Abstract:
As is obvious from the description in the specification and the attached drawings, the present invention provides a display apparatus for displaying an image on a display panel by turning on pixels of said display panel, said display apparatus comprising: a display panel provided with: address electrodes driven by address pulses based on a video input signal; and sustain electrodes crossing said address electrodes and sandwiching electrical discharging units of pixels with said address electrodes and driven by sustain pulses; a sustain-electrode drive circuit for generating said sustain pulses and scan pulses, provided with a common circuit for generating said sustain pulses or said scan pulses in response to an operating state thereof and for supplying said scan pulses and said sustain pulses to said sustain electrodes.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to a display apparatus such as a plasma display apparatus. More particularly, the present invention relates to a configuration of a circuit for driving a display unit. 
     A variety of conventional display apparatuses are known. One of them is a plasma display apparatus. A plasma display apparatus reproduces an image by driving a fluorescent material to emit light in an electrical discharge phenomenon. In a plasma display apparatus, a large screen can be implemented in a small space. Thus, the plasma display apparatus is a future display apparatus which draws attention. 
     FIG. 2 is a block diagram showing a typical configuration of the conventional plasma display apparatus. In the figure, reference numerals  3  and  8  denote a plasma display panel and a first-electrode drive circuit respectively. Reference numeral  27  denotes a drive circuit whereas reference numerals  25  and  26  each denote a power MOST. A symbol X denotes a first electrode or an X electrode common to the power MOSFETs  25  and  26 . A sustain power supply is connected to a terminal  7 . Reference numeral  10  denotes an address drive circuit. Symbols A 1  to AN each denote an address electrode. Reference numerals  82  and  33  denote a second-electrode sustain circuit and a drive circuit respectively. Reference numerals  31  and  32  each denote a power MOST whereas symbols Y 1  to Yn each denote a second electrode. A sustain power supply of the second electrodes Y 1  to Yn is connected to a terminal  29 . Reference numeral  34  denotes a scan drive circuit which comprises first to nth sustain drive circuits  34   a  to  34   n . The outputs of the first to nth sustain drive circuits  34   a  to  34   n  are connected to the second electrodes Y 1  to Yn. The scan drive circuit  34  comprises a shift register  36 , logic circuits  35  and  37 , constant-current power supplies  39  and  47 , power MOSFETs  38 ,  40 ,  42 ,  43 ,  46 ,  48 ,  50  and  51 , resistors  41  and  49  as well as diodes  44 ,  45 ,  52 ,  53  and  80 . A scan power supply is connected to a terminal  28 , furnishing power to the scan drive circuit  34  by way of a diode  80 . Reference numeral  11  denotes a waveform control circuit for outputting control signals Dxs, Dad and Dys to a first-electrode drive circuit  8 , an address drive circuit  10  and a second-electrode sustain circuit  82  respectively. The waveform control circuit  11  also supplies a control signal Dscn to the scan drive circuit  34  by way of an insulation circuit  30 . A second drive circuit  81  comprises the second-electrode sustain circuit  82  and the scan drive circuit  34 . 
     In the plasma display apparatus shown in FIG. 2, the scan signal Dscn output by the waveform control circuit  11  is supplied to the shift register  36  employed in the scan drive circuit  34   n  by way of the photo-coupler insulation circuit  30 . The shift register  36  sequentially distributes the scan signal Dscn to the scan drive circuits  34   a  to  34   n . In the scan drive circuit  34 , scan pulses bases on the scan signal Dscn are sequentially supplied to the second electrodes Y 1  to Yn of the plasma display panel  3 . 
     The second-electrode sustain circuit  82  generates sustain pulses YS based on the sustain pulses Dys output by the waveform control circuit  11 . The sustain pulses YS are supplied to the second electrodes Y 1  to Yn of the plasma display panel  3 . The sustain pulses YS generated by the second-electrode sustain circuit  82  are also supplied to the second electrodes Y 1  to Yn by way of a common terminal  83  of the scan drive circuit  34 , the diode  45  and the diode  53 . 
     The address signal Dad generated by the waveform control circuit  11  is supplied to an address drive circuit  10 . The address drive circuit  10  outputs address drive pulses based on the address signal Dad to the address electrodes A 1  to An of the plasma display panel  3 . 
