DE4301437A1 - Controlling plasma discharge display panel - using pulse control signals generated by sequence circuits that are applied to hold cathode and anode electrodes - Google Patents

Abstract

The control method for a plasma discharge panel display involves using a sequence circuit to select scanning electrodes in the form of a cathode by applying signals to the bases of transistors. A synchronous sequential circuit transmits data signals to the anodes. The anode signals consist of a positive pulse, the cathode of negative amplitude pulses and the hold signal is in the form of repeated pulses. The display has an anode (11) on an upper glass panel (10) surface, a hold electrode (13) on the surface of a lower glass panel and a dielectric (14) located in between. A cathode (15) is enclosed within the dielectric. ADVANTAGE - Avoids coupling between write and discharge operations.

Description

The invention relates to a method for controlling a Plasma display screen (PDP) according to the preamble of the patent saying 1.

Among common plasma display devices, namely DC and AC types, is related to the life of the cathode materials of the AC type. In particular, in the case a color PDP, its short life problem cannot can be solved with currently used nickel thick films because the drive voltage is high and the discharge gas itself heavy compared to neon orange monochrome displays.

The present invention takes on the idea that a AC cathode (namely, a cathode, one with a dielectric and MgO layer coated electrode) DC PDP's is introduced. If still a change  current electrode is used, the discharge lasts for the Luminosity not due to the discharge principles of the switch type. Therefore, an alternating current becomes a permanent one Discharge controlled, the writing and erasing by DC control method is controlled.

The object of the invention is a method for driving to provide a PDP, which by time base separation of the up maintenance and scanning and removal of the coupling between writing and continuous discharge is operated safely.

This object is achieved by the features of the An spell 1 solved.

The invention provides a method for driving a PDP provided which a sequential circuit for selecting one Scanning cathode among a plurality of scanning cathodes, one synchronous sequence conversion circuit for transmitting a Data signal that is sent to one of a variety of anodes the time sequence circuit is associated with the selected anode, Switching transistors, each one with the respective off Control terminal connected to the time connection circuit have trode and ver the emitter with a bias voltage source are bound, and a maintenance pulse supply circuit that connects to the collector of each of the switching transistors connected, a maintenance electrode and a Wi the state between a general node of the lot number of cathodes and ground is switched, where a voltage higher than the discharge ignition voltage across the selected anodes and scanning cathodes is fed around initiate a discharge, with an alternating waveform with a predetermined period of the maintenance electrode is supplied before the discharge is extinguished and one before certain voltage led to the selected scanning cathode to maintain the discharge, and then a shame The pulse of the selected cathode is supplied around the discharge  delete.

Further features and advantages will become apparent from the following description of a preferred embodiment of the invention hand of the drawing explained.

Show it:

FIGS. 1A to 1F, the structure of a PDP, the driving with a Ansteuerver of the present invention will strike beauf invention;

Figure 2 shows a PDP having a structure in accordance with the present invention and a drive circuit for controlling the PDP.

Figure 3A shows the current-voltage characteristic for driving a PDP according to the invention.

Fig. 3B, the driving signal of a PDP from another execution form of the invention;

Fig. 3C, the drive signal of a PDP from a further guide of the invention;

FIG. 3D is the driving signal of a PDP according to a wide ren embodiment of the invention; and

FIGS. 4A to 4D are views for explaining the driving operation in accordance with the driving method of a PDP OF INVENTION dung the.

Figs. 1A to 1F show the structure of a PDP of the present invention is applied to a driving method.

Referring to FIG. 1A, an anode 11 is formed on an upper face glass 10; a maintenance electrode 13 is formed on the entire surface of a deeper rear glass 12 , and a dielectric 14 is disposed on the maintenance electrode 13 as a layer. Here, a cathode 15 is completely enclosed by the dielectric 14 . While according to FIG. 1B, the upper plate structure the same as that of FIG. 1A, the sustain electrodes of the lower panel assembly and are mutually arranged in parallel with the cathodes.

Referring to FIG. 1C, the upper plate structure the same as that of FIG. 1A, the maintaining electrodes, however, are disposed on the lower plate structure in the same direction as the anodes.

As shown in FIG. 1D, the anode 11 is formed on the upper end glass 10 , the anode 11 is coated with a dielectric 16 , the maintenance electrode 13 is formed on the entire surface of the rear glass 12 , and the dielectric 14 is on the maintenance electrode 13 applied as a layer. Here the cathode 15 is completely enclosed by the dielectric 14 .

As shown in FIG. 1E, the top plate structure of the moving surface such as that of FIG. 1D, the Aufrechterhaltungselek are trodes of the lower plate structure alternately and uniformly arranged with the cathodes.

1F, the lower plate structure is the same as that of FIG. 1D, but the lower plate structure is arranged so that two cathodes are placed in parallel between each maintenance electrode.

In the above structures, thin film material (e.g. ITO or Au) or a thick film material (e.g. Ni or Ag) on the Anode and formed in the same direction by this. If a Dielectric is applied to the anode or not, depends depending on the type of business. In the present invention, this is Failure to apply a dielectric beneficial for the Charge storage. In the case of color writing, red (R), Green (G) and blue (B) fluorescence on or around the  Writing electrode surface can be applied by such Gas mixtures such as He-Xe, He-Xe-Kr, Ne-Xe or Ne-Xe-Kr, the one have high ultraviolet emissivity.

An SiO ₂ (or Al ₂ O ₃ ) thin film layer (or dielectric thick film layer) is applied to the cathodes and maintenance electrodes of the lower and lower rear glass, respectively. An MgO layer is formed on the upper part to have a thickness measured in angstroms.

