JP2011191658A - Liquid crystal display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To adjust the brightness of liquid crystal panels separately while reducing the number of parts. <P>SOLUTION: A liquid crystal display device includes a CPU 60 which transmits alternately a first PWM signal for driving a first LED backlight 30 and a second PWM signal for driving a second LED backlight 80 for every predefined period of time. The liquid crystal display device controls current switching so that: during the first PWM signal is transmitted, a current corresponding to the pulse width of the first PWM signal flows in the backlight 30; and during the second PWM signal is transmitted, a current corresponding to the pulse width of the second PWM signal flows in the backlight 80. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a liquid crystal display system including a first display device having a first liquid crystal panel and a second display device having a second liquid crystal panel.

  2. Description of the Related Art Conventionally, there is a liquid crystal display device that includes an LED backlight having an LED that illuminates a liquid crystal panel from the back side, and drives an LED provided in the LED backlight in accordance with a pulse width modulated PWM signal (for example, , See Patent Document 1).

JP 2009-32497 A

  In recent years, liquid crystal display devices such as those described above have been used in various parts of a vehicle such as for driver seats and passenger seats, in the center and around the instrument panel, for front seats such as driver seats, and for rear seats. It is becoming more and more mounted on

  However, these liquid crystal display devices are each configured independently and output an LED drive circuit for driving an LED provided in the LED backlight, and a PWM signal that is pulse-width modulated to the LED drive circuit. Since the CPU and the power supply circuit that boosts the input voltage from the on-vehicle battery and supplies it to the LED drive circuit are also provided separately, there is a problem that the number of parts is large and the cost is increased.

  Therefore, it is considered effective to use a liquid crystal display system having a plurality of liquid crystal display devices by sharing the above LED drive circuit, CPU, power supply circuit, and the like.

  However, if the control circuit and the CPU are shared in this way, each LED backlight of a plurality of liquid crystal display devices is driven by the same PWM signal, and the brightness of each liquid crystal display device is separately set. There arises a problem that adjustment cannot be performed.

  In particular, a liquid crystal display device mounted on a vehicle has different effects due to external light depending on the mounting position. Therefore, it is not convenient to use unless the brightness of each liquid crystal display device can be adjusted separately. In addition, since the optimum brightness varies depending on the video source (for example, map display, DVD playback display), etc., it is not convenient to use unless the brightness of each liquid crystal display device can be adjusted separately.

  The present invention has been made in view of the above problems, and an object of the present invention is to make it possible to separately adjust the luminance of a liquid crystal panel while reducing the number of components.

  In order to achieve the above object, the first aspect of the present invention provides a first display device (1) having a first liquid crystal panel (1a) and a second display having a second liquid crystal panel (2a). The first display device (1) includes LEDs (31a to 31d, 32a to 32d, 32a to 32d) that illuminate the first liquid crystal panel (1a) from the back side. 33a to 33d, 34a to 34d), the second display device (2) includes LEDs (81a to 81a) that illuminate the second liquid crystal panel (2a) from the back side. 81d, 82a-82d, 83a-83d, 84a-84d), the second LED backlight (80), and the first LED backlight (30) LED (31a-31d, 32a-32d, 33a- 33d, 34a-34d The first PWM signal for driving the second PWM signal for driving the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) of the second LED backlight (80) During the period in which the first PWM signal is transmitted from the pulse signal transmission circuit (60) and the pulse signal transmission circuit (60) which are alternately transmitted every predetermined period, the first PWM signal A current corresponding to the pulse width flows through the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) provided in the first LED backlight (30), and a pulse signal transmission circuit (60) During the period in which the second PWM signal is being transmitted, the LED (8) provided in the second LED backlight (80) has a current corresponding to the pulse width of the second PWM signal. a~81d, 82a~82d, are 83a to 83d, a control circuit for the current switch control flow in 84a~84d) (40,50), comprising the.

  According to such a configuration, the first PWM signal for driving the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) of the first LED backlight (30) and the second LED backlight (30). A second PWM signal for driving the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) of the LED backlight (80) is alternately sent every predetermined period, During the period during which the PWM signal is being sent, the currents corresponding to the pulse width of the first PWM signal are supplied to the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d), and during the period during which the second PWM signal is transmitted, a current corresponding to the pulse width of the second PWM signal is supplied to the second LED backlight (80 Since the current switching control is performed so as to flow to the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) included in the circuit, the pulse signal transmission circuit (60) and the control circuit (50) are shared. However, the brightness of the liquid crystal panel can be adjusted separately. In addition, the number of parts can be reduced.

