voltage is decreased to 12V when the voltage is normal.

  First, changes in voltage values and reset signals in each unit of the display device 100 after the accessory power switch is turned on until the CPU 101 and the GDC 102 are driven will be described.

  When the accessory power switch is turned on by the user, an applied voltage + B having a voltage value of 12 V is applied from the battery to the power supply IC 104 and the power supply module 107. The power supply IC 104 to which the applied voltage + B of 12V that is the voltage value belonging to the fourth range is applied applies the drive voltage Vcc1 of 3V that is the voltage value belonging to the second range to the CPU 101. Next, the power supply IC 104 switches the reset signal RST1 output to the CPU 101 from a low signal to a high signal. The CPU 101 that has detected switching of the reset signal RST1 from the low signal to the high signal executes initialization of the CPU 101 and starts driving (time t1).

  The CPU 101 that has started driving outputs an ON signal to the power supply module 107 in this order from the port P2, the port P3, and the port P4. First, the power supply module 107 that has received the ON signal from the port P <b> 2 applies a drive voltage Vcc <b> 2 of 5 V that is a voltage value belonging to the first range to the GDC 102. After that, the power supply module 107 that has received the ON signal from the port P3 applies a drive voltage Vcc3 of 5 V, which is a voltage value belonging to the first range, to the GDC 102. After that, the power supply module 107 that has received the ON signal from the port P4 applies a drive voltage Vcc4 of 5 V, which is a voltage value belonging to the first range, to the GDC 102. Next, the CPU 101 switches the reset signal RST2 output to the GDC 102 from a low signal to a high signal. The GDC 102 that has detected the switching of the reset signal RST2 from the low signal to the high signal executes a data reset process and starts driving (time t2). As described above, the drive voltage Vcc2, the drive voltage Vcc3, and the drive voltage Vcc4 whose voltage values belong to the first range are applied in an order that conforms to the power-on sequence, and the received reset signal RST2 is switched from the low signal to the high signal. The received GDC 102 starts driving.

As described above, the CPU 101 and the GDC 102 are driven when the voltage value and the reset signal in each part of the display device 100 change.
Next, the ignition switch is turned on while the CPU 101 and the GDC 102 are driven, the voltage value of the battery applied voltage + B is temporarily reduced, and then the battery applied voltage + B is restored to the normal voltage value. The change in the voltage value and the reset signal in each part of the display device 100 will be described.

  When the ignition switch is turned on by the user, the engine is started. As described above, when the engine is started, a voltage is supplied from the battery to the starter, so that the voltage value of the applied voltage + B of the battery may rapidly decrease from 12 V in the normal time to 7 V in the time of the decrease. When the applied voltage + B of the battery decreases, the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 is a voltage that does not belong to the first range from 5 V that is the voltage value belonging to the first range. It temporarily drops to the value 0V. The GDC 102 in which the voltage value of the applied drive voltage Vcc2 has been reduced to 0 V stops driving (time t3). At this time, the power supply IC 104 to which the applied voltage + B of 7 V, which is a voltage value belonging to the fourth range, is applied from the battery continues to operate normally. Further, the CPU 101 to which the driving voltage Vcc1 of 3V that is a voltage value belonging to the second range is applied continues to operate normally. That is, when the applied voltage + B of the battery decreases at the time of starting the engine, the normal applied voltage + B (the voltage value belongs to the third range) required to apply the drive voltage Vcc2 belonging to the first range to the GDC 102 The applied voltage + B) is not applied to the power supply module 107, and the normal applied voltage + B (the voltage value belongs to the fourth range) required to apply the drive voltage Vcc1 belonging to the second range to the CPU 101. Voltage + B) is applied to the power supply IC 104.

  When the voltage value of the drive voltage Vcc2 applied to the GDC 102 decreases from 5V to 0V, the voltage value of the drive voltage Vcc2 that the CPU 101 receives from the port P1 also decreases from 5V to 0V (time t3). At this time, the CPU 101 determines that the voltage value of the drive voltage Vcc2 does not belong to the first range. The CPU 101 that has determined that the voltage value of the drive voltage Vcc2 does not belong to the first range executes an initialization process that initializes driving of the GDC 102 described below.

