JP2000322030A - Liquid crystal display device and power supply method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal drive device and a power supply method for the device increasing the display quality regardless of the content of image information, and reducing power consumption for a liquid crystal display module mounted on a portable information terminal. SOLUTION: This device is provided with a liquid crystal display panel 10 comprising multiple liquid crystal pixels arranged as a matrix, an LCD driver 20A displaying a desired display data on the liquid crystal display panel 10, and a power supply selection circuit 80 supplying a drive voltage for driving the LCD driver 20A. A CPU 50 determines a load state of the LCD driver 20A based on the display data, thereby selecting a specific power supply circuit part from multiple power supply circuits based on the determination result.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal driving device and a power supply method, and more particularly, to a liquid crystal driving device and a portable information terminal having a limited power supply such as a portable telephone or a pager (registered trademark) (pager). Liquid crystal driving device and a power supply method thereof.

[0002]

2. Description of the Related Art In recent years, mobile information terminals such as mobile phones and pagers have rapidly become widespread due to the progress of semiconductor technology and liquid crystal technology, and the fusion with communication technology, and various types of information including characters and images have been widely used. Transmission and reception are being performed.
Such a portable information terminal usually includes a small liquid crystal display module (LCDM) of a few inches and an image memory for storing image data corresponding to the display screen. Has a function of displaying a black-and-white binary image centered on the information of the above or a multi-valued image to which an intermediate gradation is added.

[0003] A schematic configuration of a conventional liquid crystal display module is as follows.
As shown in FIG. 9, the liquid crystal display panel 10 roughly includes a liquid crystal display panel 10, a signal driver 20, a scanning driver 30, and a controller 40. 50 is a CPU and 60 is an image memory. The liquid crystal display panel 10 has liquid crystal pixels arranged in a matrix, signal lines connected to the liquid crystal pixels and extending in the column direction of the matrix, and scanning lines extending in the row direction of the matrix, which will be described later. By applying a signal voltage to a liquid crystal pixel selected by the signal driver 20 and the scanning driver 30, predetermined image information is displayed and output. The signal driver 20 applies a signal voltage corresponding to image information to each liquid crystal pixel via a signal line based on a horizontal control signal supplied from a controller 40 described later. Further, the scanning driver 30 includes the controller 4
Based on the vertical control signal supplied from 0, a scanning signal is sequentially applied to each scanning line to be in a selected state, and the signal voltage is applied to a liquid crystal pixel arranged at a position crossing the signal line.

The controller 40 has a horizontal clock signal,
A horizontal control signal and a vertical control signal are generated based on the vertical clock signal and the synchronization signal, and supplied to the signal driver 20 and the scanning driver 30 to apply a signal voltage to the liquid crystal pixels at a predetermined timing, Control is performed to display desired image information on the display panel 10. CPU
Reference numeral 50 performs signal conversion of image information, adjustment of a synchronization signal, generation of a clock signal, and the like, and outputs a horizontal and vertical synchronization signal, a clock signal, and display data to a controller. It processes signals and instructions from the operation unit to perform reception operation and display operation. Image memory 6
0 stores image information received by a receiving unit (not shown) and display data such as characters and images prepared in advance for each display screen of the liquid crystal display panel 10.

When the above-described liquid crystal display module is applied to a display section of a portable information terminal (pager) as shown in FIG. 10, a method of supplying driving power to a signal driver and a scanning driver is as follows. Then, the boosted voltage is divided so as to match a specified bias voltage, and constant power is supplied using a constant voltage dividing circuit. Here, the driving power supplied by the power supply circuit 108 is configured to supply the same power regardless of the display load. Therefore, in the case of a portable information terminal having only a limited power supply, the following problem occurs. Had. (1) When the display load is large (heavy) such as when the ratio of ON data of the liquid crystal display panel based on the display data is high and the ratio of OFF data is low, the driving power is insufficient for the load, and the voltage during display is low. The display quality deteriorates and the display quality deteriorates. (2) When the display load is small (light), such as when the ratio of ON data of the liquid crystal display panel due to display data is low and the ratio of OFF data is high, power is supplied from the power required to drive the load. The power becomes excessive and wasteful power is consumed.

FIG. 10 shows a schematic configuration of a general pager reception and image display unit.
Is the RF section, 102 is the decoder section, 103 is the ID-RO
M and 104 are a control unit, 105 is a display unit, 106 is an image memory, 107 is an operation unit, and 108 is a power supply circuit. RF
The unit 101 receives a carrier such as address information and image information transmitted from a message sender via a pager center from an information device such as a telephone or a personal computer, or directly from the pager center, and converts the frequency to an intermediate frequency. Then, the signal is transmitted to the subsequent decoder unit 102. Decoder section 1
02 reads out the self-address stored in the ID-ROM 33 or the address for the information service, extracts the image information addressed to itself from the information transmitted from the pager center, and performs a signal control function at the subsequent stage. To the control unit 104 having

The control section 104 stores the image information extracted by the decoder section 32 in an internal area secured in the image memory 106, performs predetermined image processing, and converts the image information into a data format corresponding to the specification of the display section 105. Then, the restored image is reproduced and displayed. The display unit 105 includes a command input via an operation unit 107 having a key switch and the like, an image memory 106
Display the message and image information stored in the. As the display unit 105 applied to the pager, for example, an STN type monochrome liquid crystal display panel having excellent display characteristics and power consumption characteristics is mounted. However, the display unit 105 is not limited to the monochrome liquid crystal display panel. In addition to a liquid crystal panel corresponding to an image, a liquid crystal panel corresponding to a multi-value image or a color image having an intermediate gradation may be used. Power supply circuit 10
Reference numeral 8 denotes an operation power supply for each of the above-described units, which performs a boosting process as necessary, and divides and supplies a boosted voltage so as to match a specified bias.

