1. Field of the Invention
The present invention relates to a capacitive-load driving circuit and a plasma display apparatus using the same, and more particularly, to a circuit technique capable of properly handling the temperature rise occurring due to the driving of capacitive loads in a plasma display panel, an electronic luminescence panel, and the like.
2. Description of the Related Art
Recently, a variety of display apparatuses have been researched and developed, and the research and development of thin flat display apparatuses, exemplified by plasma display panels (PDP) and electronic luminescence (EL) panels, has been proceeding. Among them, the PDP, with its ability to achieve a large-screen, fast-response display and its improved display quality, has been attracting attention as a display apparatus that has the potential of replacing the traditional CRT.
The PDPs are largely classified as AC or DC. The DC PDPs have the characteristic that the matrix discharge electrodes are exposed in each discharge cell and the electric field control of the discharge space in the cell is easy. On the other hand, the AC PDPs have the characteristic that the matrix discharge electrodes are covered with a dielectric layer, which reduces electrode degradation due to discharge and achieves a longer life. Further, a three-electrode panel construction (three-electrode surface-discharge AC-type PDP), in which a front plate with X electrodes and Y electrodes formed thereon in the horizontal line direction and a back panel with address electrodes in the vertical column direction are simply laminated together one on top of the other, has been commercially implemented, facilitating the construction of a higher-resolution display.
Incidentally, in a prior art technique for achieving power reduction in a pulsed capacitive-load driving circuit, it is known to provide a power recovery circuit that utilizes a phenomenon of resonance for energy transfer between load capacitance and inductance. One specific example of the power recovery technique suitable for a driving circuit where the load capacitance varies greatly for driving each individual load electrode by a mutually independent voltage in accordance with display image, as in an address electrode driving circuit, is the low power driving circuit disclosed in Japanese Unexamined Patent Publication (Kokai) No. 05-249916.
The prior art capacitive-load driving circuit recovers power by utilizing a phenomenon of resonance, but with the recent trend toward higher-resolution and larger-screen plasma display panels, the power consumption reduction design has been losing its effectiveness significantly. Specifically, when the output frequency of the driving circuit is increased to increase the resolution of the panel, it becomes necessary to reduce the resonance time in order to maintain the control performance of the panel. If the power consumption of the driving circuit cannot be reduced sufficiently, the cost involved in removing heat from various parts of the display, and therefore, the component cost, increases, and besides, this could lead to a situation where the display brightness is reduced due to the limit of the heat dissipation capability of the display apparatus itself, or where the advantage of the flat panel display, i.e., thin and light-weight construction, cannot be exploited to the full.
Furthermore, as the output frequency of the driving circuit increases, power consumption increases due to the generation of high-voltage pulses to drive the plasma display panel, and a temperature rise in the driving circuit (drive IC) becomes a serious concern.
The prior art and the problems associated with the prior art will be described in detail later with reference to accompanying drawings.
An object of the present invention is to provide a capacitive-load driving circuit capable of distributing a temperature rise (power consumption) in a circuit that drives a capacitive load. Another object of the invention is to provide a plasma display apparatus that uses such a capacitive-load driving circuit.
According to the present invention, there is provided a capacitive-load driving circuit including a configuration in which a driving power supply source is connected to an output terminal via a driving device, comprising a power distributing circuit inserted between the driving power supply source and the driving device.
According to the present invention, there is also provided a capacitive-load driving circuit including a configuration in which a reference potential point is connected to an output terminal via a driving device, comprising a power distributing circuit inserted between the reference potential point and the driving device.
The power distributing circuit may be a resistive element having an impedance whose value is not smaller than one-tenth of the value of a resistive component of the conducting impedance of the driving device. The power distributing circuit may be a high-power resistor having a capability to handle power higher than the allowable power of the driving device. The power distributing circuit may be a constant-current source.
The driving power supply source may output a plurality of different voltage levels in a selective manner. The power distributing circuit may include a plurality of power distributing units, one for each of the plurality of different voltage levels. Each of the power distributing units may have a function as a switch for selecting one of the plurality of different voltage levels. The driving device may be a device whose input withstand voltage is higher than an output voltage.
Further, according to the present invention, there is provided a capacitive-load driving circuit including a configuration in which a plurality of driving devices for driving a plurality of capacitive loads are formed in integrated-circuit form, wherein each of the driving devices is connected to a driving power supply source or a reference potential point via a power distributing circuit.