  The invention according to claim 2 is based on the forward voltage drop of the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) provided in the first LED backlight (30). While generating the 1st constant voltage which optimized the voltage of the power supply with respect to the said 1st LED backlight (30), LED (81a-81d, 82a) with which the 2nd LED backlight (80) was equipped. -82d, 83a-83d, 84a-84d) based on the forward voltage drop, a power supply circuit for generating a second constant voltage that optimizes the power supply voltage for the second LED backlight (80) The control circuit (40, 50) includes a first constant generated by the power supply circuit (20) during a period in which the first PWM signal is transmitted from the pulse signal transmission circuit (60). Electric Is supplied to the first LED backlight (30), and during the period in which the second PWM signal is sent from the pulse signal sending circuit (60), the second constant generated by the power supply circuit (20) is used. The power supply circuit (20) is controlled to supply a voltage to the second LED backlight (80).

  According to such a configuration, the first LED backlight (30) includes the first voltage drop based on the forward voltage drop of the LEDs (31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d). The first constant voltage that optimizes the voltage of the power supply for the LED backlight (30) of the second LED backlight (80) and the LEDs (81a to 81d, 82a to 82d, A power supply circuit (20) for generating a second constant voltage obtained by optimizing the voltage of the power supply for the second LED backlight (80) based on the forward voltage drop of 83a to 83d and 84a to 84d). The control circuit (40, 50) supplies the first constant voltage generated by the power supply circuit (20) during the period when the first PWM signal is transmitted from the pulse signal transmission circuit (60). The second constant voltage generated by the power supply circuit (20) is supplied to the LED backlight (30) during the period when the second PWM signal is sent from the pulse signal sending circuit (60). Since the power supply circuit (20) is controlled so as to be supplied to the second LED backlight (80), the power supply voltage can be optimized while the power supply circuit (20) is shared.

  According to a third aspect of the present invention, in the control circuit (40, 50), the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) provided in the first LED backlight (30) are provided. ) And the LED (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) included in the second LED backlight (80) are connected to a common LED driving transistor (41 to 44). A first constant voltage generated by the power supply circuit (20) is supplied to the first LED backlight (30), and a second constant voltage generated by the power supply circuit (20) is supplied to the second LED backlight. During the period not supplied to the light (80), the LEDs (31a to 31d) provided in the first LED backlight (30) by the LED driving transistors (41 to 44). 32a to 32d, 33a to 33d, 34a to 34d), a current according to the pulse width of the first PWM signal flows, and the second constant voltage generated by the power supply circuit (20) is the second LED. During a period in which the first constant voltage supplied to the backlight (80) and generated by the power supply circuit (20) is not supplied to the first LED backlight (30), the LED driving transistors (41-41) 44), current corresponding to the pulse width of the second PWM signal flows to the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) provided in the second LED backlight (80). It is characterized by that.

  According to such a configuration, the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) and the second LED backlight (80) included in the first LED backlight (30) are provided. The LED driving transistors (41 to 44) for driving the provided LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) can be shared, and the number of components can be reduced. It is.

  According to a fourth aspect of the present invention, the pulse signal transmission circuit (60) and the control circuit (50) are incorporated in any one of the first and second display devices (1, 2). Of the first and second display devices (1, 2), the display device incorporating the pulse signal transmission circuit (60) and the control circuit (50) is provided in the first LED backlight (30). The magnitude of current flowing through the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) and the LEDs (81a to 81d, 82a to 82d, 83a) provided in the second LED backlight (80) ˜83d and 84a to 84d) are provided with an operation unit (70) for adjusting the magnitude of the current flowing through each of them.