[0008]

The improvement of display quality and power saving in a portable information terminal as described above are disclosed in Japanese Patent Application Laid-Open Nos.
A technique described in Japanese Patent Application Laid-Open No. 0-214063 is known. For example, JP-A-10-124006 discloses that
As a method for reducing power consumption while optimizing a contrast ratio of a liquid crystal display, a configuration in which a user operates a switch to switch a bias ratio to switch an output voltage from a power supply circuit is shown. In such a configuration, since the bias ratio is switched by operating the switch based on the user's subjectivity, the switch operation becomes complicated, and there is a problem that an appropriate switching process cannot be performed. .

Japanese Patent Laying-Open No. 10-214063 discloses a method for reducing power consumption when a pager is in a standby state, by changing a liquid crystal driving duty according to an operation state of a system and changing the liquid crystal driving duty. A configuration is shown in which the drive voltage and the bias condition are set accordingly. In such a configuration, only in a specific operation state (standby state), a part of the liquid crystal display panel is displayed with low voltage and low duty driving, or only some rows are displayed. However, there is a problem that it is not possible to reduce the power consumption while maintaining the display quality in accordance with various information received by the user. Therefore, the present invention solves the above-described problem, and in a liquid crystal display module mounted on a portable information terminal, it is possible to reduce power consumption while improving display quality regardless of the content of image information. It is an object to provide a liquid crystal driving device and a power supply method thereof.

[0010]

According to a first aspect of the present invention, there is provided a liquid crystal display device comprising: a liquid crystal display panel including a plurality of liquid crystal pixels arranged in a matrix; and a liquid crystal display panel driven by driving the liquid crystal pixels. In a liquid crystal display device including: a liquid crystal driving unit that displays desired display data; and a driving voltage supply unit that supplies a driving voltage for driving the liquid crystal driving unit, the driving voltage supply unit includes the liquid crystal driving unit. A plurality of power supply circuit units for generating the drive voltage for supplying to the liquid crystal display, a load determination unit that determines a load state of the liquid crystal drive unit based on the display data, and a load determination unit based on a determination result from the load determination unit. A selection control unit for selecting a specific power supply circuit unit from the plurality of power supply circuit units.

According to a second aspect of the present invention, in the liquid crystal display device according to the first aspect, the driving voltage supply unit includes a display for registering the display data in which the liquid crystal driving unit enters a specific load state. A data registration unit, and a display data determination unit that determines whether the desired display data displayed on the liquid crystal display panel corresponds to the display data registered in the display data registration unit, The selection control unit, when the display data determination unit determines that the desired display data corresponds to the registered display data, selects the power supply circuit corresponding to the specific load state. It is characterized by. Claim 3
The liquid crystal display device according to claim 1, wherein the driving voltage supply unit is at least:
A first power supply circuit that generates a drive voltage corresponding to a normal load state of the liquid crystal drive unit; and a second power supply circuit that generates a drive voltage corresponding to a load state other than the normal load state. It is characterized by having.

According to a fourth aspect of the present invention, in the liquid crystal display device according to the third aspect, the second power supply circuit includes at least a driving voltage corresponding to a heavy load state of the liquid crystal driving means. It is characterized by generating. Also,
A liquid crystal display device according to a fifth aspect is the liquid crystal display device according to the third aspect, wherein the second power supply circuit generates at least a driving voltage corresponding to a light load state of the liquid crystal driving means. And According to a sixth aspect of the present invention, in the liquid crystal display device according to any one of the third to fifth aspects, the power supply circuit includes a plurality of resistance components connected in series and a connection between the resistance components. And a drive voltage output terminal provided at the contact. In the liquid crystal display device according to a seventh aspect, in the liquid crystal display device according to the sixth aspect, the selection control unit switches a connection state of the plurality of resistance components based on a determination result from the load determination unit. Thereby, a combined resistance value of the plurality of resistance components is changed.

Further, in the liquid crystal display device described in claim 8, in the liquid crystal display device according to claim 6 or 7, the selection control unit determines that the load determining unit determines that the liquid crystal driving unit is in a heavy load state. When it is determined, the power supply circuit in which the combined resistance value of the plurality of resistance components is set to a small value is selected, and when it is determined that the liquid crystal driving unit is in a light load state, the plurality of resistance components are selected. The power supply circuit in which the combined resistance value of the components is set large is selected. According to a ninth aspect of the present invention, there is provided a power supply method for a liquid crystal display device, comprising: a liquid crystal display panel including a plurality of liquid crystal pixels arranged in a matrix; and driving the liquid crystal pixels to perform desired display on the liquid crystal display panel. A power supply method for a liquid crystal display device, comprising: a liquid crystal driving unit that displays data; and a driving voltage supply unit that supplies a driving voltage for driving the liquid crystal driving unit. Determining a load state of the means, and selecting a specific power supply circuit section from a plurality of power supply circuit sections constituting the drive voltage supply means based on the determination result. I do. According to a tenth aspect of the present invention, there is provided a power supply method for a liquid crystal display device, wherein the liquid crystal display device according to the ninth aspect includes the liquid crystal display device according to any one of the second to eighth aspects. And