The capacitive-load driving circuit may further comprise a diode inserted between each of the capacitive loads and a corresponding one of the driving devices. Each of the power distributing circuits may be a resistive element having an impedance whose value is not smaller than one-tenth of the conducting impedance of the driving device divided by the number of driving devices connected to the power distributing circuit. Each of the power distributing circuits may be a high-power resistor having a capability to handle power higher than the allowable power of the driving device. Each of the power distributing circuits may be a constant-current source.
The driving power supply source may output a plurality of different voltage levels in a selective manner. The power distributing circuit may include a plurality of power distributing units, one for each of the plurality of different voltage levels. Each of the power distributing units may have a function as a switch for selecting one of the plurality of different voltage levels. The driving device may be a device whose input withstand voltage is higher than an output voltage.
A ground terminal of each of the integrated driving devices may be connected to the driving power supply source via the power distributing circuit. A ground terminal of each of the integrated driving devices may be connected to the reference potential point via the power distributing circuit. A series connection of each of the power distributing circuit and a switch device may be provided between each of the driving devices and the driving power supply source or the reference potential point.
The capacitive-load driving circuit may be constructed as a driving module containing a plurality of driving integrated circuits for driving the capacitive loads. Each of the driving integrated circuits may comprise a high-voltage output device whose input withstand voltage is increased up to a driving power supply voltage, and a flip-flop that drives a control input of the output device to a full-swing level either at the driving power supply voltage or at the reference potential. Each of the driving integrated circuits may include a buffer driven by a logic voltage, and wherein an output of the buffer may be connected to an input terminal of the each driving device, and the power distributing circuit to an inverting input terminal of the each driving device, thereby applying self-biasing to the driving device by a voltage drop occurring across the power distributing circuit. The capacitive-load driving circuit may further comprise a switch device inserted between the power distributing circuit and the driving power supply source or the reference potential point, and the switch being caused to conduct after the driving devices have been switched into a conducting state.
According to the present invention, there is provided a capacitive-load driving circuit including a configuration in which a driving power supply source is connected to an output terminal via a driving device, wherein the driving power supply source outputs a plurality of different voltage levels in a selective manner.
The driving power supply source may raise or lower an output voltage in steps by switching the output voltage between the plurality of voltage levels within a drive voltage amplitude, while retaining the ON/OFF states of the driving device.
According to the present invention, there is also provided a capacitive-load driving circuit for driving a capacitive load, connected to an output terminal, by a driving device, comprising a resistive impedance inserted in series to the output terminal.
The resistive impedance may provide an impedance whose value is not smaller than one-tenth of the value of a resistive component of the conducting impedance of at least one of the driving devices. The resistive impedance may be a distributed resistor showing a resistance value not smaller than three-tenths of the value of a resistive component of the conducting impedance of at least one of the driving devices. The capacitive-load driving circuit may further comprise a driving power supply source connected to the output terminal via the driving device, and a power distributing circuit inserted between the driving power supply source and the driving device.
Furthermore, according to the present invention, there is also provided a plasma display apparatus including a capacitive-load driving circuit used as an electrode driving circuit.
The capacitive-load driving circuit may be used as a driving circuit for driving address electrodes. The plasma display apparatus may be a three-electrode surface-discharge AC plasma display apparatus in which the address electrodes are formed on a first substrate and X and Y electrodes are formed on a second substrate; and thickness of a conductive layer of each of the address electrodes may be reduced to one half or less of the thickness of a conductive layer formed from the same material as the conductive layer of each of the X and Y electrodes. The plasma display apparatus may be a three-electrode surface-discharge AC plasma display apparatus in which the address electrodes are formed on a first substrate and X and Y electrodes are formed on a second substrate; and each of the address electrodes may be formed from a plurality of conductive metal layers, and an arbitrary one of the conductive metal layers is omitted.
In addition, according to the present invention, there is also provided an inductance-load driving circuit for driving an inductive load, connected to an output terminal, by a driving device, wherein a resistive impedance is inserted in series to the output terminal.
The resistive impedance may provide an impedance whose value is not smaller than one-tenth of the value of a resistive component of the conducting impedance of at least one of the driving devices.