  According to such a configuration, adjustment of the current flowing through each LED provided in each backlight (30) can be adjusted by one operation unit (70). That is, the brightness of the first and second display devices (1, 2) can be adjusted with one operation unit (70). For example, it is also possible to operate the brightness adjustment of the display device disposed far away by providing the operation unit in the display device disposed near the passenger.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

1 is a diagram illustrating an overall configuration of a liquid crystal display system according to a first embodiment of the present invention. It is a figure which shows the block configuration of the liquid crystal display system which concerns on 1st Embodiment of this invention. It is a figure for demonstrating waveforms, such as a control signal. It is a figure which shows the block configuration of the liquid crystal display system which concerns on 2nd Embodiment of this invention. It is a figure for demonstrating waveforms, such as a control signal.

(First embodiment)
FIG. 1 shows the overall configuration of the liquid crystal display system according to the first embodiment of the present invention. The present liquid crystal display system includes a first liquid crystal display device 1 having a first liquid crystal panel 1a, a second liquid crystal display device 2 having a second liquid crystal panel 2a, and a connection line 3. Moreover, as shown in this figure, the 1st liquid crystal display device 1 and the 2nd liquid crystal display device 2 are comprised as a different body.

  FIG. 2 shows a block configuration of the present liquid crystal display system. As shown in FIG. 2, the present liquid crystal display system operates by receiving power supply from the in-vehicle battery 10.

  The first liquid crystal display device 1 includes a first liquid crystal panel 1a (not shown in FIG. 2), a DC / DC converter 20, a backlight 30, an LED drive circuit 40, a control circuit 50, a CPU 60 (shown in FIG. 1). Equivalent to a pulse signal transmission circuit) and an operation unit 70. The second liquid crystal display device 2 includes the second liquid crystal panel 2a (not shown in FIG. 2) and the backlight 80 shown in FIG.

  That is, the DC / DC converter 20, the LED drive circuit 40, the control circuit 50, the CPU 60, and the operation unit 70 in the present liquid crystal display system are made common and built in the first liquid crystal display device 1.

  The DC / DC converter 20 is a boost type power supply circuit that boosts the input voltage Vin from the in-vehicle battery 10 from the internal power supply 10 of the device and outputs a voltage to be supplied to the backlight 30.

  A smoothing capacitor 21 is provided between the input terminal A of the DC / DC converter 20 and the ground. A coil 22 and an N-channel MOS transistor 23 connected in series are provided between the input terminal A and the ground. A diode 24 and a capacitor 25 connected in series are provided between a connection point B of the coil 22 and the N-channel MOS transistor 23 and the ground. By switching the transistor 23, an output voltage Vo obtained by boosting the input voltage Vin from the in-vehicle battery 10 is output from the output terminal C. Between the output terminal C and the ground, resistors 26a and 26b connected in series are provided. A voltage obtained by dividing the output voltage Vo of the output terminal C by the resistors 26a and 26b is input to the monitor terminal Mon of the control circuit.

  The backlight 30 is used as a backlight for illuminating the first liquid crystal panel 1a from the back side. The backlights 31a to 31d connected in series, 32a to 32d connected in series, and 33a to 33 connected in series. 33d, 34a to 34d connected in series, and a P-channel MOS transistor 33 are provided.

  The transistor 33 is for switching the power supplied from the output terminal C of the DC / DC converter 20. An enable signal is input to the gate terminal of the transistor 33 via the inverter 61 from the enable terminal EN1 of the CPU. When a high level enable signal is output from the enable terminal EN1 of the CPU, the transistor 33 is turned on and power is supplied from the output terminal C of the DC / DC converter 20.

  The backlight 80 is used as a backlight for illuminating the second liquid crystal panel 2a from the back side. The light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d, and the P-channel MOS transistor 83 are used. It has. The internal configuration of the backlight 80 is the same as that of the backlight 30. An enable signal is input to the gate terminal of the transistor 83 via the inverter 62 from the enable terminal EN2 of the CPU. When a high level enable signal is output from the enable terminal EN2 of the CPU, the transistor 83 is turned on and power is supplied from the output terminal C of the DC / DC converter 20.

  The LED drive circuit 40 includes N-channel MOS transistors 41 to 44 and N-channel MOS transistors 45 to 48.

  The transistors 41 to 44 include the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d of the backlight 30, and the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84a of the backlight 80, respectively. 84d is a transistor for PWM control. The PWM signals that have been subjected to pulse width modulation are input to the gate terminals of these transistors 41 to 44 from the S1 to S4 terminals of the control circuit 50, respectively.