[0014]

Embodiments of a liquid crystal display device according to the present invention will be described below with reference to the drawings. First Embodiment First, a schematic configuration of a liquid crystal display device according to the present invention will be described with reference to FIG. In addition, about the structure equivalent to the above-mentioned prior art, the same code | symbol is attached | subjected and the description is abbreviate | omitted. 1, 10 is a liquid crystal display panel, 20A is an LCD driver (liquid crystal driving means), 40 is an LCD controller, 50 is a CPU (selection control unit), 60A is an SRAM, 70 is an operation unit, and 80 is a power supply selection circuit (drive). Voltage supply means). The LCD driver 20A includes a signal driver and a scanning driver, and outputs a signal voltage for displaying desired display data on the liquid crystal display panel 10 and scans a scanning line. Therefore, the load state of the LCD driver 20A changes according to the type of display data displayed on the liquid crystal display panel 10.

The CPU 50 supplies a horizontal control signal, a vertical control signal, and a synchronization signal to the LCD controller 40, and controls output of desired display data. Also,
It stores and reads out display data to and from an SRAM 60A, which will be described later, and outputs a signal for controlling the operation of a power supply selection circuit 80, which will be described later, based on display data to be displayed on the liquid crystal display panel 10. The SRAM 60A stores display data displayed on the liquid crystal display panel 10 for each screen. The operation unit 70 transmits an instruction input from the user to the CPU 50 via an operation button or the like.

The power supply selection circuit 80 performs a boosting process on the reference voltage VDD and divides the boosted voltage,
The operating power supply required for each of the above configurations is supplied. In particular, in the present invention, a power supply circuit section for generating a plurality of different power supplies is provided, and based on a control signal from the CPU 50, an optimal power supply is provided. A circuit section is selected to supply a driving voltage to the LCD driver 20A. Here, in order to supply a driving voltage corresponding to the load state of the LCD driver 20 </ b> A based on the display data displayed on the liquid crystal display panel 10, the plurality of different power supply circuit units include at least a heavy load state in addition to the normal load state. It has a configuration for generating and outputting a drive voltage corresponding to a load state, a light load state, or both load states. Details will be described later.

Next, the operation processing of the first embodiment in the liquid crystal display device having the above-described configuration will be described with reference to the flowchart of FIG. First, the CPU 50
Extracts data for one line of column address from display data to be displayed stored in the SRAM 60A (S101), and determines the load state of the LCD driver 20A when displaying on the liquid crystal display panel 10. Specifically, based on the extracted data, each of the display ON state (ON data) and the display OFF state (OFF data) on the liquid crystal display panel 10 when the data for one line is set to 100. Calculate the ratio. Next, the ratio between the ON data and the OFF data is compared with a predetermined light load reference value. For example, as the light load reference value, the ON data is 20
% (S102) and whether the OFF data is 35% or more (S103). If the state corresponding to the light load is continuous on all lines of the display data (S104), a selection control signal is output to the power supply selection circuit 80 so as to select a light load power supply circuit that determines and determines a light load state and generates and outputs a drive voltage corresponding to the light load state (S105). . Here, the light load state is compared with a normal load state set in advance,
This refers to a state in which power for driving the liquid crystal pixels constituting the liquid crystal display panel 10 is small.

Next, when the state corresponding to the light load is not continuous in all the lines of the display data (S10
4) As the heavy load reference value, for example, when the ON data is 5
It is determined whether or not it is 0% or more (S106) and whether or not the OFF data is 25% or less (S107), and the state corresponding to the heavy load is continued for five lines of the display data. In this case (S108), it is determined that the state is a heavy load state, and a selection control signal is output to the power supply selection circuit 80 so as to select a heavy load power supply circuit that generates and outputs a drive voltage corresponding to the heavy load state (S109). ). Here, the heavy load state is compared with a normal load state set in advance,
The state in which the power for driving the liquid crystal pixels constituting the liquid crystal display panel 10 is large. Next, if neither the light load state nor the heavy load state described above is satisfied, and the determination of the load state is completed for all the lines (S
110), it is determined that the load state is normal, and a selection control signal is output to the power supply selection circuit 80 so as to select the normal power supply circuit corresponding to the normal load state (S111).

The liquid crystal display panel 1 is operated by a predetermined power supply circuit selected based on the above series of load state determination processing.
A predetermined drive voltage is supplied to the LCD driver 20A until the display operation of the display data to 0 times out (S112), and when the display data is updated, the above-described determination processing is performed again to control the selection of the power supply circuit. Do. Thus, based on the content of the display data, the ON data and the OFF
By calculating the data ratio and comparing it with a preset load reference value, the load state of the LCD driver can be determined, and a power supply circuit that supplies a drive voltage corresponding to the load state can be selected. When the load due to the display data is light (the number of lit dots is small), it is possible to reduce the power consumption by preventing useless current from flowing, while the load due to the display data is heavy (the number of lit dots is large). In some cases, the driving capability can be increased to prevent the display quality from deteriorating. Note that, in the present embodiment, after determining whether the load state of the display data is a light load state, a processing procedure for determining whether the display data that is not a light load state is a heavy load state is shown. But
The present invention is not limited to this, and may determine the light load state after determining the heavy load state. Further, in addition to determining both the light load state and the heavy load state, the method may include a processing procedure of determining only the light load state and selecting the light load power supply circuit and the normal power supply circuit. It may have a processing procedure of determining only the load state and selecting the heavy load power supply circuit and the normal power supply circuit.