According to an exemplary embodiment of the present invention, a plasma display apparatus including capacitive loads and a driving circuit includes a driving power source supplying a drive voltage to the capacitive load, a reference potential terminal supplying a reference potential to the capacitive load, a drive IC having a first input terminal coupled to the driving power source via a resistor that is an external device different from the drive IC, a second terminal coupled to the reference potential terminal without interposing a resistor, first and second switching devices, the first switching device being coupled to the first input terminal, and the second switching device being coupled to the second input terminal, and the drive IC having an output terminal, connected to each switching device, which selectively outputs the drive voltage or the reference potential by switching the first and second switching devices, wherein one of terminals of the first switching device is coupled to the first input terminal and the other of the terminals is coupled to the output terminal, one of terminals of the second switching device is coupled to the second input terminal and the other of the terminals is coupled to the other of the terminals of the first switching device and the output terminal, and the drive voltage and the reference potential are selectively supplied to the capacitive load via the output terminal according to control signals inputted to control terminals of the first and second switching devices, wherein the drive IC includes one each of the first input terminal and the second input terminal, n (n is an integer larger than or equal to 2) each of the first and second switching devices and the output terminals, and each of the n sets of the first and second driving devices and the output terminals correspond to each of n loads of the capacitive loads, and the drive voltage is supplied to each of the plurality of capacitive loads corresponding to each of the n sets from the driving power source via the resistor, the first input terminal, the each first switching device of the n sets, and the output terminal.
According to an exemplary embodiment of the present invention, a plasma display apparatus having a plurality of capacitive loads and a driving circuit includes a plurality of driving devices driving a plurality of capacitive loads in an integrated-circuit form; a driving power source supplying a drive voltage to the capacitive load, a reference potential source supplying a reference potential to the capacitive loads, wherein the integrated circuit includes a first input terminal coupled to the driving power source via a resistor that is an external device different from the drive IC, one second input terminal coupled to the reference potential terminal without interposing a resistor, and a plurality of output terminals respectively corresponding to the plurality of driving devices, each of the plurality of driving devices includes a first switching device having one of the terminals coupled to the first input terminal and the other terminals coupled to the output terminal; and a second switching device having one of terminals coupled to the second input terminal and the other of the terminals coupled to the other of the terminals of the first switching device and the output terminal, and the drive voltage and the reference potential are selectively supplied to the capacitive load via the output terminal according to control signals inputted to control terminals of the first and second switching devices, and wherein the drive voltage is supplied to each of the plurality of capacitive loads corresponding to each of the plurality of driving devices from the driving power source via the resistor, the first input terminal, each of the first switching devices of the plurality of driving devices, and the output terminal.
The present invention will be more clearly understood from the description of the preferred embodiments as set forth below with reference to the accompanying drawings, wherein:
Before proceeding to the detailed description of the preferred embodiments of the invention, problems associated with a prior art capacitive-load driving circuit and a plasma display apparatus using the same will be described first.
The following description deals primarily with the address driving circuit (address drive IC) of the plasma display apparatus, but it will be recognized that the capacitive-load driving circuit of the invention can be applied not only for the address driving circuit of the plasma display apparatus, but also for other circuits for driving the capacitive loads (discharge cells), such as the X driving circuit and the Y driving circuit; furthermore, the circuit technique of the invention can be applied extensively to circuits for driving various capacitive loads other than those in the plasma display apparatus, for example, to circuits for driving logic gates formed from MOS transistors (the gate of each transistor to be driven can be considered a capacitor, with which a capacitor or the like, parasitic on an interconnection, etc., is combined to form a capacitive load).
The configuration shown in
More specifically, the display panel (plasma display panel: PDP) 101 is largely classified as AC or DC. The DC PDP has the characteristic that the matrix discharge electrodes are exposed in each discharge cell 107 and the electric field control of the discharge space in the cell is easy. Furthermore, in the case of the DC PDP, since the electrode polarities are limited to the anode A1-Ad and the cathode K1-KL, it is easy to optimize the discharge glow state and, by also utilizing a technique that produces a preliminary discharge using a sub-anode electrode SA1-SA(d/2), etc. shared between adjacent anode electrodes, the main discharge voltage to be applied between the anode and cathode to produce a display can be reduced and, in addition, the display can be made faster. The driving section comprises, as described above, three driving circuits, i.e., the anode driving circuit 102, cathode driving circuit 103, and sub-anode driving circuit 104, and the control circuit 105 for controlling these driving circuits.
On the other hand, the AC PDP has the characteristic that the matrix discharge electrodes are covered with a dielectric layer, which reduces electrode degradation due to discharge and achieves a longer life. Furthermore, a three-electrode panel construction (three-electrode surface-discharge AC PDP), in which a front plate with X electrodes and Y electrodes formed thereon in the horizontal line direction and a back panel with address electrodes in the vertical column direction are simply laminated together one on top of the other, has been commercially implemented, facilitating the construction of a higher-resolution display. The driving section comprises, as described above, three driving circuits, i.e., the address driving circuit 102 for selecting a display cell in the column direction according to the video data, the Y driving circuit 103 for selectively scanning each line, and the X driving circuit 106 for applying main display sustain pulses simultaneously to all the lines, and the control circuit 105 for controlling these driving circuits.
