JP5513100B2 - Liquid crystal display device - Google Patents

Description

  The present invention relates to a liquid crystal display device that heats a liquid crystal display with a heater and drives the liquid crystal display by applying an optimum driving voltage corresponding to the temperature of the liquid crystal display.

  Generally, a vehicle is equipped with a combination meter having a plurality of types of instruments for displaying measured values such as vehicle speed, engine rotation, fuel remaining amount, and temperature. Some combination meters include an LCD device that displays a plurality of types of display contents on a liquid crystal display (LCD). The LCD device is arranged in the center of the combination meter or the like and performs a plurality of types of display.

  In such an LCD device, it has been conventionally known that the optimum driving voltage for displaying the LCD in an optimum state varies depending on the ambient temperature, and the multi-display device is adapted to match the optimum driving temperature. Voltage control is performed. Since the LCD has poor responsiveness under low temperature conditions, some LCD devices warm the LCD with a heater. A structure for making it difficult for heat generated in the apparatus to be transmitted to the back side of the housing is described in Patent Document 1 and the like. In Patent Document 1, heat is structurally dissipated to suppress a temperature rise on the back surface of the housing.

JP 2009-157196 A

  However, when controlling the heater ON / OFF in the above-described LCD device, it is necessary to use a temperature sensor. However, depending on the location where the temperature is detected, a temperature difference may occur between the LCD display portion and the above-described temperature sensor. It was found that the optimum driving voltage showed different characteristics. Furthermore, if the optimum driving voltage is applied as it is without considering the thermal conductivity of the LCD when the heater is turned on or off, or when the heater is turned on and off, a non-optimal voltage is applied to the LCD due to the difference in thermal conductivity. It has been found that the visibility of the LCD deteriorates.

  Therefore, in view of the above-described problems, an object of the present invention is to provide a liquid crystal display device capable of maintaining a good display on an LCD.

In order to solve the above-mentioned problems, the liquid crystal display device according to claim 1, which is made according to the present invention, includes a liquid crystal display 3, a heater 17 for heating the liquid crystal display 3, and the liquid crystal as shown in the basic configuration diagram of FIG. 1. Temperature detection means 18 for detecting temperature information indicating the temperature of the display 3, heater- off driving voltage that is an optimum driving voltage in a steady state when the heater is off, which is determined in advance corresponding to the detected temperature information, and heater-on Drive control for controlling the driving of the liquid crystal display by switching the heater-on driving voltage, which is the optimum driving voltage in the steady state at the time, according to the off state and the on state of the heater 17 and applying it to the liquid crystal display in the liquid crystal display display device 10 having a means 11, wherein the heater off during the drive voltage and the Hitao Storage means for storing the hour driving voltage, and storage means for storing a predetermined off-time adjustment time required for the temperature of the liquid crystal display changed by switching the heater from the on state to the off state. The drive control means 11 drives the heater off drive voltage and the heater on drive so that the drive voltage applied to the liquid crystal display 3 becomes the heater off drive voltage when the off adjustment time has elapsed . It is means for applying to the liquid crystal display 3 an increased drive voltage that is gradually increased from the heater-on drive voltage within the off-time adjustment time based on the voltage and the off-time adjustment time .

According to the liquid crystal display device of the present invention described in the first aspect, when the heater 17 is in the ON state, the drive control means 11 applies the heater ON drive voltage to the liquid crystal display 3 to drive it. When the heater 17 is in the off state, the drive control means 11 applies the heater off drive voltage to the liquid crystal display 3 to drive it. When the heater 17 is switched from the on-state to the off-state, the drive control means 11 is in a state where the off-time adjustment time required for the temperature of the liquid crystal display 3 changed by the switching to stabilize has elapsed from the start of the off-state. Based on the heater-off drive voltage, the heater-on drive voltage, and the off-time adjustment time, for example, linearly or from the heater-on drive voltage within the off-time adjustment time so that the drive voltage applied to the liquid crystal display 3 becomes the heater-off drive voltage. An increased driving voltage gradually increased in a curve can be applied to the liquid crystal display 3.

  According to a second aspect of the present invention, as shown in the basic configuration diagram of FIG. 1, in the liquid crystal display display device according to the first aspect, the drive control unit 11 is configured to turn on the heater 17 within the off-time adjustment time. When the state is switched, the drive voltage is reduced to the heater-on-time drive voltage by a decrease amount equivalent to the increase amount per unit time of the increased drive voltage being increased.