<Second Embodiment> Next, the operation of the liquid crystal display device according to the second embodiment will be described with reference to the flowchart of FIG. This embodiment has the same general configuration as the liquid crystal display device shown in FIG.
Specific display data determined to correspond to a heavy load by the PU (selection control unit, display data registration unit, display data determination unit) 50 is registered in advance as registration data, and becomes a display target on the liquid crystal display panel 10. The power supply circuit is selected according to whether or not the displayed display data matches the registered data. Specifically, first, the CPU
By pre-registering the specific display data determined to correspond to the heavy load by 50, the display data is classified into the display data corresponding to the heavy load and the other display data.
That is, in a portable information terminal such as a pager, when the power is turned on or a message is received, the liquid crystal display panel 1
In many cases, specific display data is set to be displayed at 0. Therefore, among the display data stored in the SRAM 60A, data corresponding to a heavy load is registered in advance as registration data. Here, registration of display data
For example, a method of storing the image identification information set in the header of the corresponding display data by the CPU 50, a method of setting a flag (heavy load flag) in the header of the display data, or the like can be applied.

Next, as shown in FIG. 3, display data to be displayed is input (S201), and it is determined (determined) whether or not the data corresponds to the above-described registered data (S20).
2). When the display data to be displayed corresponds to the registered data, a selection control signal is output to the power supply selection circuit 80 so as to select the heavy load power supply circuit (S2).
03). On the other hand, if the display data to be displayed does not correspond to the registered data, it is determined that the load is normal, and a selection control signal is output to the power supply selection circuit 80 so as to select the normal power supply circuit ( S204). The LCD driver 20A operates until the display operation of the display data on the liquid crystal display panel 10 times out by the predetermined power supply circuit selected based on the series of load state determination processing described above.
Is supplied (S205), and when the display data is updated, the above-described determination processing is performed again, and the selection control of the power supply circuit is performed. As described above, the specific display data corresponding to the heavy load is registered in advance as the registration data, and it is determined whether the display data corresponds to the display data to be displayed. In addition, since a power supply circuit that supplies a drive voltage corresponding to a heavy load state can be selected, the driving capability of the LCD driver can be increased, and display quality can be prevented from deteriorating.

<Third Embodiment> Next, an operation process of the liquid crystal display device according to the third embodiment will be described with reference to a flowchart of FIG. This embodiment has the same general configuration as the liquid crystal display device shown in FIG.
Specific display data determined to correspond to a light load by the PU (selection control unit, display data registration unit, display data determination unit) 50 is registered in advance as registration data, and becomes a display target on the liquid crystal display panel 10. The power supply circuit is selected according to whether or not the displayed display data matches the registered data. Specifically, first, the CPU
By pre-registering the specific display data determined to correspond to the light load by 50, the display data is classified into the display data corresponding to the light load and the other display data.
That is, in the case of a portable information terminal such as a pager, in a standby state (reception standby state) or the like, most of the display of the liquid crystal display panel 10 is set to a non-display state except a clock display or the like. Because there are many, such data that corresponds to light load among the display data,
Register as registration data. Here, for registration of display data, a method equivalent to that of the above-described second embodiment can be applied.

Next, as shown in FIG. 4, display data to be displayed is inputted (S301), and it is determined whether or not the display data corresponds to the above-mentioned registration data (S302). If the display data to be displayed corresponds to the registered data, a selection control signal is output to the power supply selection circuit 80 so as to select the light load power supply circuit (S303). On the other hand, when the display data to be displayed does not correspond to the registered data, it is determined that the load is normal, and a selection control signal is output to the power supply selection circuit 80 so as to select the normal power supply circuit ( S304). By a predetermined power supply circuit selected based on the above series of load state determination processing,
A predetermined drive voltage is supplied to the LCD driver 20A until the display operation of the display data on the liquid crystal display panel 10 times out (S305). When the display data is updated, the above-described determination processing is performed again, and the power supply circuit is turned off. Perform selection control. As described above, specific display data determined to correspond to light load is registered in advance as registration data, and is compared with the display data to be displayed, thereby reducing the load.
Since the light load state of the CD driver can be determined and a power supply circuit that supplies a drive voltage corresponding to the light load state can be selected, unnecessary current flow to the LCD driver can be prevented, and power consumption can be reduced. Reduction can be achieved.

In the above-described second and third embodiments, the LCD driver determines whether the display data to be displayed corresponds to the registered data registered in advance. Load condition, or
Although the processing procedure for determining whether the vehicle is in the light load state has been described, the present invention is not limited to this, and the specific display data corresponding to each of the heavy load and the light load is registered in advance, so that the heavy load and the light load can be registered. One that has a processing procedure for classifying display data corresponding to each of a load and a light load and other normal display data and selecting one of a heavy load power supply circuit, a light load power supply circuit, and a normal power supply circuit. It may be. In each of the above-described embodiments, the case where the load state of the display data is determined and the power supply circuit is selected by the individual method has been described. However, the ON / OFF ratio of the display data and the comparison with the registered data are described. The load state may be determined by using both of the determination processes based on the load.