     The first-electrode drive signal DXS generated by the waveform control circuit  11  is supplied to a first-electrode drive circuit  8 . The first-electrode drive circuit  8  outputs drive pulses based on the first-electrode drive signal DXS to the first electrode X of the plasma display panel  3 . The scan drive circuit  34  is available in the market as a scan drive IC. 
     A conventional implementation of the plasma display apparatus shown in FIG. 2 is disclosed in U.S. Pat. No. 5,745,086. FIG. 10 of this US patent is a block diagram showing a basic circuit for driving the plasma display apparatus. 
     In the plasma display apparatus shown in FIG. 2, the scan drive circuit  34  composing the second-electrode drive circuit and the second-electrode sustain circuit  82  employ circuits independent of each other. For example, the second-electrode drive circuit  34  has a configuration employing a scan drive IC having a circuit configuration shown in FIG. 2 while the second-electrode sustain circuit  82  has a configuration employing a power module. In addition, since the terminal  83  of the second-electrode sustain circuit  82  is floating off the ground, it is necessary to put the scan signal Dscn in a floating state through the insulation circuit  30 . 
     Moreover, the circuit scale of the second-electrode drive circuit  34  is larger than the first-electrode drive circuit  8 , resulting a big ratio of the second-electrode drive circuit  34  to the entire circuit of the plasma display apparatus. Accordingly, the second-electrode drive circuit  34  is a problem encountered in an effort made to reduce the size of the plasma display apparatus. 
     SUMMARY OF THE INVENTION 
     It is thus an object of the present invention addressing the problems described above to provide a display apparatus having a simple and compact configuration capable of avoiding malfunctions. 
     In order to achieve the object described above, the present invention provides the following: 
     1) A display apparatus for displaying an image on a display panel by turning on pixels of said is play panel, the display apparatus comprising: said display panel provided with: address electrodes driven by address pulses based on a video input signal; and sustain electrodes crossing said address electrodes and sandwiching electrical discharging units of pixels with said address electrodes and driven by sustain pulses; a sustain-electrode drive circuit for generating said sustain pulses and scan pulses, provided with a common circuit for generating said sustain pulses or said scan pulses in response to an operating state thereof and for supplying said scan pulses and sustain pulses to said sustain electrodes; an address drive circuit for generating and outputting said address pulses; and a control-signal generation circuit for generating a control signal for changing said operating state of said sustain-electrode drive circuit, wherein, in order to display an image on said display panel, an address of a pixel on said display panel is specified by an electric field created between said sustain electrodes and said address electrodes by said scan pulses and said address pulses; a pixel on said display panel at an address specified by an electric field of said sustain electrodes created by said sustain pulses is turned on; and said sustain-electrode drive circuit is used for both specifying said address and turning on said pixel. 
     2) A display apparatus for displaying an image on a display panel by turning on pixels of said display panel, the display apparatus comprising: said display panel provided with address electrodes and, first and second electrodes parallel to each other crossing said address electrodes and sandwiching electrical discharging units of pixels with said address electrodes; a first-electrode drive circuit for generating first-electrode sustain pulses for driving said first electrodes; a second-electrode drive circuit for generating scan pulses and second-electrode sustain pulses for driving said second electrodes, provided with a common circuit for generating said second-electrode sustain pulses or said scan pulses in response to an operating state thereof and for supplying said scan pulses and said second-electrode sustain pulses to said second electrodes; an address drive circuit for generating and outputting address pulses based on a video signal and for driving said address electrodes; and a control-signal generation circuit for generating a control signal for changing said operating state of said second-electrode drive circuit, wherein, in order to display an image on said display panel, an address of a pixel on said display panel is specified by an electric field created between said second electrodes and said address electrodes by said scan pulses and said address pulses; a pixel on said display panel at an address specified by an electric field between said first electrodes and said electrodes created by said first-electrode sustain pulses and said second-electrode sustain pulses is turned on; and said second-electrode drive circuit is used for both specifying said address and for turning on said pixel. 