  In this embodiment, the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d of the backlight 30 and the light emitting diodes 81a to 81d, 82a to 82d of the backlight 80, The transistors that drive the transistors 83a to 83d and 84a to 84d are shared by the transistors 41 to 44.

  The transistors 45 to 48 include the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d of the backlight 30, and the light emitting diodes 81a to 81d, 82a to 82d83a to 83d, and 84a to 84d of the backlight 80, respectively. Each is a transistor for driving at a constant current. Analog current adjustment signals are input to the gate terminals of the transistors 45 to 48 from the C1 to C4 terminals of the control circuit 50, respectively.

  The control circuit 50 outputs a control signal for switching control of the transistor 23 of the DC / DC converter 20 from the control terminal Cont, and signals S1 to S4 and the CPU 60 according to the pulse width modulated pulse signal input from the CPU 60. The analog current adjustment signals C1 to C4 corresponding to the constant current setting information input from are generated, and the generated signals are output to the LED drive circuit 40 to drive the backlight 30 and the backlight 80.

  When the N-channel MOS transistor 22 is turned on in response to a control signal output from the control terminal Cont of the control circuit 50, a current flows through the coil 22 and energy is accumulated. When the N-channel MOS transistor 22 is turned off according to the control signal output from the control terminal Cont, an electromotive force is generated by the energy accumulated in the coil 22 during that time. This voltage is superimposed on the input voltage and the output capacitor is charged through the rectifier diode 24. Thus, the voltage Vo at the output terminal C becomes higher than the input voltage according to the switching operation of the transistor 22 by the control signal output from the control terminal Cont.

  When the lowest voltage among the detection voltages Vdet1 to Vdet4 rises to the reference voltage Vref, the duty of the control signal from the control terminal Cont of the control circuit 50 is controlled to be small. For this reason, the voltage Vo of the output terminal C falls. When the lowest voltage among the detection voltages Vdet1 to Vdet4 decreases to a predetermined voltage, the duty of the control signal from the control terminal Cont is largely controlled, and the voltage Vo at the output terminal increases. As described above, the control circuit 50 makes the output voltage Vo of the DC / DC converter 20 constant by feedback control.

  By the way, when power is supplied to the backlights 30 and 80, variations in forward voltage Vf of the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d connected in series, and serial connection Considering the variation of each forward voltage Vf of the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d, it is possible to drive the diode having the largest forward voltage Vf. Therefore, it is necessary to increase the output voltage Vo to some extent. However, if the output voltage Vo is increased unnecessarily, the loss of the LED drive circuit 40 increases.

  Therefore, when supplying power to the backlight 30, the control circuit 50 according to the present embodiment has the forward voltage Vf among the light emitting diodes 31 a to 31 d, 32 a to 32 d, 33 a to 33 d, and 34 a to 34 d. When the DC / DC converter 20 is instructed to output the output voltage Vo in which the power supply voltage is optimized in accordance with the largest voltage drop, that is, the largest forward drop voltage, and the power is supplied to the backlight 80 The output voltage Vo is optimized by optimizing the voltage of the power supply in accordance with the largest forward voltage Vf among the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d. The DC / DC converter 20 automatically controls.

  Note that a switching transistor (corresponding to the transistor 23) of one DC / DC converter is switched so that a specific detection voltage Vdet out of a plurality of detection voltages Vdet input from the LED drive circuit 40 is equal to the reference voltage Vref. The control technique is a known technique (see, for example, Japanese Patent Laid-Open No. 2005-33853).

  The CPU 60 has a memory such as a ROM, a RAM, and a flash memory, and performs various processes according to a program stored in the ROM.

  In the present liquid crystal display system, the brightness of the liquid crystal panel 1 a of the first liquid crystal display device 1 and the liquid crystal panel of the second liquid crystal display device 2 are operated by operating the operation unit 70 provided in the first liquid crystal display device 1. The brightness of 2a can be adjusted separately. When each luminance is adjusted according to the operation of the user operation unit 70, each adjusted value is stored in the flash memory of the CPU 60. The CPU 60 determines the duty ratio of the PWM signal output from the PWM terminal in accordance with the adjustment value stored in the flash memory, and sends out a PWM signal having a pulse width corresponding to the duty ratio.