Next, an embodiment of a power supply selection circuit applied to the liquid crystal display device according to the present invention will be described with reference to the drawings. (First Embodiment) FIG. 5 is a circuit diagram showing a first embodiment of the power supply selection circuit. As shown in FIG. 5, the power supply selection circuit 80 includes a voltage adjustment circuit 81, a switch SW1,
It has a light load power supply circuit (second power supply circuit) PL, a normal power supply circuit (first power supply circuit) PN, and a heavy load power supply circuit (second power supply circuit) PH. Voltage adjustment circuit 81
Generates the maximum voltage V5 required for the driving operation of the LCD driver 20A by, for example, boosting the reference voltage VDD. The switch SW1 is a C (not shown).
The selection control signal from the PU 50, that is, the ON / OFF ratio of the display data and the LC based on the comparison with the registered data
Based on the determination result of the load state of the D driver 20A, any one of the light load power supply circuit PL, the normal power supply circuit PN, and the heavy load power supply circuit PH is selected, and the maximum voltage V
5 is switched.

A light load power supply circuit PL, a normal power supply circuit PN,
The heavy load power supply circuit PH has resistance components RL1 to RL, respectively.
5, RN1 to RN5, RH1 to RH5 are connected in series, and each resistance component RL1 to RL5, RN1 to RN
5, a drive voltage output terminal is provided at a connection point between RH1 and RH5, and predetermined drive voltages V4 to V1 required for the drive operation of the LCD driver 20A are output. Here, the resistance components RL1 to RL5 constituting the light load power supply circuit PL are:
RL1 = 2R, RL2 = 2R, RL3 = 10, respectively
R, RL4 = 2R and RL5 = 2R are set to the resistance value (the combined resistance value is 18R). Also, the normal power supply circuit PN
Are respectively RN1 to RN5.
= R, RN2 = R, RN3 = 5R, RN4 = R, RN5
= R (the combined resistance is 9R), and the resistance components RH1 to RH5 constituting the heavy load power supply circuit PH are RH1 = １ ／ R, RH2 = １ ／ R, and RH3 =
The resistance values are set to 5 / 2R, RH4 = 1 / 2R, and RH5 = 1 / 2R (the combined resistance value is 9 / 2R).

Therefore, the current value IL (= V5 / 18R) flowing down in the light load power supply circuit PL is reduced by half compared to the current value IN (= V5 / 9R) flowing down in the normal power supply circuit PN. Therefore, the driving capability of the LCD driver 20A is adjusted to half of the normal driving capability.
On the other hand, the current value IH flowing down in the heavy load power supply circuit PH
(= 2 × V5 / 9R) is twice as large as the current value IN (= V5 / 9R) flowing down in the normal power supply circuit PN, so that the driving capability of the LCD driver 20A is increased. It is adjusted to twice the normal value.

By applying the power supply selection circuit having such a configuration to each of the above-described embodiments, when it is determined that the display data to be displayed is in a heavy load state, the combined resistance value is small. When the power supply circuit is determined to be in the light load state, the switch SW1 is switched so as to select a power supply circuit having a large combined resistance value, and the power supply circuit has a driving capability according to the load state of the display data. Can be used properly, so that the display operation can be performed with a sufficient driving capacity so as not to cause the deterioration of the display quality under the heavy load condition, while the unnecessary current flows under the light load condition. And power consumption can be reduced. Further, the above-described switching of the power supply circuit and the control of optimizing the driving capability can be realized by a simple configuration using a resistance component and a switch connected in series.

(Second Embodiment) Next, a second embodiment of the power supply selection circuit applied to the liquid crystal display device according to the present invention will be described with reference to the drawings. FIG. 6 is a circuit configuration diagram showing a second embodiment of the power supply selection circuit. Here, in the present embodiment, a power supply selection circuit having a normal power supply circuit and a heavy load power supply circuit will be described. Note that the first
Configurations equivalent to those of the embodiment are denoted by the same reference numerals and described. As shown in FIG. 6, the power supply selection circuit 80 includes a voltage adjustment circuit 81, a switch SW2, a normal power supply circuit (first power supply circuit) PN, a heavy load power supply circuit (second power supply circuit) PH, have. The switch SW2 is controlled based on a selection control signal from the CPU 50 (not shown), that is, an ON / OFF ratio of display data and a determination result of the load state of the LCD driver 20A based on comparison with registered data. And heavy load power circuit PH
Is selected to switch the connection state with the maximum voltage V5.

The normal power supply circuit PN has a configuration in which resistance components RN1 to RN5 are connected in series, respectively, similarly to the first embodiment described above, and a drive voltage output is connected to a connection contact between the respective resistance components RN1 to RN5. And a predetermined driving voltage V4 to V1 required for the driving operation of the LCD driver 20A.
Is output. On the other hand, the heavy load power supply circuit PH has a resistance component connected in series (hereinafter referred to as a series resistance component) RH11.
RH13 to RH13 and RH14 to RH16 are connected in parallel, and drive voltages V4 and V3 are connected to each other by a connection contact between the series resistance components RH11 to RH13.
Drive voltage V to drive voltage V
2, V1 is output. Here, the resistance components RN1 to RN5 constituting the normal power supply circuit PN are respectively RN1 =
R, RN2 = R, RN3 = 5R, RN4 = R, RN5 =
R is set to the resistance value (the combined resistance value is 9R), and the resistance components RH11 to RH1 constituting the heavy load power supply circuit PH are set.
6, RH11 = R, RH12 = R, RH13
= 7R, RH14 = 7R, RH15 = R, RH16 = R
(The combined resistance value is 9 / 2R).