Here, the drive terminals of all the electrodes, except the dummy electrodes at the panel edge, are DC isolated from circuit ground, and capacitive impedance is dominant as the load for each driving circuit.
In a prior art technique for achieving power reduction in a pulsed capacitive-load driving circuit, it is known to provide a power recovery circuit that utilizes a phenomenon of resonance for energy transfer between load capacitance and inductance. One specific example of the power recovery technique suitable for a driving circuit where the load capacitance varies greatly for driving each individual load electrode by a mutually independent voltage in accordance with display image, as in an address electrode driving circuit, is the low power driving circuit disclosed in Japanese Unexamined Patent Publication (Kokai) No. 05-249916.
In the prior art capacitive-load driving circuit shown in
In the prior art capacitive-load driving circuit where the supply voltage to the address drive IC is set to a constant level, power equal to the amount of change in the stored energy in the load capacitor CL before and after switching a discharge cell is all consumed in the resistive impedance section of the charge/discharge current path; when the power recovery circuit 110 is used, the amount of potential energy stored in the load capacitor, relative to the intermediate potential of the address driving voltage that serves as the resonance center of the output voltage, is maintained through the resonance inductance within the recovery circuit. Then, while the supply voltage is held at ground, the switching state of the output circuit 122 is changed, and after that, the supply voltage to the address drive IC is again raised to the normal constant driving voltage through the resonance, thereby achieving savings in power consumption.
The prior art capacitive-load driving circuit shown in
If the power consumption of the driving circuit cannot be reduced sufficiently, the cost involved in removing heat from various parts of the display, and hence the component cost, increases, and besides, this could lead to a situation where the display brightness is reduced due to the limit of the heat dissipation capability of the display apparatus itself, or where the advantage of the flat panel display, i.e., thin and light-weight construction, cannot be exploited to the full.
Furthermore, as the output frequency of the driving circuit increases, power consumption increases due to the generation of high-voltage pulses to drive the plasma display panel, and temperature rise in the driving circuit (drive IC) becomes a serious concern.
Next, before describing the embodiments of the capacitive-load driving circuit and plasma display apparatus according to the present invention, the principle of the present invention will be described below.
As shown in
In this way, according to the present invention, the power consumed in the address drive IC (capacitive-load driving circuit) can be reduced. That is, though the power consumption as a whole remains the same, a portion of the power that would have been consumed in the address drive IC 3 in the prior art is consumed by the power distributing means 2; this construction serves to simplify the heat sinking structure of the address drive IC 3, and achieves a reduction in circuit cost.
A flat panel display apparatus, in particular, a plasma display apparatus whose trend is toward a larger-screen and higher-resolution display and whose drive voltage is high, requires the use of many large load capacitors and many display panel driving circuits operating at high driving speed; therefore, when the capacitive-load driving circuit of the present invention is applied to such display apparatus, not only can the cost involved in removing heat be reduced significantly, but high-voltage LSIs can be mounted in a very limited space.
The use of the capacitive-load driving circuit of the present invention offers an enormous advantage for a plasma display apparatus in which many capacitive loads (discharge cells, etc.) are driven using high-voltage pulses, but the invention is not specifically limited to the plasma display apparatus, but can be applied extensively to circuits for driving various types of capacitive loads.
The preferred embodiments of the capacitive-load driving circuit and plasma display apparatus according to the present invention will be described in detail below with reference to the accompanying drawings.
As shown in
The reason that the impedance of the resistive element (power distributing means) 21 is chosen to be higher than about one-tenth of the resistive impedance that the driving device 6 provides at the time of conduction is that with a lower impedance, the power distributed to the resistive element 21 would be so small that an effective power distribution effect would not be obtained. On the other hand, if the impedance of the resistive element 21 were made too high, the power distribution effect would increase but the driving waveform would deteriorate; therefore, an appropriate upper limit value should be determined according to each individual system (display apparatus, etc.) to which the driving circuit is applied. Accordingly, for the resistive element 21, it is preferable to use a high-power resistor that is inexpensive and reliable, and that has as high a resistance value as possible so that its power consumption can be made larger than the power consumption of the driving device.