  Further, the CPU 60 outputs each enable signal for repeating power supply to the backlights 30 and 80 from the enable terminals EN1 and EN2, and the light emitting diode 31a of the backlight 30 in synchronization with these enable signals. To 31d, 32a to 32d, 33a to 33d, a PWM signal (corresponding to the first PWM signal), and light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d provided in the backlight 80. , 84a to 84d are alternately output PWM signals (corresponding to the second PWM signal).

  Next, the lighting control of the backlight of the backlight control device 1 will be described. FIG. 3 shows a PWM signal (denoted as PWM in the figure) output from the PWM terminal of the CPU 60, an enable signal (denoted as EN1 in the figure) output from the enable terminal EN1 of the CPU 60, and an output from the enable terminal EN2 of the CPU 60. Enable signal (denoted as EN2 in the figure), currents flowing in the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d provided in the backlight 30 (in the figure, I31 / I32 / I33 / I34), currents flowing through the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d provided in the backlight 80 (in the figure, indicated as I81 / I82 / I83 / I84) The waveform is shown.

  The CPU 60 outputs a PWM signal for driving the backlight 30 from the PWM terminal, and outputs a high-level enable signal from the enable terminal EN1. During this period, a low level enable signal is output from the enable terminal EN2.

  The control circuit 50 outputs the PWM signal of the CPU 60 from the S1, S2, S3, and S4 terminals. At this time, a constant current having a waveform indicated by I31 / I32 / I33 / I34 in the figure flows through the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d provided in the backlight 30, respectively. . Further, since no power is supplied to the backlight 80, no current flows through the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 83a to 83d provided in the backlight 80.

  When the predetermined period T1 elapses, the CPU 60 outputs a PWM signal for driving the backlight 80 from the PWM terminal, and outputs a high-level enable signal from the enable terminal EN2. During this period, a low level enable signal is output from the enable terminal EN1.

  The control circuit 50 outputs the PWM signal of the CPU 60 from the S1, S2, S3, and S4 terminals. At this time, a constant current having a waveform indicated by I81 / I82 / I83 / I84 flows in the light emitting diodes 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d provided in the backlight 80, and Since no power is supplied to the backlight 30, no current flows in the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 33a to 33d provided in the backlight 30.

  When the predetermined period T2 elapses, the CPU 60 again outputs a PWM signal for driving the backlight 30 from the PWM terminal, and outputs a high-level enable signal from the enable terminal EN1. By repeating this operation alternately in a short cycle, the backlight 30 and the backlight 80 can be driven with PWM signals having different duty ratios. The fixed periods T1 and T2 may or may not be the same.

  According to the above configuration, the first PWM signal for driving the LEDs 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d included in the first LED backlight 30 and the second LED backlight A CPU 60 that alternately sends second PWM signals for driving the LEDs 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d included in the light 80 at predetermined intervals. During the period in which the PWM signal is transmitted, currents corresponding to the pulse width of the first PWM signal are supplied to the LEDs 31a to 31d, 32a to 32d, 33a to 33d provided in the first LED backlight 30. During a period when the second PWM signal is sent from the CPU 60, the pulse width of the second PWM signal is set to 34a to 34d. Current switching control is performed so that the current flowing through the LEDs 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d included in the second LED backlight 80 is shared. However, the brightness of the liquid crystal panel can be adjusted separately. In addition, the number of parts can be reduced.

  Further, based on the forward voltage drop of the LEDs 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d provided in the first LED backlight 30, the voltage of the power source is applied to the first LED backlight. Based on the forward voltage drop of the LEDs 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 84d provided in the second LED backlight 80, the second constant current voltage is generated. The power supply circuit 20 that generates a second constant voltage that optimizes the power supply voltage for the LED backlight is provided, and the control circuits 40 and 50 are in the period T1 during which the first PWM signal is transmitted from the CPU 60. The first constant voltage generated by the power supply circuit 20 is supplied to the first LED backlight 30, and the second PWM signal is sent from the CPU 60. During the period T2, the power supply circuit 20 is controlled so that the second constant voltage generated by the power supply circuit 20 is supplied to the second LED backlight 80. Therefore, the power supply circuit 20 is shared. However, the power supply voltage can be optimized and the loss of the LED drive circuit 40 can be reduced.