As described above, by connecting the resistance components constituting the power supply circuit in parallel, the resistance components are simply connected in series, and the resistance value of each resistance component constituting the heavy load circuit is set low. As compared with the above, since the type (resistance value) of the resistance component to be used can be made uniform and the combined resistance value can be reduced, a large driving capability can be realized by a simple manufacturing process and a circuit configuration. In this embodiment, only the normal power supply circuit PN and the heavy load power supply circuit PH have been described. However, the power supply selection circuit applied to the present invention is not limited to this. And a light load power supply circuit PL, or a normal power supply circuit PN and a heavy load power supply circuit P.
H, and may have three types of power supply circuits including a light load power supply circuit PL. In short, by making the types of resistance components used uniform and changing the connection form of the resistance components, a plurality of power supply circuits with different combined resistance values are configured, and the driving capability according to the load state based on the display data is increased. As long as the connection is realized, a connection form other than the connection form shown in FIG. 6 may be used.

Third Embodiment Next, a third embodiment of the power supply selection circuit applied to the liquid crystal display device according to the present invention will be described with reference to the drawings. FIG. 7 is a circuit diagram showing a third embodiment of the power supply selection circuit. Here, in the present embodiment, a power supply selection circuit having a normal power supply circuit and a heavy load power supply circuit will be described. Note that the first
Alternatively, the same components as those of the second embodiment will be described with the same reference numerals. As shown in FIG.
0 is a voltage adjustment circuit 81 and a power supply circuit changeover switch 82
, Switch SW3, normal power supply circuit (first power supply circuit) PN, heavy load power supply circuit (second power supply circuit) PH
And The power supply circuit switch 82 is provided with a selection control signal from the CPU 50 (not shown),
Based on the ON / OFF ratio of the display data and the determination result of the load state of the LCD driver 20A based on the comparison with the registered data, the drive voltage output terminal (V
2, V1) and the state using the drive voltage output terminals (V2, V1) on the side of the heavy load power supply circuit PH so that the normal power supply circuit PN and the heavy load power supply circuit PH are selected. And the maximum voltage V5, and switches ON / OFF the switch SW3 to switch the output state of the drive voltage output terminals (V2, V1).

The normal power supply circuit PN includes the series resistance components RN1 to RN5, as in the first and second embodiments.
It has a configuration connected to the maximum voltage V5, and each resistance component RN
A drive voltage output terminal is provided at a connection contact between the first to RN5, and predetermined drive voltages V4 to V1 required for the drive operation of the LCD driver 20A are output. Here, the driving voltage V1
And the output state of V2 from the output terminal is determined by ON / OF of the switch SW3 controlled by the power supply circuit changeover switch 82.
It is controlled by the F operation. The heavy load power supply circuit PH has a configuration in which the series resistance components RH21 to RH23 are connected to the maximum voltage V5 via a power supply circuit changeover switch 82, and a drive voltage output terminal is connected to a connection contact between the respective resistance components RH21 to RH23. Are provided, and drive voltages V1 and V2 are output. Here, the resistance component RN constituting the normal power supply circuit PN
1 to RN5 are respectively RN1 = R, RN2 = R, RN
3 = 5R, RN4 = R, RN5 = R, and the resistance component RH constituting the heavy load power supply circuit PH
21 to RH23 are RH21 = 7R and RH22, respectively.
= R, RH23 = R.

In the power supply selection circuit having such a circuit configuration, when the selection control signal from the CPU 50 indicates that the display data to be displayed is in a normal load state, the power supply circuit The changeover switch 82 sets the heavy load power supply circuit PH to a non-selection state, disconnects the connection state with the maximum voltage V5, and switches the switch SW3
Is turned on, the drive voltages V4, V3, and V2, V1 are output from the drive voltage output terminal on the normal power supply circuit PN side. On the other hand, when the selection control signal from the CPU 50 indicates that the display data to be displayed is in a heavy load state, the power supply circuit changeover switch 82 sets the heavy load power supply circuit PH to the selected state. While ensuring the connection with the maximum voltage V5, switch SW3 is turned off.
In the F state, the drive voltages V2 and V1 are output from the drive voltage output terminals on the heavy load power supply circuit PH side, and the drive voltages V4 and V3 are output from the drive voltage output terminals on the normal power supply circuit PN side.

Therefore, according to the present embodiment, the drive voltage output terminals (V4, V3) can be shared by sharing a part of the circuit configuration in both the normal load state and the heavy load state. In addition, the driving capability can be switched according to the load state of the display data while simplifying and reducing the circuit configuration. In this embodiment, only the normal power supply circuit PN and the heavy load power supply circuit PH have been described. However, the power supply selection circuit applied to the present invention is not limited to this. As in the case shown in the example, the normal power supply circuit PN and the light load power supply circuit PL
The power supply circuit may include three types of power supply circuits including a normal power supply circuit PN, a heavy load power supply circuit PH, and a light load power supply circuit PL. In short, if the drive capability is switched by changing the connection state of the resistance component according to the load state of the display data while also using a part of the circuit configuration of the power supply circuit, a connection form other than that shown in FIG. May be used.