     3) A display apparatus for displaying an image on a display panel by turning on pixels of said display panel, the display apparatus comprising: said display panel provided with address electrodes and, first and second electrodes parallel to each other crossing said address electrodes and sandwiching electrical discharging units of pixels with said address electrodes; a first-electrode drive circuit for generating first-electrode sustain pulses for driving said first electrodes; a second-electrode drive circuit for generating scan pulses and second-electrode sustain pulses for driving said second electrodes, provided with a common circuit for generating said second-electrode sustain pulses or said scan pulses in response to an operating state thereof and for supplying said scan pulses and said second-electrode sustain pulses to said second electrodes; an address drive circuit for generating and outputting address pulses based on a video signal and for driving said address electrodes; a switch unit for selecting a scan power supply for generating said scan pulses or a sustain power supply for generating said second-electrode sustain pulses; and a control-signal generation circuit for generating a control signal for changing said operating state of said second-electrode drive circuit and controlling said switch device, wherein, in order to display an image on said display panel, an address of a pixel on said display panel is specified by an electric field created between said second electrodes and said address electrodes by said scan pulses and said address pulses; a pixel on said display panel at an address specified by an electric field between said first electrodes and said electrodes created by said first-electrode sustain pulses and said second-electrode sustain pulses is turned on; and said second-electrode drive circuit is used for both specifying said address and for turning on said pixel. 
     4) A display apparatus for displaying an image on a display panel by turning on pixels of said display panel, the display apparatus comprising: said display panel provided with address electrodes and, first and second electrodes parallel to each other crossing said address electrodes and sandwiching electrical discharging units of pixels with said address electrodes; a first-electrode drive circuit for generating first-electrode sustain pulses for driving said first electrodes; a second-electrode drive circuit for generating scan pulses and second-electrode sustain pulses for driving said second electrodes, provided with a common circuit for generating said second-electrode sustain pulses or said scan pulses in response to an operating state thereof and used for supplying said scan pulses and said second-electrode sustain pulses to said second electrodes; an address drive circuit for generating and outputting address pulses based on a video signal and for driving said address electrodes; a power collection circuit provided with a coil, a switch means and a capacitor and connected by a diode to outputs of said first-electrode drive circuit or said second-electrode drive circuit or both; and a control-signal generation circuit for generating a control signal for changing said operating state of said second-electrode drive circuit and an operating state of said switch device, wherein, in order to display an image on said display panel, an address of a pixel on said display panel is specified by an electric field created between said second electrodes and said address electrodes by said scan pulses and said address pulses; a pixel on said display panel at an address specified by an electric field between said first electrodes and said electrodes created by said first-electrode sustain pulses and said second-electrode sustain pulses is turned on; said second-electrode drive circuit is used for both specifying said address and for turning on said pixel; and on falling edges of said first-electrode sustain pulses or said second-electrode sustain pulses, said control-signal generation circuit puts said switch means employed in said power collection circuit in a conductive state, and resonance of said coil employed in said power collection circuit is used to establish a state to collect power from said first electrodes, said second electrodes or both in said capacitor employed in said power collection circuit. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram showing a first embodiment implementing a display apparatus provided by the present embodiment; 
     FIG. 2 is a block diagram showing a typical configuration of the conventional display apparatus; 
     FIG. 3 is a block diagram showing a second embodiment implementing a display apparatus provided by the present embodiment; 
     FIG. 4 is a block diagram showing a third embodiment implementing a display apparatus provided by the present embodiment; 
     FIG. 5 is a block diagram showing a fourth embodiment implementing a display apparatus provided by the present embodiment; 
     FIG. 6 is a block diagram showing a fifth embodiment implementing a display apparatus provided by the present embodiment; 
     FIG. 7 is a block diagram showing a sixth embodiment implementing a display apparatus provided by the present embodiment; and 
     FIG. 8 is a diagram showing the waveforms of voltages supplied to the display apparatus. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Next, preferred embodiments of the present invention each implementing a plasma display apparatus are explained. 
     It should be noted that, in the drawings, components having identical functions are denoted by the same reference numeral in order to avoid duplication of explanation. 
     FIG. 1 is a block diagram showing a first embodiment implementing a display apparatus provided by the present embodiment. In FIG. 1, reference numerals  1  and  2  denote a line drive power supply input terminal and a line drive circuit respectively. Reference numeral  3  denotes a plasma display panel and reference notations Y 1  to Yn each denote a second electrode. Reference notation X denotes a first electrode and reference numeral  7  denotes a sustain power supply of the first electrode X. Reference numeral  8  denotes a first-electrode drive circuit and reference notations A 1  to An each denote an address electrode. Reference numerals  10  and  11  denote an address drive circuit and a waveform control circuit respectively. Reference numerals  12  and  19  each denote a logic circuit whereas reference numerals  13 ,  20  and  27  each denote a drive circuit. Reference numerals  14 ,  15 ,  21  and  22  each denote a power MOST whereas reference numerals  16 ,  17 ,  23  and  24  each denote a diode. Reference numerals  18  and  80  denote a shift register and a second-electrode drive circuit respectively. 