  According to the liquid crystal display device of the present invention described in claim 2 above, the heater 17 is switched from the on state to the off state, and again within the off time adjustment time during which the driving voltage of the liquid crystal display gradually increases. When the heater is switched to the ON state, the drive control means 11 can reduce the drive voltage to the heater-on-time drive voltage by a reduction amount equivalent to the increase amount per unit time of the increased drive voltage that is being increased.

According to a third aspect of the present invention, as shown in the basic configuration diagram of FIG. 1, in the liquid crystal display device according to the first or second aspect, the liquid crystal changed by switching the heater 17 from the off state to the on state. a storage means for the temperature of the display 3 stores the predetermined on-time adjustment time required to stabilize, the drive control unit 11, when the on-time adjustment time has elapsed, be applied to the liquid crystal display 3 The driving voltage is gradually decreased from the heater-off driving voltage within the on-time adjustment time based on the heater-off driving voltage, the heater-on driving voltage, and the on-time adjustment time so that the driving voltage becomes the heater-on driving voltage. It is means for applying a reduced driving voltage to the liquid crystal display 3.

According to the liquid crystal display device of the present invention described in the third aspect, when the heater 17 is switched from the off state to the on state, the drive control means 11 changes the temperature of the liquid crystal display 3 that has been changed by the switching from the on state start time. Based on the heater off-time drive voltage, the heater on-time drive voltage, and the on-time adjustment time so that the drive voltage applied to the liquid crystal display 3 becomes the heater on-time drive voltage when the on-time adjustment time required for stabilization of the heater has elapsed. Within the on-time adjustment time, it is possible to apply to the liquid crystal display 3 a reduced drive voltage that is gradually increased, for example, linearly or curvedly from the heater-off drive voltage.

As described above, according to the liquid crystal display device of the present invention described in claim 1, when the heater is switched from the on state to the off state, the temperature of the liquid crystal display changed by the switching from the start point of the off state is stabilized. The off-time adjustment is based on the heater off-time drive voltage, the heater on-time drive voltage, and the off-time adjustment time so that the drive voltage applied to the liquid crystal display becomes the heater off-time drive voltage when the off-time adjustment time required for Since the increased drive voltage, for example, linearly or curvilinearly increased from the heater-on drive voltage within the time, is applied to the liquid crystal display, the heat of the liquid crystal display is changed when the heater is switched from the on state to the off state. Unsuitable drive voltage is applied to the liquid crystal display due to the difference in conductivity It is possible to prevent, can prevent the visibility of the deterioration of the liquid crystal display by application of the driving voltage is not suitable. Therefore, even if a heater is used, there is an effect that good display on the liquid crystal display can be maintained.

  According to the liquid crystal display device of the present invention described in claim 2, in addition to the effect of the invention described in claim 1, the heater is switched from the on state to the off state, and the driving voltage of the liquid crystal display gradually increases. If the heater is switched on again within the off-time adjustment time, the drive voltage is reduced to the heater-on drive voltage with a decrease equivalent to the increase per unit time of the increased drive voltage that is being increased. As a result, since the driving voltage can be gradually reduced to the heater-on driving voltage, it is possible to prevent the visibility from being deteriorated by applying an inappropriate driving voltage to the liquid crystal display. In addition, since it is only necessary to reduce the drive voltage by a reduction amount equivalent to the increase amount, it is not necessary to calculate the reduction amount when the heater is switched on again, thereby preventing complicated drive control by software. be able to.

According to the liquid crystal display display device of the present invention as set forth in claim 3, in addition to the effect of the invention according to claim 1 or 2, if the heater is switched from off to on, by the switching from the ON state beginning The heater off-time drive voltage, the heater on-time drive voltage, and the heater on-time drive voltage so that the drive voltage applied to the liquid crystal display becomes the heater on-time drive voltage when the on-time adjustment time required for the temperature of the changed liquid crystal display to stabilize has elapsed. Based on the on-time adjustment time, a reduced drive voltage, for example, linearly or curvilinearly decreased from the heater off-time drive voltage within the on-time adjustment time, is applied to the liquid crystal display. When the on-state switches, the drive voltage that is not suitable due to differences in the thermal conductivity of the liquid crystal display Since it is possible to prevent application of the Isupurei can prevent visibility of the deterioration of the liquid crystal display by application of the driving voltage is not suitable. Therefore, even if a heater is used, there is an effect that good display on the liquid crystal display can be maintained.

It is a block diagram which shows the basic composition of the liquid crystal display display apparatus of this invention. 1 is a configuration diagram illustrating an example of a system configuration of a liquid crystal display device according to the present invention. It is a graph for demonstrating the relationship between an optimal drive voltage and temperature. It is a figure for demonstrating the drive example of LCD with respect to the on / off state of a heater, (a) is at the time of switching of the normal heater on state / off state, (b) is again in the on state immediately after the heater is turned off. Each time is switched. It is a flowchart which shows an example of the drive control process which CPU in FIG. 2 performs. 6 is a flowchart showing another example of the drive control process executed by the CPU in FIG. 2.

  Hereinafter, an embodiment in which a liquid crystal display (LCD) display device according to the present invention is applied to a combination meter mounted on a vehicle will be described below with reference to the drawings of FIGS.

  In FIG. 2, an LCD display device 10 controls driving of a liquid crystal display (LCD) 3 incorporated as a part of a vehicle combination meter. The LCD display device 10 includes a CPU (central processing unit) 11, a ROM (read only memory) 12, a RAM (random access memory) 13, an EEPROM (electrically erasable programmable read-only memory) 14, a communication unit 15, The LCD driver 16, the heater 17, and the temperature sensor 18 are included.

  The CPU 11 controls the entire LCD display device 10 and performs control according to a program stored in the ROM 12. The CPU 11 operates with electric power supplied from the vehicle battery via the power supply circuit 11b. The CPU 11 is activated in response to the change of the ignition switch (IGN +) of the vehicle from the OFF state to the ON state via the interface (I / F) 11i, and operates according to the change of the IGN + from the ON state to the OFF state. finish.

  Further, the LCD drive power supply 11c and the heater power supply 11d are electrically connected to the power supply circuit 11b. The LCD drive power supply 11c is electrically connected to the CPU 11 via the I / F 11i, and supplies power from the power supply circuit 11b to the LCD 3 under the control of the CPU 11. The heater power supply 11d is electrically connected to the CPU 11 via the I / F 11i, and supplies power from the power supply circuit 11b to the heater 17 under the control of the CPU 11.

  The ROM 12 stores a drive control program for causing the CPU 11 to function as various means such as the drive control means in the claims shown in FIG. 1, a program for controlling the display of the LCD 3, and the like. The RAM 13 stores various data and has an area necessary for processing operations of the CPU 11.

  The EEPROM 14 is an electrically erasable / rewritable read-only memory, and is electrically connected to the CPU 11. The EEPROM 14 corresponds to the thermal conductivity storage means in the claims shown in FIG. 1 and stores the thermal conductivity of the LCD 3 used in the LCD display device 10. The thermal conductivity is stored as a table or the like corresponding to the model of the LCD 3, and the thermal conductivity corresponding to the model is extracted from the table or the like, or stored in the ROM 12 in advance as a program parameter or the like. It can also be an embodiment to store.

  The communication unit 15 is communicably connected to an in-vehicle network such as a CAN (Controller Area Network) built in the vehicle, and communicates with other electronic devices connected to the in-vehicle network using a communication protocol such as CAN. The communication unit 15 transmits information input from the CPU 11 to the transmission destination, and outputs information received from other electronic devices to the CPU 11.

  The LCD driver 16 is electrically connected to the CPU 11 and controls display on the LCD 3 under the control of the CPU 11. As is well known, the LCD 3 is a display device using liquid crystal. A special liquid is sealed between two glass plates, and a voltage is applied to change the direction of liquid crystal molecules and increase or decrease the light transmittance. Thus, the image is displayed. The LCD 3 is configured to be able to display information according to a request from the CPU 11.

  The heater 17 is provided in the vicinity of the LCD 3 and is driven by the control of the CPU 11 to warm the LCD 3. The CPU 11 adjusts the heating temperature of the LCD 3 by controlling the heater power supply 11 d and adjusting the voltage applied to the heater 17. The CPU 11 prevents the responsiveness of the LCD 3 from deteriorating by driving the heater 17 to warm the LCD 3 when the ambient temperature of the LCD 3, the temperature of the LCD 3, etc. satisfy a predetermined low temperature condition. Yes. Note that the low temperature condition indicates a condition such as a temperature, a temperature range, etc. at which the responsiveness of the LCD 3 deteriorates, such as 0 ° C. or less.

  The temperature sensor 18 corresponds to the temperature detection means in the claims shown in FIG. 1, and various sensors such as a thermocouple are used. The temperature sensor 18 is electrically connected to the CPU 11 via the I / F 11 i and outputs temperature information indicating the detected temperature to the CPU 11. A plurality of temperature sensors 18LCD3 may be provided.

  Next, the graph of FIG. 3 is a graph showing the relationship between the optimum drive voltage [V] and the temperature [° C.] of the LCD 3 corresponding to each time the heater 17 is on and off. In FIG. 3, the vertical axis represents the optimum drive voltage [V], and the horizontal axis represents the temperature [° C.] of the LCD 3. The graph G 1 indicated by the solid line is when the heater 17 is turned off, and the graph G 2 indicated by the broken line is the heater ON. Each time is shown. When the heater 17 is on, the LCD display device 10 obtains the optimum driving voltage when the heater is off based on the temperature information detected by the temperature sensor 18 and the graph G1, and when the heater 17 is off, the temperature sensor 18 Based on the temperature information detected in step 1 and the graph G2, the optimum driving voltage when the heater is on is obtained. The LCD display device 10 stores a program, a table, and the like for obtaining each optimum driving voltage when the heater is on and when the heater is off in the ROM 12 or the like.

  Next, an example of control of the driving voltage applied to the LCD 3 by the LCD display device 10 will be described below with reference to the drawing of FIG.

  First, the LCD display device 10 specifies the heater-on optimum drive voltage V1 and the heater-off optimum drive voltage V2 to be applied to the LCD 3 based on the temperature information detected by the temperature sensor 18. In order to simplify the description, the present embodiment will be described with the temperature of the LCD 3 being fixed.

  As shown in FIG. 4A, the LCD display device 10 drives the LCD 3 by switching the optimum driving voltage V1 when the heater is on and the optimum driving voltage V2 when the heater is off according to the change in the on / off state of the heater 17. . The heater-on optimum drive voltage V1 is lower than the heater-off optimum drive voltage V2.

  The LCD display device 10 receives a drive voltage applied to the LCD 3 when a predetermined off-time adjustment time T1 has elapsed from the start of the switching of the heater 17 from the on state to the off state, corresponding to the thermal conductivity of the LCD 3. An increased drive voltage gradually increased from the heater-on drive voltage V1 is applied to the LCD 3 so that the heater-off drive voltage V2 is obtained. That is, the increased drive voltage of the present embodiment is linearly increased by a predetermined increase amount every predetermined time in the off-time adjustment time T1.

  In addition, the LCD display device 10 is applied to the LCD 3 when a predetermined on-time adjustment time T2 corresponding to the thermal conductivity of the LCD 3 has elapsed since the heater 17 started switching from the OFF state to the ON state. A reduced drive voltage that is gradually reduced from the heater-off drive voltage V2 is applied to the LCD 3 so that the voltage becomes the heater-on drive voltage V1. That is, the decrease drive voltage of the present embodiment is linearly decreased by a predetermined increase amount every predetermined time in the on-time adjustment time T2.

  Since the off-time adjustment time T1 and the on-time adjustment time T2 vary greatly depending on the shape of the LCD 3 (for example, size, shape, etc.) and the arrangement relationship between the temperature sensor 17 and the LCD 3, they are obtained in advance through experiments. In this embodiment, the case where the off-time adjustment time T1 and the on-time adjustment time T2 are equal will be described. However, the present invention is not limited to this, and the off-time adjustment time T1 and the on-time adjustment time T2 Can be at different times.

  Further, as shown in FIG. 4B, the LCD display device 10 is equivalent to the increased amount per unit time of the increased drive voltage that is increased when the heater 17 is switched on during the off-time adjustment time T1. Is applied to the LCD 3 by reducing the drive voltage to the drive voltage V1 when the heater is on. If the drive voltage is changed in this manner, the heater voltage can be gradually decreased to the drive voltage V1 when the heater is turned on, so that an inappropriate drive voltage is applied to the LCD 3 and visibility can be prevented from deteriorating. In addition, since it is only necessary to decrease the drive voltage by a decrease amount equivalent to the increase amount, it is not necessary to calculate the decrease amount when the heater 17 is switched to the ON state again, thereby preventing complicated drive control by software. can do.

  The LCD display device 10 stores a drive control program for performing the above-described control in the ROM 12, and stores an off-time adjustment time T 1 and an on-time adjustment time T 2 corresponding to the thermal conductivity of the EEPROM 14 in the EEPROM 14.

  Next, an example of a processing outline of the CPU 11 that controls the driving of the LCD 3 described above will be described below with reference to a flowchart of FIG. Note that the processing in FIG. 5 is based on the premise that the processing ends in response to the power-off of the LCD display device 10 or the like.

  When executing the drive control program, the CPU 11 acquires temperature information from the temperature sensor 18 in the RAM 13 in step S11, acquires the actual drive voltage currently applied to the LCD 3 in step S12, and stores it in the RAM 13. Thereafter, the process proceeds to step S13.

  In step S13, the CPU 11 obtains the heater 3 on-time optimum drive voltage V1 corresponding to the obtained temperature information and stores it in the RAM 13, and in step S14, the LCD 3 heater off-time drive voltage corresponding to the obtained temperature information. V2 is acquired and stored in the RAM 13, and then the process proceeds to step S15.

  In step S15, the CPU 11 determines whether or not the acquired temperature information is 0 ° C. or less. If the CPU 11 determines that the temperature is 0 ° C. or lower (Y in S15), the data power source 11d is controlled to drive the heater 17 in step S16, and the process proceeds to step S17.

  In step S17, the CPU 11 calculates the optimum voltage difference between the heater-off drive voltage V2 and the actual drive voltage or heater-on drive voltage V1 and stores it in the RAM 13. In step S18, the CPU 11 calculates the optimum voltage difference. Based on the off-time adjustment time T1 or the on-time adjustment time T2, the output value to be increased or decreased to the off-time adjustment time T1 or the on-time adjustment time T2 is calculated and stored in the RAM 13, and then the process proceeds to step S19. Then, in step S19, the CPU 11 divides the calculated output value by a predetermined unit time to acquire the unit time increase / decrease and stores it in the RAM 13, and then proceeds to the process of step S20.

Here, an example of a calculation method for the unit time increase / decrease from the optimum voltage difference will be described. The driving voltage Von when the heater 17 is off and the driving voltage Voff when the heater 17 is off can be expressed by Expression 1 and Expression 2, respectively.
Von = f0 (x) + (f1 (x) −f0 (x)) / T * t (Expression 1)
Voff = f1 (x) − (f1 (x) −f0 (x)) / T * t (Expression 2)

  F0 (x) is a drive voltage table when the heater 17 is off, f1 (x) is a drive voltage table when the heater 17 is on, T is the above-described off-time adjustment time T1 or on-time adjustment time T2, and t is The elapsed time since the state of the heater 17 was switched is shown, respectively. Then, the adjustment of the drive voltage is completed when the elapsed time t is the off-time adjustment time T1 or the on-time adjustment time T2.

In step S20, the CPU 11 determines whether or not a unit time has elapsed since the heater 17 was switched. When it is determined that the unit time has not elapsed (N in S20), the CPU 11 waits until the unit time has elapsed. On the other hand, if the CPU 11 determines that the unit time has elapsed (Y in S20), in step S21, the LCD drive power supply is applied to the LCD 3 in addition to the current drive voltage by the obtained unit time increase / decrease. 11c is requested, and then the process proceeds to step S22. By the process of step S21, the LCD drive power supply 11c applies the drive voltage added by the unit time increase / decrease to the LCD 3.

In step S22, when the heater 17 is in the on state, the CPU 11 sets the off time adjustment time T1. When the heater is in the off state, the on time adjustment time T2 becomes the set time, and the heater 17 is turned on or off. It is determined whether or not the set time has elapsed. If the CPU 11 determines that the set time has not elapsed (N in S22), the CPU 11 returns to step S20 and repeats a series of processes. On the other hand, if the CPU 11 determines that the set time has elapsed (Y in S22), since the drive voltage applied to the LCD 3 has reached the optimum drive voltage, an increase / decrease in unit time is added in step S23. Then, the output is stopped, that is, the drive voltage currently applied to the LCD 3 is maintained in the LCD drive power supply 11c, the process returns to step S11, and a series of processes is repeated.

If it is determined in step S15 that the temperature is not below 0 ° C. (N in S15), the CPU 11 determines in step S24 whether or not the heater 17 is in an on state. If the CPU 11 determines that the heater 17 is on (Y in S24), the CPU 11 controls the data power source 11d to stop driving the heater 17 in step S25, and then proceeds to the processing in step S17. Meanwhile, CPU 11 is in the (N in S24), step S26 if the heater 17 is determined not to be turned on, and requests the LCD drive power supply 11c so as to apply a heat Taofu at optimum driving voltage V 2 to the LCD 3, then Returning to the process of step S11, a series of processes is repeated. Through the processing in step S26, the LCD drive power supply 11c applies the optimum drive voltage to the LCD 3.

  According to the LCD display device 10 described above, when the heater 17 is switched from the on state to the off state, it is applied to the LCD 3 when the off-time adjustment time T1 corresponding to the thermal conductivity of the LCD 3 has elapsed since the start of the off state. For example, an increase drive voltage that is gradually increased linearly from the current drive voltage that is actually applied to the heater 17 or the current drive voltage that is actually applied to the heater 17 is applied to the LCD 3 so that the drive voltage to be driven becomes the drive voltage V2 when the heater is off. Thus, when the heater 17 is switched from the on state to the off state, it is possible to prevent an unsuitable drive voltage from being applied to the LCD 3 due to the difference in the thermal conductivity of the LCD 3, and therefore by applying an unsuitable drive voltage. Deterioration of the visibility of the LCD 3 can be prevented.

  Further, when the heater 17 is switched from the off state to the on state, when the on-time adjustment time T2 corresponding to the thermal conductivity of the LCD 3 has elapsed from the start of the on state, the drive voltage applied to the LCD 3 is the heater on-time drive voltage V1. Thus, since the drive voltage V2 that is gradually decreased from the heater-off drive voltage V2 is applied to the LCD 3, for example, the heat conduction of the LCD 3 is switched when the heater 17 is switched from the off-state to the on-state. Since an unsuitable drive voltage can be prevented from being applied to the LCD 3 due to the difference in rate, the visibility of the LCD 3 can be prevented from being deteriorated by the unsuitable drive voltage.

  Therefore, according to the LCD display device 10 of the present invention described above, there is an effect that a good display on the LCD 3 can be maintained even if the heater 17 is used.

  In the above-described embodiment, the case where the drive voltage applied to the LCD 3 is linearly increased / decreased at the off-time adjustment time T1 and the on-time adjustment time T2 when the heater 17 is turned on / off is described. did. Instead, an example in the case where the drive voltage applied to the LCD 3 is increased or decreased in a curve will be described below with reference to the flowchart of FIG.

  When the CPU 11 executes the drive control program, the temperature information is acquired from the temperature sensor 18 in the RAM 13 in step S51, and the actual drive voltage currently applied to the LCD 3 is acquired in step S52 and stored in the RAM 13. Thereafter, the process proceeds to step S53.

  In step S53, the CPU 11 acquires the heater 3 on-time optimum drive voltage V1 corresponding to the acquired temperature information and stores it in the RAM 13, and in step S54, the LCD 3 heater off-time drive voltage corresponding to the acquired temperature information. V2 is acquired and stored in the RAM 13, and then the process proceeds to step S55.

  In step S55, the CPU 11 determines whether or not the acquired temperature information is 0 ° C. or less. If the CPU 11 determines that the temperature is 0 ° C. or lower (Y in S55), the data power source 11d is controlled to drive the heater 17 in step S56, and the process proceeds to step S57.

  In step S57, the CPU 11 calculates the optimum voltage difference between the heater-off drive voltage V2 and the actual drive voltage or heater-on drive voltage V1 and stores it in the RAM 13. In step S58, the CPU 11 calculates the optimum voltage difference. Based on the off-time adjustment time T1 or the on-time adjustment time T2, an output value to be increased or decreased to the off-time adjustment time T1 or the on-time adjustment time T2 is calculated and stored in the RAM 13, and then the process proceeds to step S59. Then, in step S59, the CPU 11 sequentially acquires the unit time increase / decrease divided in such a way that the calculated output value is gradually reduced as it approaches the optimum drive voltage in a predetermined unit time, and is stored in the RAM 13. Thereafter, the process proceeds to step S60.

In step S60, the CPU 11 determines whether a unit time has elapsed since the heater 17 was switched. When determining that the unit time has not elapsed (N in S60), the CPU 11 waits until the unit time has elapsed. On the other hand, when the CPU 11 determines that the unit time has elapsed (Y in S60), in step S61, the LCD drive power supply is applied to the LCD 3 in addition to the current drive voltage by the obtained unit time increase / decrease. 11c is requested, and then the process proceeds to step S62. By the process of step S61, the LCD drive power supply 11c applies the drive voltage added by the unit time increase / decrease to the LCD 3.

In step S62, the CPU 11 determines whether or not the drive voltage has reached the heater-off drive voltage V2 when the heater 17 is off and the heater-on drive voltage V1 when the heater 17 is on. . If the CPU 11 determines that the optimum drive voltage has not been reached (N in S62), the CPU 11 returns to step S60 and repeats a series of processes. On the other hand, if the CPU 11 determines that the optimum drive voltage has been reached (Y in S62), it stops adding and outputting the unit time increase / decrease in step S63, that is, it is currently applied to the LCD 3. The drive voltage is maintained at the LCD drive power supply 11c, and the process returns to step S51 to repeat a series of processes.

If it is determined in step S55 that the temperature is not below 0 ° C. (N in S55), the CPU 11 determines in step S64 whether or not the heater 17 is on. If the CPU 11 determines that the heater 17 is on (Y in S64), the CPU 11 controls the data power source 11d to stop driving the heater 17 in step S65, and then proceeds to the processing in step S57. Meanwhile, CPU 11 is in the (N in S64), step S66 if the heater 17 is determined not to be turned on, and requests the LCD drive power supply 11c so as to apply a heat Taofu at optimum driving voltage V 2 to the LCD 3, then Returning to the process of step S11, a series of processes is repeated. Through the processing in step S26, the LCD drive power supply 11c applies the optimum drive voltage to the LCD 3.

  Thus, even if the processing of the LCD display device 10 is changed, the same effect as that of the LCD display device 10 described above can be obtained.

  As described above, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

3 Liquid crystal display 10 Liquid crystal display (LCD) display device 11 Drive control means (CPU)
14 Thermal conductivity storage means 17 Heater 18 Temperature detection means (temperature sensor)

Claims (3)

A liquid crystal display, a heater for heating the liquid crystal display, temperature detection means for detecting temperature information indicating the temperature of the liquid crystal display, and a steady state when the heater is turned off, which is predetermined corresponding to the detected temperature information The heater driving off driving voltage, which is the optimum driving voltage, and the heater driving driving voltage, which is the optimum driving voltage in the steady state when the heater is on, are switched according to the heater off state and the on state, and applied to the liquid crystal display. A liquid crystal display device having drive control means for controlling the drive of the liquid crystal display,
Storage means for storing the heater-off drive voltage and the heater-on drive voltage;
Storage means for storing a predetermined off-time adjustment time required for the temperature of the liquid crystal display changed by switching the heater from the on state to the off state to be stable;
It said drive control means, when the off-time adjustment time has elapsed, such that the drive voltage applied to the liquid crystal display is the heater off drive voltage, said heater off drive voltage, the heater on during the driving voltage and the OFF A liquid crystal display device comprising: means for applying, to the liquid crystal display, an increased drive voltage that is gradually increased from the heater-on drive voltage within the off-time adjustment time based on the time adjustment time .   When the heater switches to the on state within the off time adjustment time, the drive control means supplies the drive voltage to the increase voltage when the heater is on, with a decrease amount equivalent to the increase amount per unit time. 2. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is means for reducing the driving voltage. Storage means for storing a predetermined on-time adjustment time required for the temperature of the liquid crystal display changed by switching the heater from the off state to the on state to be stable;
Said drive control means, when said on-time adjustment time has elapsed, such that the drive voltage applied to the liquid crystal display is the heater ON drive voltage, the heater off drive voltage, the heater on during the drive voltage and the ON 3. The liquid crystal according to claim 1 , wherein the liquid crystal display is means for applying to the liquid crystal display a reduced drive voltage that is gradually reduced from the heater-off drive voltage within the on-time adjustment time based on the time adjustment time. Display display device.

Images