(Fourth Embodiment) Next, a fourth embodiment of the power supply selection circuit applied to the liquid crystal display device according to the present invention will be described with reference to the drawings. FIG. 8 is a circuit diagram showing a fourth embodiment of the power supply selection circuit. Here, in the present embodiment, a power supply selection circuit having a normal power supply circuit and a light load power supply circuit will be described. Note that the first
Configurations equivalent to those of the third to third embodiments will be described with the same reference numerals. As shown in FIG.
0 is a voltage adjustment circuit 81 and a power supply circuit changeover switch 82
a to 82e and resistance components R1 to R5 and R11 to R15
And Power supply circuit changeover switches 82a to 82
e is a selection control signal from the CPU 50 not shown,
That is, based on the ON / OFF ratio of the display data and the determination result of the load state of the LCD driver 20A based on the comparison with the registered data, the resistance components R1 to R5 and R11 to R11 are determined.
The connection state of R15 is switched between a series connection of only the resistance components R1 to R5 and a series connection of the resistance components R1 to R5 and R11 to R15.

The resistance components R1 to R5 are connected to the high potential side (primary side) of the power supply circuit changeover switches 82a to 82e, respectively. Further, the resistance components R11 to R15 are connected to the second path side on the low potential side (secondary side) of the power supply circuit changeover switches 82a to 82e, respectively. In addition, the second potential is set on the low potential side (secondary side) of the power supply circuit changeover switches 82a to 82e.
No resistance component is connected to the first path provided in parallel with the path. That is, each power supply circuit changeover switch 82
The first connection state realized by a to 82e is such that each of the resistance components R1 to R5 is between the highest voltage V5 and the lowest voltage (GND).
5 and each of the power supply circuit changeover switches 82a to 82e are directly connected alternately and directly. On the other hand, the second connection state realized by each of the power supply circuit changeover switches 82a to 82e is such that each of the resistance components R1 to R5 and each of the power supply circuit changeover switches 82a to 82 are between the highest voltage V5 and the lowest voltage (GND).
82e and each of the resistance components R11 to R15 are directly connected alternately and directly.

Here, the resistance components R1 to R5 are R1 = R, R2 = R, R3 = 5R, R4 = R, and R5 = R, respectively.
And the resistance components R11 to R15
Are respectively R11 = R, R12 = R, R13 = 5R,
R14 = R and R15 = R are set to the resistance values. In the power supply selection circuit having such a circuit configuration, CP
If the selection control signal from U50 indicates that the display data to be displayed is in the normal load state, the power supply circuit changeover switches 82a to 82e are used to switch the display data to the first connection state. And the resistance component R
Circuit configuration in which 1 to R5 are connected in series (combined resistance value is 9R)
And the first of the power supply circuit changeover switches 82a to 82d.
A drive voltage V4 having a drive capability corresponding to a normal load state is provided from a connection point between the path side of the resistor and each of the resistance components R2 to R5.
To V1 are output.

On the other hand, the selection control signal from the CPU 50 is
If the display data to be displayed indicates a light load state, the power supply circuit changeover switch 8
The second connection state is switched and set by 2a to 82e, and the resistance components R1 to R5 and the resistance components R11 to R1 are set.
5 are connected alternately in series (the combined resistance value is 18
R), and the respective resistance components R11 to R14 on the second path side.
And connection resistances of the resistance components R2 to R5 output drive voltages V4 to V1 having a drive capability corresponding to a light load state. Therefore, according to the present embodiment, the drive voltage output terminals (V4 to V1) can be shared in both the normal load state and the light load state, so that the display data load can be simplified while simplifying the circuit configuration. The driving ability can be switched according to the state.

In this embodiment, only the normal power supply circuit PN and the light load power supply circuit PL have been described. However, the power supply selection circuit applied to the present invention is not limited to this. Two types of power supply circuits including a power supply circuit PN and a heavy load power supply circuit PH, or a normal power supply circuit PN
And a heavy load power supply circuit PH and a light load power supply circuit PL.
It may have a different type of power supply circuit. In short, if the drive voltage is switched by changing the connection path of the resistance component according to the load state of the display data while sharing the drive voltage output terminal of the power supply circuit, the connection form other than the connection form shown in FIG. It may be something. As described above, the power supply circuit described in each of the embodiments and examples includes the control unit 104, the display unit 105, and the image memory 106 of the pager illustrated in FIG.
The present invention is not limited to the above-described pager, and is preferably applied to a portable information terminal having a limited power supply such as a mobile phone, a PHS, or a PDA. it can.

[0041]

According to the present invention, the load determining unit determines the load state of the liquid crystal driving unit based on the display data, and the selection control unit determines the load state. By selecting a specific power supply circuit section from among a plurality of power supply circuit sections based on the determination result of (1), the power supply circuit can be switched in real time according to display data, and the driving capability can be optimized. When the driving unit is in a heavy load state, the driving voltage is increased to prevent the display quality from deteriorating, and when the driving unit is in a light load state, it is possible to suppress unnecessary current flow and reduce power consumption. it can. According to the second aspect of the present invention, display data having a specific load state is registered in the display data registration unit in advance,
If the display data determining unit determines that the desired display data corresponds to the display data registered in the display data registering unit, the power supply circuit is switched, so that the power supply circuit that supplies the drive voltage corresponding to the load state is appropriately set. Therefore, it is possible to optimize the driving ability of the liquid crystal driving means to improve the display quality or reduce the power consumption.

According to the present invention, the power supply circuit is constituted by a plurality of resistance components connected in series, and further based on a judgment result from the load judgment unit.
By switching the connection state of the plurality of resistance components, when it is determined that the load state is a heavy load state, a power supply circuit in which the combined resistance value of the plurality of resistance components is set to a small value is selected, and when the load state is a light load state. If it is determined, a power supply circuit with a large combined resistance value can be selected, so that switching of the power supply circuit and control of optimizing the driving capability can be realized with a simple circuit configuration.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of a liquid crystal display device according to the present invention.