     As shown in FIG. 1, the second-electrode drive circuit  80  is a line drive circuit  2  comprising a first line drive circuit  2   a  to an nth line drive circuit  2   n  for electrode lines. The first line drive circuit  2   a  comprises a logic circuit  12 , a drive circuit  13 , power MOSFETs  14  and  15  and diodes  16  and  17 . On the other hand, the nth line drive circuit  2   n  comprises a shift register  18 , a logic circuit  19 , a drive circuit  20 , power MOSFETs  21  and  22  and diodes  23  and  24 . The other line drive circuits have the same configurations. The shift register  18  of the nth line drive circuit  2   n  receives a scan signal Dscn from a waveform control circuit  11 . On the other hand, the logic circuit  19  of the nth line drive circuit  2   n  receives sustain pulses DYS from the waveform control circuit  11 . The power MOSFETs  14  and  21  employed in the line drive circuit  2  are each referred to as a first switch device. On the other hand, the power MOSFETs  15  and  22  employed in the line drive circuit  2  are each referred to as a second switch device. 
     When compared with the conventional plasma display apparatus shown in FIG. 2, the embodiment of the present invention shown in FIG. 1 is different from the conventional display apparatus in that the embodiment includes neither the second-electrode sustain circuit  82  nor the insulation circuit  30  and, in the embodiment, the line drive circuit  2  generates both scan pulses and sustain pulses for the second electrodes Y 1  to Yn. 
     The operation of the plasma display apparatus shown in FIG. 1 is explained as follows. 
     The scan signal Dscn output by the waveform control circuit  11  employed in the embodiment shown in FIG. 1 is supplied to the shift register  18  of the nth line drive circuit  2   n . The scan signal Dscn is converted by the shift register  18  from a serial signal into a parallel signal. The parallel signal is supplied sequentially to the logic circuits  12  and  19  and the drive circuits  13  and  20  employed in the first to nth line drive circuits  2   a  to  2   n . Then, the signal is amplified by the power MOSFETs  14  and  15  in the first line drive circuit  2   a  and the power MOSFETs  21  and  22  in the nth line drive circuit  2   n . The amplified signal is supplied to the second electrodes Y 1  to Yn as scan pulses. 
     Sustain pulses DYS generated by the waveform control circuit  11  of the display apparatus shown in FIG. 1 for the second electrodes Y 1  to Yn are supplied to the drive circuit  20  by way of the logic circuit  19  and supplied to the drive circuit  13  by way of the logic circuits  19  and  12  of the line drive circuit  2 . The sustain pulses DYS for the second electrodes Y 1  to Yn are then amplified by the power MOSFETs  21 ,  22 ,  14  and  15 . The amplified signal is supplied to the second electrodes Y 1  to Yn as sustain pulses of the second electrodes Y 1  to Yn. 
     The plasma display apparatus shown in FIG. 1 is characterized in that the scan pulses and the sustain pulses for the second electrodes Y 1  to Yn are generated by a common circuit. Thus, the line drive circuit  2  shown in FIG. 1 is provided with both functions of the second-electrode sustain circuit  82  and the scan drive circuit  34  which compose the conventional plasma display apparatus shown in FIG.  2 . As a result, the size of the plasma display apparatus shown in FIG. 1 is small in comparison with the conventional plasma display apparatus shown in FIG.  2 . 
     The configuration of the line drive circuit  2  shown in FIG. 1 is similar to the scan drive circuit  34  shown in FIG.  2 . In the line drive circuit  2 , however, the current capacities of the drive circuits  13  and  20  and the power MOSFETs  14 ,  15 ,  21  and  22  and the switching speeds of the power MOSFETs  14 ,  15 ,  21  and  22  are set at values to give a large amplitude of the scan pulse supplied to the second electrodes Y 1  to Yn and to supply sustain pulses resulting in a large discharge current to the second electrodes Y 1  to Yn. In addition, the plasma display circuit shown in FIG. 1 is different from the conventional plasma display circuit shown in FIG. 2 in that, in the case of the former, the drive circuits  13  and  20  and the power MOSFETs  14 ,  15 ,  21  and  22  are operated by using the sustain pulses DYS of the second electrodes Y 1  to Yn supplied to the logic circuit  19 . 