As shown in
As shown in
Here, in an application, for example, where power is supplied to a plurality of driving circuits 3 (driving devices 6) via a plurality of constant-current sources 22 by using one driving power supply source 1 shown in
As shown in
The driving power supply source 1 outputs a high-level supply voltage V2 when the switch 12 is on, an intermediate voltage V1 when the switch 13 is on, and a ground potential V0 when the switch 14 is on. As shown in
In the fourth embodiment, the switches 12, 13, and 14 in the driving power supply source 1 of
In this way, in the fourth embodiment, nMOS transistors (active devices) are used as the switches (voltage switching means) in the driving power supply source circuit 1, and the control terminals (gates) of the active devices are constant-voltage or constant-current controlled, thereby regulating the output of each active device at a constant current level. In this way, the power consumption of the entire driving circuit system including the driving circuit 3 can be reduced sufficiently, and at the same time, the number of devices used can also be reduced.
As shown in
When driving the voltage of the load capacitor 5 to the potential of the reference potential point (for example, ground point) 4, if the power distributing means 23 is inserted in series to the driving device 7 connected between the load capacitor 5 and the reference potential point 4 as illustrated here, the power consumption of the driving device 7 can be reduced by distributing a portion of the power to the power distributing means 23. That is, by distributing a portion of the power consumed in the address drive IC (capacitive-load driving circuit) 3 to the power distributing means 23 for consumption therein, the heat sinking structure of the driving circuit 3 can be simplified and the circuit cost reduced.
In the sixth embodiment, the power distributing means 23 in the fifth embodiment is constructed as a resistive element (resistive impedance) 24, as in the previously described first embodiment. Here, the impedance of the resistive element 24 is chosen to be higher than about one-tenth of the resistive impedance that the driving device 7 provides at the time of conduction; as a result, about one-tenth or more of the power consumption in the driving device 7 during load driving is distributed to the resistive element 24, thereby reducing the power consumption of the driving circuit 3.
In the seventh embodiment, the power distributing means 23 in the fifth embodiment is constructed as a constant-current source 25, as in the previously described second embodiment. By constructing the power distributing means from the constant-current source 25 as illustrated here, the effective value of the current flowing in the driving device 7 can be made the smallest under the same driving conditions; as a result, theoretically, the seventh embodiment can achieve lower power consumption than any other driving method that uses a driving device.
In the eighth embodiment, a first power distributing means 26 is provided between the driving power supply source 1 and the high-level voltage supply terminal 8 of the driving circuit 3, and a second power distributing means 27 is provided between the reference potential point and the low-level voltage supply terminal 9 of the driving circuit 3; further, diodes 60 and 70 are inserted between the driving device 6 and a driving terminal 10 and between the driving terminal 10 and the driving device 7, respectively.
In an application where a plurality of load capacitors CL (5) are driven using the driving circuit 3 (when constructed in integrated circuit form), the power consumption of the driving circuit 3 can be reduced sufficiently by inserting the diode 60 or 70 in series with at least either one of the driving devices 6 and 7. That is, by eliminating unnecessary output voltage variations using the series-connected diode 60 or 70, it becomes possible to suppress an excess drive current flowing into the load capacitor due to the interference occurring between the outputs via a common power supply line or a reference potential line connected to the ground, and thus the power consumption of the driving circuit 3 can be reduced. Furthermore, since unnecessary drive voltage can be prevented from being applied to the driving devices in the plasma display apparatus, not only does the display quality improve, but the drive voltage can also be reduced while reducing the drive voltage margin.
In an application where a plurality of load capacitors are driven using the driving circuit 3, when the power distributing means 26 and 27 are each constructed using a resistive impedance (resistive element), each resistive element should be chosen to have a resistive impedance higher than about one-tenth of the conducting resistive impedance of the driving device 6 or 7 divided by the number of output terminals (for example, address lines A1 to Ad: d=N); by so doing, the power consumption of the driving circuit 3 can be reduced by distributing about one-tenth or more of the power consumed in the driving devices 6 and 7 during load driving to the respective resistive elements.
Here, when the configuration of the driving circuit 3 is applied to the address driving circuit (102 in
As shown in
When the driving circuit 3 is constructed using the totem-pole configuration as described above, the driving circuit (IC) can be constructed at low cost since the chip area can be reduced by using only nMOS transistors having a higher current-handling capability than pMOS transistors.
As shown in
By constructing the driving circuit 3 using the CMOS configuration as described above, the drive power for the pullup-side driving devices can also be reduced, and the rise and fall times of the drive voltage can be reduced while retaining good symmetry between them.