  In the initialization process, first, when the CPU 101 determines that the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range, the CPU 101 changes the reset signal RST2 output to the GDC 102 from the high signal. Switch to low signal. Next, the CPU 101 stops the output of the ON signal to the power supply module 107 via the port P4, the port P3, and the port P2 in this order, and the drive voltage Vcc4, the drive voltage Vcc3, and the drive voltage applied from the power supply module 107 to the GDC 102 The voltage value of Vcc2 is decreased from 5V to 0V in this order. As described above, the reset signal RST2 is switched from the high signal to the low signal in an order suitable for the power-off sequence reverse to the power-on sequence, and the applied drive voltage Vcc4, drive voltage Vcc3, and drive voltage Vcc2 voltage values. Decreases.

  Thereafter, the CPU 101 resumes the output of the ON signal to the power supply module 107 via the port P2, the port P3, and the port P4 in this order, and the drive voltage Vcc2, the drive voltage Vcc3, the drive voltage applied from the power supply module 107 to the GDC 102 The voltage value of Vcc4 is increased from 0V to 5V in this order. Then, the CPU 101 switches the reset signal RST2 output to the GDC 102 from a low signal to a high signal. The GDC 102 that has detected that the reset signal RST2 has switched from the low signal to the high signal executes a data reset process and starts driving. As described above, the drive voltage Vcc2, the drive voltage Vcc3, and the drive voltage Vcc4 whose voltage values belong to the first range are applied in an order that conforms to the power-on sequence, and the received reset signal RST2 is switched from the low signal to the high signal. The GDC 102 thus started normally starts driving.

  When the applied voltage + B of the battery is reduced at the time of starting the engine and the supply of voltage from the battery to the starter is stopped after the engine is started, the voltage value of the applied voltage + B of the battery is reduced from 7V at the time of reduction to 12V at the normal time. (Time t4). As a result, the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 increases from 0V to 5V. Since the time from the fall of the applied voltage + B of the battery to the recovery, that is, the time from the time t3 to the time t4 is generally very short, the CPU 101 starts executing the initialization process at the time t3 as described above. Thereafter, the voltage value of the drive voltage Vcc2 increases to 5 V until the processing in the power-off sequence in the initialization processing is completed. For this reason, after executing the processing in the power-off sequence, the CPU 101 can execute the processing in the power-on sequence in the initialization processing to cause the GDC 102 to start driving normally. If there is a possibility that the time from the decrease in the applied voltage + B of the battery to the recovery will increase, the CPU 101 determines that the applied voltage + B in the battery has decreased and recovered, and then the power-off sequence in the initialization process. It is good also as a structure which starts execution of.

  As described above, even if the voltage value of the drive voltage + B supplied from the battery is lowered and the drive is once stopped due to the change of the voltage value and the reset signal in each part of the display device 100, the GDC 102 When the drive voltage + B supplied from the battery returns to the normal voltage value, the drive starts normally.

  The operation and effect of the display device 100 according to the first embodiment including the control device of the present invention will be described.

(Comparative example)
In order to describe the operation and effect of the display device 100 according to the first embodiment, first, as a comparative example, the display device 100 when the CPU 101 does not accept the voltage value of the drive voltage Vcc2 applied to the GDC 102 from the port P1. Will be described.

  FIG. 3 is a block diagram showing a hardware configuration example of a conventional display device 200 shown as a comparative example. The conventional display device 200 shown in FIG. 3 has the same configuration as the display device 100 according to the first embodiment, except that the CPU 101 does not accept the voltage value of the drive voltage Vcc2 applied to the GDC 102 from the port P1. Therefore, hereinafter, the same components are denoted by the same reference numerals as those of the display device 100 according to the first embodiment, and description of each component is omitted.

  A specific operation of the conventional display device 200 will be described with reference to FIG. FIG. 4 is a time chart showing an example of changes in voltage value and reset signal in each part of the conventional display device 200 shown in FIG.

  After the accessory power switch is turned on, until the CPU 101 and the GDC 102 are driven, that is, until time t2, the change in voltage value and reset signal in each part of the display device 200 is the case of the display device 100 according to the first embodiment. Since it is the same, description is abbreviate | omitted.

  Next, when the CPU 101 and the GDC 102 are driven, a voltage is supplied from the battery to the starter, so that the voltage value of the applied voltage + B of the battery decreases, and then the applied voltage of the battery + B is the normal voltage value. A description will be given of changes in the voltage value and the reset signal in each part of the display device 200 when the operation returns to step S2.

  As described above, when the engine is started, a voltage is supplied from the battery to the starter, so that the voltage value of the applied voltage + B of the battery may rapidly decrease from 12 V in the normal time to 7 V in the time of the decrease. When the applied voltage + B of the battery decreases, the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 is a voltage that does not belong to the first range from 5 V that is the voltage value belonging to the first range. The value drops to 0V, which is the value (time t3). The GDC 102 in which the voltage value of the applied drive voltage Vcc2 has been reduced to 0 V stops driving (time t3). At this time, the power supply IC 104 to which the applied voltage + B of 7 V, which is a voltage value belonging to the fourth range, is applied from the battery continues to operate normally. Further, the CPU 101 to which the driving voltage Vcc1 of 3V that is a voltage value belonging to the second range is applied continues to operate normally.

  When the applied voltage + B of the battery is reduced at the time of starting the engine and the supply of voltage from the battery to the starter is stopped after the engine is started, the voltage value of the applied voltage + B of the battery is reduced from 7V at the time of reduction to 12V at the normal time. (Time t4). As a result, the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 increases from 0V to 5V. At this time, the drive voltage Vcc2, the drive voltage Vcc3, and the drive voltage Vcc4 whose voltage values belong to the first range are applied to the GDC 102. However, since these drive voltages are not applied in the order suitable for the power-on sequence, the GDC 102 cannot start driving normally, and the operation becomes unstable or cannot operate normally.

  As described above, in the conventional display device 200, when the voltage value of the drive voltage + B supplied from the battery is lowered and the drive is once stopped, the GDC 102 normally uses the drive voltage + B supplied from the battery. Even if it returned to the voltage value of, it could not return to the normal state. On the other hand, in the display device 100 according to the first embodiment, the GDC 102 is supplied from the battery even when the drive voltage + B voltage value supplied from the battery decreases and the drive is temporarily stopped. When the driving voltage + B is restored to the normal voltage value, the driving can be started normally.

That is, the display device 100 according to the first embodiment includes a GDC 102 as a functional unit that is driven by being applied with a driving voltage Vcc2 as a first driving voltage, a CPU 101 as a control unit that controls the GDC 102, and an external power source. And a power supply module 107 serving as a first drive voltage generator for applying the drive voltage Vcc2 to the GDC 102. The CPU 101 determines whether or not the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 belongs to the first range, and determines that the voltage value of the drive voltage Vcc2 does not belong to the first range. In such a case, an initialization process for initializing driving of the GDC 102 is executed.
In the display device 100 according to the first embodiment, when the CPU 101 determines that the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range, the GDC 102 is initialized. Processing is executed. Thereby, when the voltage value of the drive voltage Vcc2 applied to the GDC 102 does not belong to the first range, the drive of the GDC 102 is initialized.
Therefore, according to the display device 100 according to the first embodiment, when the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range required to drive the GDC 102. That is, when an abnormality occurs in the voltage value supplied to the GDC 102, the driving of the GDC 102 can be initialized. As a result, according to the display device 100 according to the first embodiment, it is possible to provide a control device capable of returning the GDC 102 to a normal state when an abnormality occurs in the voltage value supplied to the GDC 102.