     Comparison of operating waveforms of the plasma display apparatus shown in FIG. 1 with operating waveforms of the conventional plasma display apparatus shown in FIG. 2 is shown in FIG.  8 . 
     FIG. 8 is diagrams showing the waveforms of voltages supplied to the plasma display apparatuses. To be more specific, FIG. 8A is a diagram showing the waveform of a voltage VX supplied to the first electrode X. FIG. 8B is a diagram showing the waveform of a voltage VY 1  supplied to the first second electrode Y 1 . FIG. 8C is a diagram showing the waveform of a voltage VYn supplied to the nth second electrode Yn. FIG. 8D is a diagram showing the waveform of a voltage VA 1  supplied to the first address electrode A 1 . FIG. 8E is a diagram showing the waveform of a voltage VA 2  supplied to the nth address electrode An. FIG. 8F is a diagram showing the waveform of a voltage DY 1  generated by the logic circuit  35  employed in the conventional plasma display apparatus shown in FIG.  2 . FIG. 8G is a diagram showing the waveform of a voltage DYn generated by the logic circuit  37  employed in the conventional plasma display apparatus shown in FIG.  2 . FIG. 8H is a diagram showing the waveform of sustain pulses YS of the second electrodes Y 1  to Yn. FIG. 8I is a diagram showing the waveform of a voltage DYS 1  output by a logic circuit  12  shown in FIG. 1; FIG. 8J is a diagram showing the waveform of a voltage DYS 2  generated by the logic circuit  19  of the plasma display apparatus of FIG. 1 provided by the present invention. 
     It should be noted that the rest of the waveforms shown in FIG. 8 is used for explaining other embodiments of the present invention. The other waveforms will be explained later. 
     The time axis of FIG. 8 is divided into a reset period, a scan period and a sustain period. The reset period is also referred to as a screen erase period and the scan period is also referred to as an address period. The sustain period is also referred to as an electrical-discharge sustain period. During the reset period, pulse voltages are applied to the first electrode X and the second electrodes Y 1  to Yn alternately as shown in FIGS. 8A to  8 C to cause an electrical discharge phenomenon over the entire screen. In the scan period following the reset period, a constant voltage is applied to the first electrode X as shown in FIG.  8 A. In addition, negative pulses are subsequently supplied to the second electrodes Y 1  to Yn as shown in FIGS. 8B and 8C. In addition, positive pulses (address pulses) are supplied subsequently to the address electrodes A 1  to An, except cells not to be turned on in the sustain period, in order to select cells to be turned on in the sustain period as shown in FIGS. 8D and 8E. During the sustain period, a sustain voltage for sustaining an electrical discharge phenomenon is applied to the first electrode X and the second electrodes Y 1  to Yn alternately as shown in FIGS. 8A to  8 C. 
     In the conventional plasma display apparatus shown in FIG. 2, the logic circuits  35  and  37  output respectively the scan signal DY 1  and DYn which are required during the scan period as shown in FIGS. 8F and 8G. As shown in FIG. 8H, the second-electrode sustain circuit  82  outputs the sustain pulses YS required during the sustain period. The sustain pulses YS are supplied to the second electrodes Y 1  to Yn by way of the diodes  45  and  53 . 
     In the case of this embodiment, on the other hand, the logic circuit  12  outputs a voltage DYS 1  required during the scan period and the sustain period as shown in FIG.  8 I. The voltage DYS 1  is supplied to the first second electrode Y 1 . By the same token, the logic circuit  19  outputs a voltage DYSn required during the scan period and the sustain period as shown in FIG.  8 J. The voltage DYSn is supplied to the nth second electrode Yn. 
     As described above, by generating the voltages DYS 1  and DYSn at the outputs of the logic circuits  12  and  19  respectively in this embodiment, the second-electrode sustain circuit  82  and the scan drive circuit  34  of the conventional plasma display apparatus can be implemented in one line drive circuit  2 . 
     FIG. 3 is a block diagram showing a second embodiment implementing a display apparatus provided by the present embodiment. 
     In the Figure, reference numerals  28  and  29  denote a scan power-supply input terminal and a second-electrode sustain power-supply input terminal respectively. Reference numeral  40  is a switch means which is controlled by the waveform control circuit  11 . The second embodiment is different from the first embodiment shown in FIG. 1 in that the former has the scan power-supply input terminal  28  and the second-electrode sustain power-supply input terminal  29  as well as the switch means  40 . In the second embodiment shown in FIG. 3, the voltage Vcc of the line drive power supply is generated by the scan power supply Vscn or the sustain power supply Vsy which is selected by the switch means  40 . 