  The control circuits 40 and 50 include LEDs 31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d provided in the first LED backlight 30, and LEDs 81a to 81d provided in the second LED backlight 80. , 82a to 82d, 83a to 83d, and 84a to 84d, the common LED driving transistors 41 to 44 are provided, and the first constant voltage generated by the power supply circuit 20 is applied to the first LED backlight 30. During a period when the second constant voltage supplied and generated by the power supply circuit 20 is not supplied to the second LED backlight 80, the first LED backlight (30) is provided by the LED driving transistors 41 to 44. LED (31a-31d, 32a-32d, 33a-33d, 34a-34d) provided in the first PWM signal The second constant voltage generated by the power supply circuit 20 is supplied to the second LED backlight 80, and the first constant voltage generated by the power supply circuit 20 is the first constant voltage. During the period when the LED backlight 30 is not supplied, the LEDs (81a to 81d, 82a to 82d, 83a to 83d) provided to the second LED backlight (80) by the LED driving transistors 41 to 44 are provided. , 84a to 84d), a current corresponding to the pulse width of the second PWM signal flows, so that the LEDs 31a to 31d, 32a to 32d, and 33a to 33d included in the first LED backlight 30 are provided. , 34a to 34d and the LEDs 81a to 81d, 82a to 82d, 83a to 83d, and 84a to 8 included in the second LED backlight 80. Can share the LED driving transistor 41 to 44 to drive the d, it is possible to reduce the number of parts.

  In addition, adjustment of the current flowing in each LED provided in each backlight 30 can be adjusted by one operation unit 70. That is, the luminance adjustment of the first and second display devices 1 and 2 can be performed with one operation unit 70. For example, it is also possible to operate the brightness adjustment of the display device disposed far away by providing the operation unit in the display device disposed near the passenger.

(Second Embodiment)
FIG. 4 shows a block configuration of a liquid crystal display system according to the second embodiment of the present invention. In the liquid crystal display system according to the first embodiment, the output voltage Vo of the DC / DC converter 20 is switched by the enable signals output from the enable terminals EN1 and EN2 of the CPU 60, and the enable signals output from the enable terminals EN1 and EN2. Although the PWM signal for supplying current to the light emitting diode provided in the backlight 30 and the PWM signal for supplying current to the light emitting diode provided in the backlight 80 are alternately output in synchronization with the signal, In this embodiment, switching of the output voltage Vo of the DC / DC converter 20 is not performed. However, in such a configuration, since the control circuit 50 cannot recognize the switching timing of the PWM signal, channel control information for instructing the switching timing from the CPU 60 to the control circuit 50 (denoted as CH control in the figure). The control circuit 50 synchronizes with the channel control information, and the PWM signal for flowing current to the light emitting diode provided in the backlight 30 from the S1 and S2 terminals and the backlight 80. PWM signals for causing a current to flow through the light emitting diodes provided are alternately output.

  Therefore, in the present embodiment, the backlight 30 and the backlight 80 are regarded as one backlight, and a constant voltage in which the power supply voltage is optimized is supplied to the backlights 30 and 80.

  FIG. 5 shows a PWM signal (denoted as PWM in the figure) output from the PWM terminal of the CPU 60, channel control information (denoted as CH control in the figure), and a PWM signal output from the S1 and S2 terminals of the control circuit 50. (Denoted as S1 / S2 in the figure), PWM signals (denoted as S3 / S4 in the figure) output from the terminals S3 and S4 of the control circuit 50, light emitting diodes 31a to 31d provided in the backlight 30, Waveforms of currents flowing through 32a to 32d (denoted as I31 / I32 in the figure) and currents flowing through light emitting diodes 81a to 81d and 82a to 82d provided in the backlight 80 (denoted as I81 / I82 in the figure). Show.

  As shown in FIG. 5, during a period T <b> 1 during which a PWM signal for driving a light emitting diode provided in the backlight 30 is sent from the CPU 60, a current corresponding to the pulse width of the PWM signal is supplied to the backlight 30. During the period T2 during which the PWM signal for driving the light emitting diode provided in the backlight 80 is sent from the CPU 60 to the light emitting diodes 31a to 31d and 32a to 32d provided in Current switching control is performed so that a current corresponding to the width flows to the light emitting diodes 81a to 81d and 82a to 82d provided in the backlight 80.