The 11th embodiment, as in the eighth embodiment, drives a plurality of load capacitors 5 from one driving circuit (drive IC). The driving circuit is constructed at low cost using conventional driver ICs; a driver module 36 (driving circuit 3) specifically designed to drive multi-terminal capacitive loads, such as those in a plasma display panel, comprises three integrated circuits (driver ICs) 37, 38, and 39. The integrated circuits 37, 38, and 39 are identical in configuration; the totem-pole configuration such as shown in
In this way, in the 11th embodiment, by connecting the power supply terminal 8 of the driver module 36 to the driving power supply source 1 via the power distributing means 26, the power consumption of the driving devices 6-1 to 6-d, etc. within the module is distributed to the power distributing means 26 outside the module and, by connecting the power supply terminal 9 of the driver module 36 to the ground potential point 4 via the power distributing means 27, the power consumption of the driving devices 7-1 to 7-d, etc. within the module is distributed to the power distributing means 27 outside the module. With this configuration, a temperature rise in the driver module 36 is reduced and the reliability increased, making it possible to reduce the cost involved in removing the generated heat and thus reduce the cost of the driver module (capacitive-load driving circuit).
The reason that the power supply terminals 84, 85, and 86 of the integrated circuits 36, 37, and 38 are connected to the output of the driving power supply source 1 and the power supply terminals 94, 95, and 96 to the ground potential point 4 is to control the high-voltage output devices 6-1 to 6-d at high speed in the respective integrated circuits 36, 37, and 38, and to ensure stable application of signal voltages to many logic signal input terminals with respect to ground by connecting the ground terminals for the low-voltage circuits, such as logic circuits, in the respective integrated circuits 36, 37, and 38 directly to the reference potential point (ground terminal) 4.
As shown in
As earlier described, the integrated circuit 37 can be constructed as a totem-pole circuit, but in the 12th embodiment, the input withstand voltage is increased up to the voltage value of the driving power supply source, for example, by increasing the gate film thicknesses of the output devices 620 and 720 forming the CMOS output circuit. These high-voltage (high voltage withstanding) output devices 620 and 720, whose control inputs (gates) are controlled by their preceding flip-flop circuits constructed from transistors 612 to 624 and 721 to 724, respectively, are driven to a full-swing level either at the drive supply voltage or at the reference voltage (ground potential). With this configuration, the high-voltage output devices 620 and 720 can be controlled in a stable manner even when the potentials at the high-level voltage supply terminal 81 and the high-voltage device reference potential terminal (ground terminal) 91 are varied greatly in order to enhance the power consumption distributing effect of the power distributing means 26 and 27.
Devices having a high input withstand voltage are used as the transistors 620, 621, 622, 721, and 722 in
In the integrated circuit 37 of the 13th embodiment, inexpensive devices (transistors) with a low input withstand voltage, and that can be controlled sufficiently by a logic power supply 75, are used as the high-voltage output devices 71-1 to 71-d. More specifically, the integrated circuit 37 has a ground terminal 94 and a logic power supply terminal 97 for receiving the output of the logic power supply 75, and self-biasing is applied to the nMOS transistors 71-1 to 71-d by the logic voltage outputs of the buffers 72-1 to 72-d and the voltage drop occurring across the power distributing means 27. The transistors 61-1 to 61-d are not limited to nMOS transistors, but it will be appreciated that they may be constructed from pMOS transistors or bipolar transistors.
Compared with the integrated circuit 37 of the 11th embodiment shown in
As described above, according to the embodiments of the present invention, there is achieved a capacitive-load driving circuit, in particular, a driving circuit for a plasma display apparatus, in which the power consumption of the driving circuit itself is reduced by distributing the power consumption associated with the capacitive component of the load to the power distributing means. The invention can thus alleviate the temperature-rise problem occurring, for example, in a 40-inch or larger plasma display apparatus having large load capacitance, a high-resolution plasma display apparatus having a high drive pulse rate, such as SVGA (800×600 dots), XGA (1024×768 dots), or even SXGA (1280×1024), or a high-brightness high-grayscale plasma display apparatus for TV or HDTV, and can promote a compact and low-power design for such display apparatuses. This also serves to suppress the increase in power consumption that occurs when the drive pulse rate is increased to cope with false contours in moving images.
The plasma display panel 201 comprises two glass substrates, the back glass substrate 210 and the front glass substrate 220, and on the front glass substrate 220 are formed the X electrodes (X1, X2, . . . , XL) and Y electrodes (scanning electrodes Y1, Y2, . . . , YL) composed of transparent electrodes and bus electrodes as sustain electrodes.