FIG. 2 is a flowchart illustrating an operation process of the liquid crystal display device according to the first embodiment.

FIG. 3 is a flowchart illustrating an operation process of the liquid crystal display device according to the second embodiment.

FIG. 4 is a flowchart illustrating an operation process of a liquid crystal display device according to a third embodiment.

FIG. 5 is a circuit configuration diagram of a power supply selection circuit according to the first embodiment.

FIG. 6 is a circuit configuration diagram of a power supply selection circuit according to a second embodiment.

FIG. 7 is a circuit configuration diagram of a power supply selection circuit according to a third embodiment.

FIG. 8 is a circuit configuration diagram of a power supply selection circuit according to a fourth embodiment.

FIG. 9 is a schematic configuration diagram showing a conventional liquid crystal display module.

FIG. 10 is a schematic configuration diagram of a portable information terminal (pager).

[Explanation of symbols]

Reference Signs List 10 liquid crystal display panel 20A LCD driver (liquid crystal drive means) 40 LCD controller 50 CPU (load determination unit, selection control unit, display data determination unit) 60A SRAM (display data registration unit) 70 operation unit 80 power supply selection circuit (drive voltage supply Means) 81 Voltage adjustment circuit 82, 82a to 82e Power supply circuit switch SW1-SW3 Switch PN Normal power supply circuit (first power supply circuit) PL Light load power supply circuit (second power supply circuit) PH Heavy load power supply circuit (second power supply circuit) Power circuit)

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04M 1/73 H04M 1/73 // H04B 7/26 H04B 7/26 X F term (Reference) 2H093 NC01 NC50 NC52 ND39 5C006 AF54 BF24 BF42 BF43 FA47 5C080 AA10 BB05 DD26 FF12 JJ02 JJ07 KK47 5K027 AA11 BB17 FF22 MM17 5K067 AA43 BB04 BB22 EE02 FF31 KK05

Claims (10)

[Claims] 1. A liquid crystal display panel comprising a plurality of liquid crystal pixels arranged in a matrix, a liquid crystal driving means for driving the liquid crystal pixels to display desired display data on the liquid crystal display panel, and the liquid crystal. A drive voltage supply unit for supplying a drive voltage for driving the drive unit, wherein the drive voltage supply unit includes a plurality of power supplies for generating the drive voltage for supply to the liquid crystal drive unit A circuit unit; a load determining unit that determines a load state of the liquid crystal driving unit based on the display data; and a specific power circuit unit among the plurality of power circuit units based on a determination result from the load determining unit. A liquid crystal display device comprising: 2. The display device according to claim 1, wherein the driving voltage supply unit includes a display data registration unit for registering the display data at which the liquid crystal driving unit enters a specific load state, and the desired display data displayed on the liquid crystal display panel is A display data determination unit that determines whether or not the display data registered in the display data registration unit corresponds to, the selection control unit, by the display data determination unit, the desired display data, 2. The liquid crystal display device according to claim 1, wherein when it is determined that the display data corresponds to the registered display data, the power supply circuit corresponding to the specific load state is selected. 3. The driving voltage supply means includes:
A first power supply circuit that generates a drive voltage corresponding to a normal load state of the liquid crystal drive unit; and a second power supply circuit that generates a drive voltage corresponding to a load state other than the normal load state. 3. The liquid crystal display device according to claim 1, wherein: 4. The liquid crystal display device according to claim 3, wherein said second power supply circuit generates at least a drive voltage corresponding to a heavy load state of said liquid crystal drive means. 5. The liquid crystal display device according to claim 3, wherein said second power supply circuit generates at least a drive voltage corresponding to a light load state of said liquid crystal drive means. 6. The power supply circuit according to claim 1, wherein the power supply circuit includes a plurality of resistance components connected in series, and a drive voltage output terminal provided at a connection contact between the respective resistance components. 6. The liquid crystal display device according to any one of items 3 to 5. 7. The method according to claim 7, wherein the selection control unit changes the combined resistance value of the plurality of resistance components by switching a connection state of the plurality of resistance components based on a determination result from the load determination unit. The liquid crystal display device according to claim 6, wherein: 8. The selection control unit, wherein when the load determination unit determines that the liquid crystal driving unit is in a heavy load state, the combined resistance value of the plurality of resistance components is set to be small. A power supply circuit is selected, and when it is determined that the liquid crystal driving unit is in a light load state, the power supply circuit having a large combined resistance value by the plurality of resistance components is selected. Item 8. The liquid crystal display device according to item 6 or 7. 9. A liquid crystal display panel comprising a plurality of liquid crystal pixels arranged in a matrix, liquid crystal driving means for driving said liquid crystal pixels to display desired display data on said liquid crystal display panel, and said liquid crystal. In a power supply method for a liquid crystal display device, comprising: a drive voltage supply unit for supplying a drive voltage for driving a drive unit; a process for determining a load state of the liquid crystal drive unit based on the display data; A method of selecting a specific power supply circuit section from a plurality of power supply circuit sections constituting the drive voltage supply means based on a result of the determination. 10. A method for supplying power to a liquid crystal display device according to claim 9, comprising the liquid crystal display device according to claim 2. Description: