1. Field of the Invention
The present invention relates to a display drive device for driving a display panel.
2. Description of the Related Art
In recent years, plasma display panels (PDPs) that have a thin thickness, a large screen, and high definition, have attracted attention. The PDP comprises a plurality of discharge cells (pixels) arranged in a matrix. An image is displayed on the PDP by utilizing light emission when discharge occurs in the discharge cells.
A typical AC PDP has a plurality of display electrodes arranged in parallel and a plurality of data electrodes arranged orthogonal to these display electrodes. A display drive device drives these data electrodes, and therefore, can be considered to drive capacitive load.
As the screen size, definition and luminance of PDPs have been more and more increased, display drive devices for driving the PDPs increasingly require a larger number of outputs and a higher voltage. Therefore, it is important to suppress power consumption and heat generation when the data electrode is driven.
When different potentials are applied to two data electrodes, a space between the electrodes functions as a capacitor. In other words, capacitive load is generated. When the capacitive load is driven, a large amount of power is consumed. As a conventional technique of reducing power consumption, the followings are known.
U.S. Pat. No. 7,116,137 discloses a display drive device that converts display data into a predetermined voltage level and outputs the resultant data to data electrodes. In the display drive device, a common floating potential line in a floating state is provided that is normally connected via selection switches to all output terminals in a wired OR manner. When a change in data level is detected on an output terminal at a timing of switching display data (i.e., between before and after display data is switched), the output terminal is controlled so that the output terminal temporarily goes to a high impedance (Hi-Z) at a predetermined timing (within a period when display data is switched and panel display is not performed). At the same time, the corresponding selection switch is controlled so that the output terminal is connected via the selection switch to the wired OR-connected floating potential line. By this control, display output is temporarily interrupted at output terminals at which data is changed by switching display data, so that all the output terminals are connected to the common floating potential line. In this case, the output terminals having a change in level are short-circuited, so that capacitance charges accumulated by displaying are transferred between terminals that have immediately previously output an H (=High) level and terminals that have immediately previously output an L (=Low) level. Therefore, the common floating potential line in the floating state is settled at a potential that is determined, depending on the number of H-level output terminals and the number of L-level output terminals. For example, when, of the terminals having a change in data, the number of H-output terminals is the same as the number of L-output terminals, the potential of the common floating potential line is ideally VDD/2 (VDD is the H-level potential of a display output). Therefore, the next drive operation only needs to be performed from VDD/2 to GND or VDD, whereby drive power can be reduced. Thus, this is a two-step drive technique.
U.S. Pat. No. 7,319,347 discloses another two-step drive technique in which panel electrodes and a capacitor having a load capacitance sufficiently larger than that accumulated between each panel electrode are connected to a common line corresponding to the floating potential line of U.S. Pat. No. 7,116,137 described above. The capacitance potential of the capacitor is previously set to be VDD/2. Charge and discharge are performed between the capacitor capacitance and an output terminal that has a change in data level between before and after display data is switched, so as to transfer accumulated charges so that the output terminal has the potential VDD/2, which is advantageous to the next drive operation.
In the display drive device of U.S. Pat. No. 7,116,137 described above, the common floating potential line varies for each piece of display data. For example, when display data is switched, then if all output terminals go from the H level to the L level, the advantageous effect is not obtained for such display data. Thus, there is a pattern dependence, so that power consumption cannot be sufficiently reduced. Also, a tri-state output and the common floating potential line are connected in a wired OR manner. Therefore, if the timing of the selection switch varies depending on the wiring path or the like, both the tri-state output and the common floating potential line may be selected, resulting in signal collision.
If signal collision occurs, any display data output has an influence on the common floating potential line, the potential of the common floating potential line is likely to change, i.e., vary for each piece of display data.
In the display drive device of U.S. Pat. No. 7,319,347 described above, the potential VDD/2 is initially applied to the capacitor by any means, and thereafter, electronic charges are not additionally supplied to the capacitor from the outside, for example. If electronic charges are even once lost during an operation when a change occurs in a characteristic (e.g., small leakage occurs, power supply leakage occurs, etc.), the output terminal cannot be restored to the original potential VDD/2, for example.
To solve these problems, a display drive device according to the present invention includes a low-voltage circuit section driven by a first power supply potential, a high-voltage circuit section driven by a second power supply potential higher than the first power supply potential, a voltage supply circuit for supplying a third power supply potential higher than or equal to the first power supply potential and different from the second power supply potential, a common power supply line for connecting the third power supply potential to each of a plurality of output terminals, an output selection switch circuit for temporarily switching between display data output via the high-voltage circuit section to each output terminal, and the common power supply line, during a predetermined period, and a display data determining circuit for generating a control signal for controlling the output selection switch circuit.