     FIG. 8K is a diagram showing the waveform of the voltage Vcc of the line drive power supply. FIG. 8L is a diagram showing the waveform of the voltage Vscn of the scan power supply which is input from the terminal  28 . FIG. 8M is a diagram showing the waveform of the voltage Vsy of the second-electrode sustain power supply. The switch means  40  is actuated to set the voltage Vcc of the line drive power supply at the voltage Vscn during a scan period for generating scan pulses. During other periods, the switch means  40  is actuated to set the voltage Vcc of the line drive power supply at the voltage Vsy. Thus, in this embodiment, a reset voltage generated during a reset period is superposed on the voltage Vsy of the sustain power supply for the second electrodes Y 1  to Yn as shown in FIG.  8 M. The switch means  40  is controlled typically as follows. The switch means  40  is initially connected to the terminal  28  to select the voltage Vscn. Then, the switch means  40  is changed over to the terminal  29  on the rising edge of the first sustain voltage appearing during a sustain period to receive the voltage Vsy. The switch means  40  is changed over back to the terminal  28  on the rising edges of the voltage of the second electrodes Y 1  to Yn appearing during the sustain period. 
     According to the second embodiment of the present invention shown in FIG. 3, a voltage value of scan pulses supplied during a scan period can be set independently so that the amount of deterioration of a screen caused by an incorrect electrical discharge phenomenon can be reduced. 
     FIG. 4 is a block diagram showing a third embodiment implementing a display apparatus provided by the present embodiment. The third embodiment is different from the second embodiment shown in FIG. 3 in that, the former is provided with a first-electrode power collection circuit  42  and a second-electrode power collection circuit  41 . In FIG. 4, reference numerals  41  and  42  thus denote the second-electrode power collection circuit and the first-electrode power collection circuit respectively. Reference numerals  43 ,  44 ,  45 ,  46 ,  52  and  53  each denote a diode whereas reference numerals  47 ,  48 ,  54  and  55  each denote a coil. Reference numerals  49 ,  50 ,  56  and  57  each denote a switch means whereas reference numerals  51  and  58  each denote a capacitor. The second-electrode power collection circuit  41  comprises the coils  47  and  48 , the switch means  50  and  49  and the capacitor  51 . On the other hand, the first-electrode power collection circuit  42  comprises the coils  54  and  55 , the switch means  56  and  57 , the capacitor  58  and the diodes  53  and  52 . Since the second-electrode power collection circuit  41  is provided in this way, the line drive circuit  2  thus also includes the diodes  43 ,  44 ,  45  and  46 . 
     In the embodiment shown in FIG. 4, when first-electrode sustain pulses are applied to the first electrode X of the plasma display panel  3 , the first-electrode power collection circuit  42  operates to reduce power losses incurred by the power MOSFETs  25  and  26  employed in the first-electrode drive circuit. In the first-electrode power collection circuit  42 , the switch means  57  is put in a conductive state on the rising edge of a sustain pulse of the first electrode X. In this state, power is supplied from the capacitor  58  to the first electrode X by way of the coil  55  and the diode  52 . On the other hand, the switch means  56  is put in a conductive state on falling edge of a first sustain pulse. In this state, power or electric charge is returned to the capacitor  58  by way of the diode  53  and the coil  54  from the stray capacitance of the first electrode X which is not shown in the figure. By virtue of the operation of the first-electrode power collection circuit  42 , the magnitudes of the currents flowing through the power MOSFETs  25  and  26  can be decreased, allowing the power loss to be reduced. In the collection of power by the first-electrode power collection circuit  42 , resonance caused by a circuit including the coils  54  and  55  and the stray capacitance of the plasma display panel  3  is utilized to suppress the power loss. 