On the back glass substrate 210 are formed the address electrodes (A1, A2, . . . , Ad) in such a manner as to intersect at right angles to the sustain electrodes (X electrodes and Y electrodes) 222, and each display cell 207, which produces light by an electrical discharge between electrodes, is formed in a region flanked by the sustain electrodes with the same number (Y1 and X1, Y2 and X2, etc.) and located where the sustain electrodes intersect the address electrode.
As shown in
The X common driver 206 generates a sustain voltage pulse, the Y common driver 204 also generates a sustain voltage pulse, and the scan driver 203 drives the scanning electrodes (Y1 to YL) independently of each other by scanning from one electrode to the next. The address driver 202 applies an address voltage pulse to each address electrode (A1 to Ad) in accordance with display data.
The control circuit 205 contains a display data controller 251 which receives a clock CLK and display data DATA and supplies an address control signal to the address driver 202, a scan driver controller 253 which receives a vertical synchronization signal Vsync and horizontal synchronization signal Hsync and controls the scan driver, and a common driver controller 254 which controls the common drivers (X common driver 206 and Y common driver 204). The display data controller 251 includes a frame memory 252.
In
First, in the address period, an intermediate voltage −Vmy is applied simultaneously to all the Y electrodes (Y1 to YL), i.e., the scanning electrodes, and then, a scanning voltage pulse of −Vy level is applied in sequence from one electrode to the next. When the scanning pulse is being applied to each Y electrode, an address pulse of +Va level is applied to selected address electrodes (A1 to Ad) thereby selecting pixels on that scanning line.
In the succeeding sustain period, a common sustain voltage pulse of +Vs level is applied to all the scanning electrodes (Y1 to YL) and X-electrodes (X1 to XL) in alternating fashion, to sustain the glowing state of the selected pixels, and a display with predetermined brightness is produced by repeating this pulse application. Furthermore, grayscale representing the lightness and darkness of the image can be reproduced by controlling the number of emissions by combining the above series of basic drive waveform application operations.
The full-screen write period is initiated at predetermined intervals of time to apply a write voltage pulse to all the display cells of the panel in order to activate the display cells and maintain the display characteristic uniform. The full-screen erase period is a period for applying an erasure voltage pulse to all the display cells of the panel and thereby erasing the previous display content before initiating a new cycle of the address and sustain operations to produce an image display.
For example, when the number of address electrodes (A1 to Ad) on the display panel is 2560, a total of 40 drive ICs are used, since usually, 64-bit output drive ICs are connected to the address electrodes. Generally, these 40 drive ICs are packaged in modules each containing a plurality of drive ICs.
The control signals consist of a clock signal CLOCK and data signals DATA1 to DATA4 are sent to the shift register 231, a latch signal LATCH to the latch circuit 232, and a strobe signal STB for controlling the gate circuits. In
An example of a mounting method for the above drive IC chip will be described below.
For example, the drive IC chip is mounted on a rigid printed-circuit board, and the power supply, signal, and output pad terminals on the drive IC chip are connected by wire bonding to the corresponding terminals on the printed-circuit board.
Output wiring lines from the IC chip are brought out to the edges of the printed-circuit board, and output terminals are formed, which are then connected by thermo-compression to a flexible board having similar terminals, thus forming one module. Terminals for connecting to the panel display electrodes are formed at the front edge of the flexible board, and these terminals are connected to the panel display electrodes by means such as thermo-compression.
The drive terminals of all the electrodes, except the dummy loads at the panel edge, are DC isolated from circuit ground, and capacitive impedance is dominant as the load for the driving circuit. As a technique for achieving power reduction in a pulsed capacitive-load driving circuit, it is known to provide a power recovery circuit that utilizes a phenomenon of resonance for energy transfer between load capacitance and inductance. One example of the power recovery technique suitable for a driving circuit where the load capacitance varies greatly for driving each individual load electrode by a mutually independent voltage in accordance with display image, as in an address electrode driving circuit, is the low power driving circuit disclosed in Japanese Unexamined Patent Publication No. 5-249916 and described earlier with reference to
As shown in
For the driving electrodes of the plasma display panel (PDP), the parasitic capacitance and parasitic resistance forming the load are not concentrated, but are distributed, and the current that flows when driving the load capacitor 5 of capacitance value CL in the voltage increasing direction flows from the driving power supply source 1 through the driving device 6 in the driving circuit 3 into the distributed resistor 51 exhibiting a resistance value of Ra. On the other hand, the current that flows when driving the load capacitor 5 in the voltage falling direction flows via the driving device 7 into the reference potential point 4. That is, in either case, the drive current always passes through the distributed resistor 51 and flows via the conducting impedance of the driving device 6 or 7. In the capacitive-load driving circuit of the 15th embodiment, the electrode resistance value Ra of the distributed resistor 51 is chosen to be large enough that its resistance value cannot be ignored, that is, effectively higher than one-tenth of the resistive component of the conducting impedance of at least one of the driving devices 6 and 7. If it is assumed that the resistance value between the ends of the distributed resistor 51 is RL, and that the current leaks evenly into the parasitic capacitance from the output terminal 10 side of the driving circuit 3 and becomes zero at the end of the electrode, then the effective electrode resistance value Ra is one-third of the end-to-end resistance value RL.