(Other embodiments)
In the first and second embodiments, the N-channel MOS transistor is connected from the control terminal Cont so that the lower detection voltage Vdet1, 2 input from the LED drive circuit 40 is equal to the reference voltage Vref. The output signal Vo is output from the DC / DC converter 20 by switching the control signal for switching control of the output voltage V. However, without detecting the detection voltage Vdet in this way, for example, to the LED drive circuit 40 The current flowing through the provided light emitting diode may be detected, and the constant voltage Vo with the power supply voltage optimized may be output from the DC / DC converter 20 to the LED drive circuit 40.

  In the above embodiment, the PWM signal for flowing current from the PWM terminal of the CPU 60 to the light emitting diode provided in the backlight 30 and the PWM signal for flowing current to the light emitting diode provided in the backlight 80 are alternately displayed. Although the configuration for outputting is shown, the PWM signal may be alternately output from separate terminals.

  In the first and second embodiments, the transistors 41 to 44 for PWM driving the LEDs of the backlight 30 and the backlight 80 and the constant current to flow to the LEDs of the backlight 30 and the backlight 80 are used. The transistors 45 to 48 are configured separately. For example, the transistor 41 and the transistor 45 are configured by one transistor, and the transistor for PWM driving and the transistor for passing a constant current are configured by one transistor. You may make it do.

  In the first and second embodiments, the configuration including the DC / DC converter 20 that boosts the input voltage Vin from the in-vehicle battery 10 from the internal power supply 10 of the device is shown. Need not boost the input voltage Vin.

  In the first and second embodiments, the brightness of the liquid crystal panel 1a of the first liquid crystal display device 1 and the brightness of the liquid crystal panel 2a of the second liquid crystal display device 2 are separately controlled by operating the operation unit 70. However, the operation of the operation unit 70 is not limited, and various setting conditions other than the operation of the operation unit 70 such as a video source (map display, DVD playback display, etc.), The luminance of the liquid crystal panel 1a of the first liquid crystal display device 1 and the luminance of the liquid crystal panel 2a of the second liquid crystal display device 2 may be adjusted separately according to the ambient brightness or the like. Further, the brightness adjustment may be automatically adjusted by the CPU 60 according to the surrounding environment and operation state.

  In the first embodiment, the backlight 30 is constituted by the light emitting diodes 31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d connected in series, and the light emitting diodes 81a to 81d, 82a to 82a connected in series are connected. 82d, 83a to 83d, 84a to 84d constitute the backlight 80, and in the second embodiment, the backlight 30 is constituted by the light emitting diodes 31a to 31d and 32a to 32d connected in series, and the light emission connected in series. Although the backlight 80 is constituted by the diodes 81a to 81d and 82a to 82d, the number of light emitting diodes constituting the backlights 30 and 80 and the way of connecting the light emitting diodes are limited to those shown in the above embodiment. Instead, it can be implemented in various forms.

  In the first embodiment, the serially connected light emitting diodes 31a to 31d, the serially connected 32a to 32d, the serially connected 33a to 33d, and the serially connected 34a to 34d are converted into PWM signals. Although they are used and driven simultaneously, they need not be simultaneously. For example, they may be sequentially shifted within a certain period T1.

  Moreover, in the said 1st, 2nd embodiment, although the 1st liquid crystal display device 1 and the 2nd liquid crystal display device 2 were comprised as a different body, you may comprise as integral.

  In the first and second embodiments, the present liquid crystal display system is configured by the two liquid crystal display devices 1 of the first liquid crystal display device 1 and the second liquid crystal display device 2. You may comprise using a display apparatus.

  Further, in the first and second embodiments, the two liquid crystal display devices 1 of the first liquid crystal display device 1 and the second liquid crystal display device 2 are used. In addition, an operation switch configured so that the switch name and the like can be seen through by illumination from the back side is arranged, and this operation switch is used as an LED backlight for illuminating from the back side of the second liquid crystal display device 2. An LED backlight may be used.

  In the second embodiment, the channel control information output from the CPU 60 is directly input to the control circuit 50. However, the channel control information is transmitted from the CPU 60 to the control circuit 50 via communication. May be.

  In the first and second embodiments, the liquid crystal display system including two display devices has been described. However, the liquid crystal display system may include three or more display devices.