The display data determining circuit has a function of, when one piece of display data is switched to another piece of display data, determining a change in level of display data in the same column of a display panel from both the pieces of display data, a function of determining how electric charges accumulated between each output terminal due to a display operation are changed due to the next display operation, and a function of generating a control signal to be supplied to the output selection switch circuit based on these determination results. When it is determined in the display data determining circuit that there is a change in display data level between before and after display data is switched, display data output to each output terminal having a change and the common power supply line are temporarily switched for a predetermined period, based on the control signal of the display data determining circuit, so that the display data is caused to be temporarily at the third power supply potential. Thereby, there is not pattern dependence of display data, and in addition, the voltage of the voltage supply circuit is invariably supplied to the common power supply line, resulting in an invariably stable voltage. Therefore, power consumption of a display drive operation can be optimally reduced. Also, heat generation by a display drive operation can be reduced in an amount corresponding to the reduction of power consumption.
According to the present invention, the potential of an output terminal having a change in data output between before and after display data is switched is forcedly caused to go to the third power supply potential before driving data to be next displayed. Therefore, a change in potential of the output terminal during a drive operation can be reduced, thereby making it possible to suppress power consumption and heat generation of the display drive device. Also, there is not data dependence of display data, and in addition, the common power supply line can be invariably stably maintained at the third power supply potential.
Moreover, by performing a drive operation in a stepwise manner, a peak current during output transition of display data can be reduced, so that EMI occurring in the display drive device can also be reduced.
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
The output selection switch circuit 20 forcedly causes the potential of an output terminal 5 to be equal to the third power supply potential if the data output of the output terminal 5 changes between before and after display data is switched, thereby making it possible to reduce a change in potential of the output terminal 5 during a drive operation. In addition, since the third power supply potential is applied from the voltage supply circuit 3 to the common power supply line 4, the potential of the common power supply line 4 is invariably stable, so that a spike does not occur during a switching operation.
With the configuration of
Note that the voltage supply circuit 3 is desirably a charge pump circuit, which does not consume power very much. The display data determining circuit 10 preferably compares pieces of data held by two latches.
Also, as the voltage supply circuit 3, a circuit equipped with a smoothing capacitor is desirably provided so as to supply a stabler potential.
When the output selection switch circuit 20 is used to switch a path from display data to the power supply potential of the voltage supply circuit 3, the output connection/disconnection switch 22 is initially opened, then the two-input one-output selector 21 is switched to the power supply potential of the voltage supply circuit 3, and then after a lapse of a time enough for all the output terminals 5 to go to the stationary state, the output connection/disconnection switch 22 is closed. Conversely, when a path is switched from the power supply potential of the voltage supply circuit 3 to display data, the output connection/disconnection switch 22 is initially opened, then the two-input one-output selector 21 is switched to the display data, and after a lapse of a time enough for all the output terminals 5 to go to the stationary state, the output connection/disconnection switch 22 is closed.
As described above, with the configuration of
When display data is switched to the power supply potential of a voltage supply circuit 3 in the output selection switch circuit 20, a display data output selection switch 23 is initially opened while a potential output selection switch 24 is in the opened state (default). As a result, the display data output selection switch 23 and the potential output selection switch 24 are both opened. After a lapse of a time enough for all the output terminals 5 to go to the stationary state, the potential output selection switch 24 is closed. Note that the potential output selection switch 24 is opened at a predetermined time.
Conversely, when the power supply potential of the voltage supply circuit 3 is switched to display data, the potential output selection switch 24 is initially opened while the display data output selection switch 23 is in the opened state. As a result, the display data output selection switch 23 and the potential output selection switch 24 are both opened. After a lapse of a time enough for all the output terminals 5 to go to the stationary state, the display data output selection switch 23 is closed.
With the configuration of
With the configuration of
The output selection switch circuit 20 of
An exemplary switching sequence in
With the configuration of
Note that the voltage supply connection/disconnection switch 40 may be a switch that can electrically interrupt a path and therefore may be controlled into a high impedance state.
Note that a voltage supply circuit 3 equipped with a connection/disconnection switch may be added to
As described above, the present invention can suppress power consumption and heat generation and therefore is useful as a driver for a display panel having capacitive load, such as a PDP, an EL panel or the like.
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2007-294858 | Nov 2007 | JP | national |
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Number | Date | Country | |
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20090122048 A1 | May 2009 | US |