In addition, the display device 100 according to the first embodiment further includes a power supply IC 104 as a second drive voltage generator that applies the drive voltage Vcc1 for driving the CPU 101 to the CPU 101 when the applied voltage + B is applied by the battery. I have. The GDC 102 is driven by applying the drive voltage Vcc2 having a voltage value belonging to the first range, and the CPU 101 is driven by being applied with the drive voltage Vcc1 having a voltage value belonging to the second range. The normal applied voltage + B required for applying the drive voltage Vcc2 belonging to the first range to the GDC 102 (the applied voltage + B belonging to the third range) is not applied to the power supply module 107, and the second When a normal application voltage + B (application voltage + B whose voltage value belongs to the fourth range) required to apply the drive voltage Vcc1 belonging to the range to the CPU 101 is applied to the power supply IC 104, the power supply IC 104 changes to the second range. The CPU 101 to which the drive voltage Vcc1 to which it belongs is determined whether or not the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 belongs to the first range, and the voltage value of the drive voltage Vcc2 is the first value. If it is determined that it does not belong to the range, an initialization process for initializing the drive of the GDC 102 is executed.
In the display device 100 according to the first embodiment, a normal applied voltage + B (applied voltage + B whose voltage value belongs to the third range) required to apply the drive voltage Vcc2 belonging to the first range to the GDC 102 is the power supply. A normal applied voltage + B (applied voltage + B whose voltage value belongs to the fourth range) required to apply the drive voltage Vcc1 belonging to the second range to the CPU 101 and not applied to the module 107 is the power supply IC 104. When the CPU 101 determines that the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range, the initialization process of the GDC 102 is executed. The Thereby, when the voltage value of the drive voltage Vcc2 applied to the GDC 102 does not belong to the first range, the drive of the GDC 102 is initialized.
Therefore, according to the display device 100 according to the first embodiment, when the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range required to drive the GDC 102. That is, when an abnormality occurs in the voltage value supplied to the GDC 102, the driving of the GDC 102 can be initialized. As a result, according to the display device 100 according to the first embodiment, it is possible to provide a control device capable of returning the GDC 102 to a normal state when an abnormality occurs in the voltage value supplied to the GDC 102.

(Second Embodiment)
A display device 300 according to the second embodiment will be described with reference to FIG.

  FIG. 5 is a block diagram illustrating a hardware configuration example of the display device 300 according to the second embodiment. The display device 300 according to the second embodiment shown in FIG. 3 has the same configuration as that of the display device 100 according to the first embodiment except that the display device 300 further includes a determination circuit 108. The configuration is denoted by the same reference numeral as that of the display device 100 according to the first embodiment, and description of each configuration is omitted.

  The determination circuit 108 detects the drive voltage Vcc2 applied to the GDC 102 from the power supply module 107, determines whether or not the detected drive voltage Vcc2 belongs to the first range, and outputs the determination result to the CPU 101.

  In the display device 300 according to the second embodiment, when the CPU 101 receives from the determination circuit 108 the determination result when it is determined that the voltage value of the drive voltage Vcc2 does not belong to the first range, the CPU 101 An initialization process for initializing the drive is executed.

  In the display device 100 according to the first embodiment, as illustrated in FIG. 2, when the voltage value of the drive voltage Vcc2 applied to the GDC 102 decreases from 5 V to 0 V at time t3, the CPU 101 Initialization that initializes driving of the GDC 102 when it is determined whether or not the voltage value of Vcc2 belongs to the first range and the voltage value of the driving voltage Vcc2 does not belong to the first range In contrast to the configuration in which the process is executed, in the display device 300 according to the second embodiment, when the voltage value of the drive voltage Vcc2 applied to the GDC 102 decreases from 5 V to 0 V, the determination circuit 108 Then, it is determined whether or not the voltage value of the drive voltage Vcc2 belongs to the first range, and the determination result is output to the CPU 101. The CPU 101 receives the drive voltage from the determination circuit 108. If the voltage value of cc2 has accepted the judgment result when it is determined not belong to the first range, it executes initialization processing GDC102.

The display device 300 according to the second embodiment including the control device of the present invention includes a GDC 102 as a functional unit that is driven by being applied with a drive voltage Vcc2 as a first drive voltage, and a control unit that controls the GDC 102. The application voltage + B is applied by the CPU 101 and a battery as an external power supply, and the power supply module 107 as a first drive voltage generator for applying the drive voltage Vcc2 to the GDC 102, and the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 And a determination circuit 108 that determines whether or not the detected voltage value of the drive voltage Vcc2 belongs to the first range, and outputs a determination result to the CPU 101. When the CPU 101 receives a determination result from the determination circuit 108 when it is determined that the voltage value of the drive voltage Vcc2 does not belong to the first range, the CPU 101 executes an initialization process for initializing the drive of the GDC 102.
In the display device 300 according to the second embodiment, when the determination circuit 108 determines that the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range, Initialization processing is executed. Thereby, when the voltage value of the drive voltage Vcc2 applied to the GDC 102 does not belong to the first range, the drive of the GDC 102 is initialized.
In the display device 300 according to the second embodiment, the CPU 101 executes an initialization process based on the determination result received from the determination circuit 108. Therefore, the display device 300 according to the second embodiment can be obtained by adding the determination circuit 108 to the conventional display device. For this reason, it is not necessary to change the processing content of CPU101 significantly.
Therefore, according to the display device 300 according to the second embodiment, when the voltage value of the drive voltage Vcc2 applied from the power supply module 107 to the GDC 102 does not belong to the first range required to drive the GDC 102. That is, when an abnormality occurs in the voltage value supplied to the GDC 102, the driving of the GDC 102 can be initialized. As a result, according to the display device 300 according to the second embodiment, it is possible to provide a control device that can return the GDC 102 to a normal state when an abnormality occurs in the voltage value supplied to the GDC 102. Further, according to the display device 300 according to the second embodiment, it is not necessary to significantly change the configuration of the conventional display device.

(Third embodiment)
A display device 400 according to a third embodiment will be described with reference to FIG.

  FIG. 6 is a block diagram illustrating a hardware configuration example of the display device 400 according to the third embodiment. The display device 400 according to the third embodiment shown in FIG. 6 is the same as the display device 100 according to the first embodiment except that the CPU 101 receives the voltage value of the applied voltage + B applied to the power supply module 107 from the port P1. Since they have the same configuration, the same configuration is denoted by the same reference numeral as that of the display device 100 according to the first embodiment, and description of each configuration is omitted.

  In the display device 400 according to the third embodiment, the CPU 101 receives the voltage value of the applied voltage + B applied from the battery to the power supply module 107 from the port P1. Based on the applied voltage + B received from the port P1, the CPU 101 determines whether or not the voltage value of the applied voltage + B applied from the battery to the power supply module 107 belongs to the third range, and the voltage value of the applied voltage + B. Is determined not to belong to the third range, an initialization process for initializing the driving of the GDC 102 is executed.

  In the display device 100 according to the first embodiment, the CPU 101 determines whether the voltage value of the drive voltage Vcc2 belongs to the first range based on the voltage value of the drive voltage Vcc2 applied to the GDC 102. When the voltage value of the applied voltage + B of the battery suddenly drops from 12V in the normal state to 7V in the drop state, the power supply module is configured to execute the initialization process for initializing the driving of the GDC 102. Since the voltage value of the drive voltage Vcc2 applied from 107 to the GDC 102 decreases from 5V, which is a voltage value belonging to the first range, to 0V, which is a voltage value not belonging to the first range, the third embodiment In the display device 400 according to the above, the CPU 101 determines the applied voltage + B based on the applied voltage + B voltage value applied from the battery to the power supply module 107. Pressure value determines whether belonging to the third range, the voltage value of the applied voltage + B is when it is determined not belong to the third range, executes initialization processing GDC102.

The display device 400 according to the third embodiment including the control device of the present invention includes a GDC 102 as a functional unit that is driven by being applied with a drive voltage Vcc2 as a first drive voltage, and a control unit that controls the GDC 102. A CPU 101 and a power supply module 107 as a first drive voltage generator that applies the applied voltage + B by a battery as an external power supply and applies the drive voltage Vcc2 to the GDC 102 are provided. Then, in the CPU 101, the voltage value of the applied voltage + B applied from the battery to the power supply module 107 is a normal range required for the power supply module 107 to apply the drive voltage Vcc2 belonging to the first range to the GDC 102. If the voltage value of the applied voltage + B does not belong to the third range, an initialization process for initializing the driving of the GDC 102 is executed.
In the display device 400 according to the third embodiment, when the CPU 101 determines that the voltage value of the applied voltage + B applied from the battery to the power supply module 107 does not belong to the third range, the GDC 102 is initialized. Processing is executed. Thereby, when the voltage value of the applied voltage + B applied from the battery to the power supply module 107 does not belong to the third range, the drive of the GDC 102 is initialized.
Therefore, according to the display device 400 according to the third embodiment, when the voltage value of the applied voltage + B applied from the battery to the power supply module 107 does not belong to the third range required to drive the power supply module 107. In other words, when an abnormality occurs in the voltage value supplied to the power supply module 107, the driving of the GDC 102 can be initialized. As a result, the display device 400 according to the third embodiment can also provide a control device that can return the GDC 102 to a normal state when an abnormality occurs in the voltage value supplied to the GDC 102.

  The technical scope of the present invention is not limited to the embodiment described above. The above-described embodiments can be accompanied by various modifications and improvements within the technical scope of the present invention.

  For example, in the embodiment described above, in the control device having the information presentation function, the CPU 101 that is the control unit is configured to control the driving of the GDC 102 that is the function unit for exhibiting the information presentation function. The target functional unit is not limited to this, and is a functional unit that is operated by being supplied with a driving voltage of a predetermined voltage value from an external power source such as a battery and whose driving is controlled by the control unit. It may be a functional unit that realizes another function of the control device.

  In the above-described embodiment, the power supply module 107 that applies the drive voltage Vcc2 to the GDC 102 and the power supply IC 104 that applies the drive voltage Vcc1 to the CPU 101 are driven by applying the applied voltage + B from the same external power supply battery. The power supply module 107 that applies the drive voltage Vcc2 to the GDC 102 and the power supply IC 104 that applies the drive voltage Vcc1 to the CPU 101 may be driven by applying voltages from different external power supplies.

  In the display device 400 according to the third embodiment, the CPU 101 determines whether or not the voltage value of the applied voltage + B belongs to the third range, and the voltage value of the applied voltage + B is in the third range. In the case where it is determined that the GDC 102 does not belong, the initialization process for initializing the GDC 102 is executed. However, as with the display device 300 according to the second embodiment, the GDC 102 is applied to the power supply module 107 from the battery. It further includes a determination circuit that detects the applied voltage + B, determines whether or not the detected applied voltage + B belongs to the third range, and outputs a determination result to the CPU 101. The CPU 101 receives the applied voltage + B from the determination circuit 108. When the determination result in the case where it is determined that the voltage value does not belong to the third range is received, an initialization process for initializing the GDC 102 may be executed.

  In addition, each upper limit value and lower limit value of the first range, the second range, the third range, and the fourth range in each embodiment is an example, and the object of the present invention can be achieved. Needless to say, it can be appropriately changed within the range.

100 Display Device 101 Microcomputer (CPU) (Control Unit)
102 Graphic display controller (GDC) (Function part)
103 Liquid crystal display 104 Power supply IC (second drive voltage generator)
105 interface 106 interface 107 power supply module (first drive voltage generator)
108 determination circuit 200 display device 300 display device 400 display device Vcc1 drive voltage (second drive voltage)
Vcc2 drive voltage (first drive voltage)
Vcc3 drive voltage Vcc4 drive voltage RST1 reset signal RST2 reset signal + B applied voltage

Claims (3)

A functional unit that is driven by applying a first driving voltage;
A control unit for controlling the functional unit;
A first drive voltage generator that applies an applied voltage from an external power source and applies the first drive voltage to the functional unit;
With
The control unit determines whether or not a voltage value of the first drive voltage applied from the first drive voltage generation unit to the functional unit belongs to a first range, and the first drive voltage If it is determined that the voltage value does not belong to the first range, an initialization process for initializing the driving of the functional unit is executed.
A control device characterized by that. A second drive voltage generator for applying a second drive voltage to the controller by applying an applied voltage from an external power source and driving the controller;
The functional unit is driven by being applied with the first driving voltage having a voltage value belonging to the first range,
The control unit is driven by being applied with the second drive voltage having a voltage value belonging to a second range,
A normal applied voltage required to apply the first drive voltage belonging to the first range to the function unit is not applied to the first drive voltage generation unit, and belongs to the second range. When a normal applied voltage required to apply the second driving voltage to the control unit is applied to the second driving voltage generating unit, the second driving voltage generating unit moves from the second driving voltage generating unit to the second range. Whether the control unit to which the second driving voltage belongs belongs to whether the voltage value of the first driving voltage applied from the first driving voltage generation unit to the functional unit belongs to the first range. Determining whether or not the voltage value of the first drive voltage does not belong to the first range, an initialization process for initializing the drive of the functional unit is executed.
The control device according to claim 1. A functional unit that is driven by applying a first driving voltage;
A control unit for controlling the functional unit;
A first drive voltage generator that applies an applied voltage from an external power source and applies the first drive voltage to the functional unit;
The first drive voltage applied from the first drive voltage generation unit to the functional unit is detected, and it is determined whether or not the detected voltage value of the first drive voltage belongs to the first range. A determination unit that outputs a determination result to the control unit;
With
When the control unit receives from the determination unit the determination result when it is determined that the voltage value of the first drive voltage does not belong to the first range, the function unit is initially driven Execute initialization processing to
A control device characterized by that.

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