The current that flows when driving the load capacitor 5 in the voltage rising direction flows from the driving power supply source 1, where the load is distributed, to the load capacitor 5 via the driving device 6 and distributed resistor 51. At this time, the power consumption is distributed in accordance with the ratio between the effective electrode resistance value Ra and the resistive impedance of the driving device 6. Likewise, when driving the load capacitor 5 in the voltage falling direction, the power consumption is distributed in accordance with the ratio between the effective electrode resistance value Ra and the resistive impedance of the driving device 7. Here, if it is possible to insert a resistive member in series in the path of the drive current flowing to the capacitor part (5), the resistive member can, of course, be inserted between the capacitor part and the output terminal 10 of the driving circuit 3 or be connected to the output terminal 10 of the driving circuit via the capacitor part.
Unlike the case that employs the prior known power recovery method utilizing a phenomenon of resonance, the power reducing effect in the above driving circuit 3 does not degrade even if the load capacitor 5 or the driving speed is increased. Thus, the capacitive-load driving circuit of the 15th embodiment can reduce the power consumed in the driving circuit (drive IC) 3, making it possible to simplify the heat sinking structure of the driving circuit 3 and reduce the cost of the circuit.
A flat panel display apparatus and, in particular, a plasma display apparatus whose trend is toward a larger-screen and higher-resolution display and whose drive voltage is high, requires the use of many load capacitors and many display panel driving circuits operating at high driving speed; therefore, when the 15th embodiment is applied to such display apparatus, the cost of the driving circuits and their heat removal mechanism can be drastically reduced. More specifically, in a plasma display apparatus, since high-voltage LSIs have to be mounted in a very limited space, the proportion of the cost of the driving circuits and their heat removal mechanism to the total cost of the display apparatus is relatively high; therefore, if the power consumption (heat generation) in each driving circuit is distributed by applying the present embodiment, the cost of the driving circuit and its heat removal mechanism can be drastically reduced. The power reducing effect in the driving circuit can also be achieved when the driving circuit 3 is implemented as an integrated circuit for driving a plurality of load capacitors.
As is apparent from a comparison between
As shown in
Distributed resistors 51, 51, . . . , 51, each similar to the one described with reference to
When the electrode is formed from a single material as shown in
When the electrode is formed from a composite material as shown in
The power distributing means 2, etc. shown here can be implemented in various configurations as explained, for example, with reference to
As described in detail above, the present invention achieves a capacitive-load driving circuit capable of distributing temperature rise (power consumption) in a circuit that drives a capacitive load, and a plasma display apparatus using such a driving circuit.
Many different embodiments of the present invention may be constructed without departing from the spirit and scope of the present invention, and it should be understood that the present invention is not limited to the specific embodiments described in this specification, except as defined in the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2000-301015 | Sep 2000 | JP | national |
2000-393510 | Dec 2000 | JP | national |
This application is a Continuation Application of pending application Ser. No. 13/325,983, filed on Dec. 14, 2011, which is a Divisional of application Ser. No. 11/139,574, filed on May 31, 2005, which is a Divisional of application Ser. No. 09/933,166, filed Aug. 21, 2001, now patented as U.S. Pat. No. 7,078,865, and claims the benefit of Japanese Application Nos. 2000-393510, filed Dec. 25, 2000 and 2000-301015, filed Sep. 29, 2000 in the Japanese Patent Office, the disclosures of which are incorporated by reference.
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Number | Date | Country | |
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20150084844 A1 | Mar 2015 | US |
Number | Date | Country | |
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Parent | 11139574 | May 2005 | US |
Child | 13325983 | US | |
Parent | 09933166 | Aug 2001 | US |
Child | 11139574 | US |
Number | Date | Country | |
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Parent | 13325983 | Dec 2011 | US |
Child | 14557883 | US |