     When sustain pulses of the second electrodes Y 1  to Yn of the plasma display panel  3  are applied to the second electrodes Y 1  to Yn, the second-electrode power collection circuit  41  operates to reduce power losses incurred by the power MOSFETs  14 ,  15 ,  21  and  22  employed in the first-electrode power collection circuit  42 . The switch means  49  employed in the second-electrode power collection circuit  41  is put in a conductive state on the rising edges of sustain pulses supplied to the second electrodes Y 1  to Yn. In this state, currents are supplied from the capacitor  51  to the second electrodes Y 1  to Yn by way of the coil  48  and the diodes  44  and  46 . On the other hand, the switch means  50  employed in the second-electrode power collection circuit  41  is put in a conductive state on the falling edges of sustain pulses supplied to the second electrodes Y 1  to Yn. In this state, electric charge accumulated in the second electrodes Y 1  to Yn is returned by way of the diodes  43  and  45  and the coil  47  to the stray capacitance of the plasma display panel  3 . 
     By virtue of the operation of the second-electrode power collection circuit  41 , the magnitudes of the currents flowing the power MOSFETs  14 ,  15 ,  21  and  22  can be decreased, allowing the power loss to be reduced. In the collection of power by the second-electrode power collection circuit  41 , the power loss is suppressed by utilizing resonance caused by a circuit including the coils  47  and  48  and the stray capacitance of the plasma display panel  3  which is not shown in this figure. 
     FIG. 8N is a diagram showing the waveform of a switch-means driving voltage V 49  supplied by the waveform control circuit  11  to a switch means  49  and FIG. 8O is a diagram showing the waveform of a switch-means driving voltage V 50  supplied by the waveform control circuit  11  to a switch means  50 . 
     As shown in FIG. 8N, the switch-means driving voltage V 49  is a signal synchronized to the rising edges of sustain pulses supplied to the second electrodes Y 1  to Yn. The switch-means driving voltage V 49  turns on the switch means  49 . In addition, as shown in FIG. 8O, the switch-means driving voltage V 50  is a signal synchronized to the falling edges of sustain pulses supplied to the second electrodes Y 1  to Yn. The switch-means driving voltage V 50  turns on the switch means  50 . 
     By providing the diodes  45 ,  46 ,  43  and  44  for the second electrodes Y 1  to Yn on the line drive circuit  2  employed in the plasma display apparatus shown in FIG. 4, the second-electrode power collection circuit  41  can be applied, allowing the power loss incurred in the line drive circuit to be reduced. By employing high-speed devices with a turn-off time equal to or smaller than 500 ns as the power MOSFETs  14  and  21 , the power MOSFETs  14  and  21  can be turned off with a high degree of reliability even if the source voltages of the power MOSFETs  14  and  21  are forcibly decreased. By collection of power and by employing high-speed devices as the power MOSFETs  14  and  21 , it is possible to prevent the power MOSFETs  14  and  21  from being turned on even if voltages appearing at junction points of the diodes  45  and  46 , that is, the source voltages of the power MOSFETs  14  and  21 , are forcibly decreased. This is because no electric charge remains between the gate and the source of each of the power MOSFETs  14  and  21 . 
     FIG. 5 is a block diagram showing a fourth embodiment implementing a display apparatus provided by the present embodiment. 
     In the figure, reference numerals  60  and  61  each denote a switch means. The fifth embodiment is different from the fourth embodiment in that the former has switch means  64  and  65 . 
     In the conventional plasma display apparatus shown in FIG. 2, in order to turn off the power MOSFETs  42  and  50  employed in the scan drive circuit  34 , the power MOSFETs  40  and  48  at the preceding stage are turned off. At that time, electric charge accumulated between the gate and the source of each of the power MOSFETs  42  and  50  is electrically discharged through the resistors  41  and  49  respectively. With this circuit configuration adopted in the plasma display apparatus shown in FIG. 4, when the second-electrode power collection circuit  41  is operated to flow a current to the capacitor  51  by way of the diodes  45  and  43  from the stray capacitance of the plasma display panel  3  on the falling edges of the sustain pulses of the second electrodes Y 1  to Yn, the source voltages of the power MOSFETs  14  and  21  employed in the line drive circuit  2  are forcibly lowered. As a result, a difference in electric potential is developed between the source and the gate of each of the power MOSFETs  14  and  21 . It is thus quite within the bounds of possibility that the voltage between the source and the gate of each of the power MOSFETs  14  and  21  exceeds a threshold value, turning on the power MOSFETs  14  and  21 . 
     In the fourth embodiment shown in FIG. 5, in order to prevent the power MOSFETs  14  and  21  from being turned on forcibly, the switch means  60  and  61  are provided between the gates and the sources of the power MOSFETs  14  and  21 . By turning on the switch means  60  and  61  on the falling edges of the sustain pulses applied to the second electrodes Y 1  to Yn, a circuit between the source and the gate of each of the power MOSFETs  14  and  21  is short-circuited, allowing the power MOSFETs  14  and  21  to be turned off at a high speed. Thus, by virtue of the second-electrode power collection circuit  41 , it is possible to reliably prevent the power MOSFETs  14  and  21  from being turned on even if the source voltages of the power MOSFETs  14  and  21  are lowered forcibly. 
     FIG. 6 is a block diagram showing a fifth embodiment implementing a display apparatus provided by the present embodiment. 
     In the figure, reference numerals  62  and  63  each denote a P-channel power MOST whereas reference numerals  64  and  65  each denote a switch means. In the plasma display apparatus shown in FIG. 6, the P-channel power MOSFETs  64  and  65  are employed in place of the N-channel power MOSFETs  14  and  21  respectively while the switch means  60  and  61  are employed in place the switch means  64  and  65 . Even if this circuit configuration is adopted, the second-electrode power collection circuit  41  is operated to flow a current to a capacitor  51  by way of diodes  45  and  43  from the stray capacitance of the plasma display panel  3  on the falling edges of the sustain pulses of the second electrodes Y 1  to Yn. Thus, by turning on the switch means  64  and  65 , the P-channel power MOSFETs  62  and  63  can each be turned off at a high speed even if the P-channel power MOSFETs  62  and  63  have been forcibly turned on. In this way, it is possible to reliably prevent the power MOSFETs  62  and  63  from being turned on by virtue of the second-electrode power collection circuit  41  even if the drain voltages of the power MOSFETs  62  and  63  are forcibly lowered. Thus, even in the case of an application using the fifth embodiment shown in FIG. 6, the same effects as those of the fourth embodiment shown in FIG. 5 can be obtained. In this embodiment, other means are used in place of the switch means  60 ,  61 ,  64  and  65  employed in the fourth and fifth embodiments to give the same effects. An example of the other means is a means for electrically discharging electric charge accumulated between the gate and the source of a power MOST at a high speed. 
     FIG. 7 is a block diagram showing a sixth embodiment implementing a display apparatus provided by the present embodiment. 
     In the figure, reference numerals  73  and  76  each denote a P-channel power MOST whereas reference numerals  72  and  75  each denote an N-channel power MOST. Reference numerals  74  and  77  each denote a constant voltage power supply. The sixth embodiment shown in FIG. 7 has a grounded-gate circuit comprising the power MOST  72 , the constant-voltage power supply  74 , the power MOST  75  and the constant-voltage power supply  77 . In the plasma display apparatus shown in FIG. 7, the grounded-gate circuit is employed as the configuration of an output unit of the line drive circuit  2 . In this configuration, the power MOSFETs  72  and  75  are turned on when the power MOSFETs  73  and  76  are turned on respectively. On the falling edges of sustain pulses of the second electrodes Y 1  to Yn, a current flows from the stray capacitance of the plasma display panel  3  to the capacitor  51  by way of the diodes  45  and  43 . In addition, the power MOSFETs  74  and  77  are held at a high impedance even if the drain voltages of the power MOSFETs  73  and  76  are lowered forcibly. Thus, by virtue of the second-electrode power collection circuit  41 , the drain voltages of the power MOSFETs  73  and  76  are lowered forcibly and it is thus possible to reliably prevent the power MOSFETs  62  and  63  from being turned on. 
     In the embodiments described above, power MOSFETs are used in the line drive circuit  2 . It should be noted, however, that the power MOSFETs can each be replaced by another switch device such as an IGBT. 
     In addition, power collection circuits can be provided by connecting them to the address drive circuit  10 . 
     According to the present embodiment, the second-electrode drive circuit has 2 functions, namely, a function to generate scan pulses and a function to generate sustain pulses of the second electrodes Y 1  to Yn. By executing the 2 functions through the use of a common circuit in this way, the configuration of the second-electrode drive circuit can be made simple. 
     Furthermore, the present invention can also be implemented by another embodiment different from the embodiments described so far without departing from the true spirit and main characteristics of the present invention. That is, all the embodiments described above are no more than examples of the present invention and should not be interpreted as limitations on the present invention. The scope of the present invention is defined by claims appended to this specification. Moreover, modifications and changes pertaining to an average range of the range of each claim are considered to be included in the scope of the present invention.