DESCRIPTION OF SYMBOLS 1 1st liquid crystal display device 1a 1st liquid crystal panel 2 2nd liquid crystal display device 2a 2nd liquid crystal panel 3 Connection line 10 Car-mounted battery 20 DC / DC converter 30 Backlight 40 LED drive circuit 50 Control circuit 60 CPU
70 Operation unit 80 Backlight

Claims (4)

A liquid crystal display system comprising a first display device (1) having a first liquid crystal panel (1a) and a second display device (2) having a second liquid crystal panel (2a),
The first display device (1) includes first LEDs having LEDs (31a to 31d, 32a to 32d, 33a to 33d, and 34a to 34d) that illuminate the first liquid crystal panel (1a) from the back side. With a backlight (30),
The second display device (2) is a second LED having LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) for illuminating the second liquid crystal panel (2a) from the back side. With backlight (80),
A first PWM signal for driving the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) of the first LED backlight (30) and the second LED backlight (80) A pulse signal transmission circuit (60) for alternately transmitting a second PWM signal for driving the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) at predetermined intervals;
During the period in which the first PWM signal is transmitted from the pulse signal transmission circuit (60), a current corresponding to the pulse width of the first PWM signal is supplied to the first LED backlight (30). The LED is provided to flow through the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d), and the second PWM signal is transmitted from the pulse signal transmission circuit (60). The current corresponding to the pulse width of the second PWM signal is applied to the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) provided in the second LED backlight (80). A liquid crystal display system comprising a control circuit (40, 50) for performing current switching control so as to flow. Based on the forward voltage drop of the LEDs (31a-31d, 32a-32d, 33a-33d, 34a-34d) provided in the first LED backlight (30), the first LED backlight (30 ) To generate a first constant voltage that optimizes the voltage of the power supply, and the LEDs (81a to 81d, 82a to 82d, 83a to 83d, provided in the second LED backlight (80), 84a-84d) including a power supply circuit (20) for generating a second constant voltage that optimizes the voltage of the power supply for the second LED backlight (80) based on the forward voltage drop of 84a-84d),
The control circuit (40, 50) is configured to output the first constant generated by the power supply circuit (20) during a period in which the first PWM signal is transmitted from the pulse signal transmission circuit (60). A voltage is supplied to the first LED backlight (30), and is generated by the power supply circuit (20) during a period in which the second PWM signal is transmitted from the pulse signal transmission circuit (60). The liquid crystal display system according to claim 1, wherein the power supply circuit (20) is controlled to supply the second constant voltage to the second LED backlight (80). The control circuit (40, 50) includes the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) provided in the first LED backlight (30) and the second LED backlight. A common LED driving transistor (41-44) for driving the LEDs (81a-81d, 82a-82d, 83a-83d, 84a-84d) provided in the light (80);
The first constant voltage generated by the power supply circuit (20) is supplied to the first LED backlight (30), and the second constant voltage generated by the power supply circuit (20) is the first constant voltage. The LED (31a-31d) provided in the first LED backlight (30) by the LED driving transistors (41-44) during a period when the LED backlight (80) is not supplied to the second LED backlight (80). 32a to 32d, 33a to 33d, 34a to 34d), a current corresponding to the pulse width of the first PWM signal flows, and the second constant voltage generated by the power supply circuit (20) is The first constant voltage supplied to the second LED backlight (80) and generated by the power supply circuit (20) is not supplied to the first LED backlight (30). During the period, the LEDs (81a to 81d, 82a to 82d, 83a to 83d, 84a to 84d) included in the second LED backlight (80) are connected to the LED driving transistors (41 to 44). 3. The liquid crystal display system according to claim 2, wherein a current corresponding to a pulse width of the second PWM signal flows. The pulse signal transmission circuit (60) and the control circuit (50) are incorporated in any one of the first and second display devices (1, 2),
Of the first and second display devices (1, 2), the display device incorporating the pulse signal transmission circuit (60) and the control circuit (50) includes the first LED backlight (30). ) Provided in the LEDs (31a to 31d, 32a to 32d, 33a to 33d, 34a to 34d) and the LEDs (81a to 81d) provided to the second LED backlight (80). The operation part (70) for each adjusting the magnitude | size of the electric current which flows into 81d, 82a-82d, 83a-83d, 84a-84d) is provided. The liquid crystal display system as described in one.

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