Separating ribs are strip-shaped along the anodes or lattice-shaped configuration. Is effective to form an MgO layer on the surface of the separating ribs when the second electron emission is with the separating ribs colliding ions is used. Similarly, the separators line ribs are formed on the top plate.

Fig. 2 shows a PDP which has the structure according to the inven tion and has a drive circuit for driving the PDP.

Fig. 2 shows a time sequence circuit 1 for selecting a cathode, e.g. B. a scanning electrode, a Zeitfolgesynchroni sationsumwandlungsschaltkreis 2 for transmitting a Dateni gnals to an anode, switching transistors 3 , which have bases which are connected to the respective output terminals of the sequential circuit 1 , the emitters are all connected to the bias voltage source and the collectors with the respective Katho are connected. A resistor 4 is connected between each cathode and ground and a maintenance plus supply circuit 5 is connected between ground and the maintenance electrodes, which are arranged between the cathodes.

According to the invention, Fig. 3A shows the current-voltage characteristic of a PDP.

As is apparent from Fig. 3A, a discharge ignition voltage + V _B or -V _B initiates a discharge process. In order to maintain the discharge after it has been initiated, the maintenance voltage + Vs maintains the discharge first, then the maintenance voltage -Vs maintains the discharge correctly. The voltages of the supplied waveforms or signals are set so that the discharge continues. At this point, the wall charge should be taken into account. This means that the combined voltage from the maintenance pulse voltage and the wall voltage is greater than or equal to the discharge discharge maintenance voltage. Here, the frequency is determined by the number of gray scale bits and the lifespan of a basic part. During writing, the supply waveforms or feed signals of the writing or scanning the electrodes are set so that the voltage supplied to the anode is greater than the discharge ignition voltage V _B , and during receiving and deleting the medium level of a conservation wave form is set to the same.

Fig. 3B shows the driving waveform of a PDP according to another embodiment of the invention. With regard to Fig. 3B, 3C and 3D should be assumed that all three waveforms are superposed actually above the other, even if they are shown here only senversatz to the representation will with a slight Amplitudenach.

In Fig. 3B, a pulse A represents the waveform supplied to the maintenance electrode, a pulse B represents the waveform supplied to the anode, and a pulse C represents the waveform supplied to the cathode. When the pulse A is continuously supplied to the maintenance electrode and the pulses B and C are respectively supplied in synchronism to the anode and cathode, a write operation is performed. Then pulse A maintains the discharge while the erasing is carried out by supplying a pulse which has a shorter duration than the pulse supplied during writing.

Fig. 3C shows the driving waveforms of a PDP according to still yet another embodiment of the invention.

According to Figure 3C. This waveform by reversely feeding the pulses which, like, produces the same amplitude in Fig. 3B have the anode and cathode during the writing of supplied feed-th pulses. That is, during writing, the discharge is initiated by supplying pulses which are higher than that of the discharge ignition potential to the anode and cathode.

Fig. 3D shows a method for driving a PDP according to another embodiment of the egg ner present invention.

In Fig. 3D, a pulse A represents the supply waveform or the feed signal of a sustaining electrode, a pulse B represents the supply waveform of a writing electrode, and a pulse C represents the waveform of a scanning electrode. Pulse A is continuously supplied to the maintenance electrode, and pulses B and C are supplied simultaneously to that writing electrode and the scanning electrode which are to be displayed. Then pulse A maintains a discharge. During writing, the discharge is initiated by the potential difference of the voltage supplied to the writing electrode and the scanning electrode.

FIGS. 4A to 4D are for explanation of the internal loading drive of a screen according to the invention, the driving method of a PDP.

Fig. 4A serves to explain the operation during the writing.

The write operation shown in FIG. 4A corresponds to a period I of the waveform shown in Fig. 3A to 3D. The discharge occurs when the voltage difference between a positive pulse supplied to the anode and a negative pulse supplied to the cathode becomes higher than the discharge ignition voltage difference. Then a positive charge is applied to the surface of the cathode and the cell voltage drops so that the discharge is stopped. A wall voltage is built up on the scanning electrode and the electrons that migrate to the writing electrode are not stored, but pass through an internal circuit.

Fig. 4B serves to explain the maintenance operation.

The maintenance operation in Fig. 4B corresponds to a period II of the waveform shown in Figs. 3A to 3B. Since the cathode becomes more positive in the course of the rise to the base potential (positive charge), a discharge occurs between the cathode and the maintenance electrode. At this time, the cathode functions as an anode and the maintenance electrode functions as a cathode. Accordingly, positive charges are stored in the sustaining electrode, negative charges are stored in the cathode, and this results in a wall voltage that is the reverse polarity to that of the external electric field.

Fig. 4C serves to explain another maintenance operation.

The maintenance operation according to FIG. 4C corresponds to a period II of the waveform shown in Fig. 3. Since the potential of the sustaining electrode becomes positive, the sustaining electrode functions as an anode, the cathode functions as a cathode, and a sustaining discharge occurs. Likewise, the formation of a wall voltage and charge storage occurs in the opposite manner, as described with respect to Fig. 4b.

The maintenance operation shown in FIGS. 4D and 4C is generated by supplying maintenance pulses having a discharge maintenance potential to the maintenance electrode before the wall charges generated by the write operation explained in connection with FIG. 4a are used up. The above explanation relates to an example, but such operation can be applied to other embodiments.

Fig. 4D is the explanation of the extinguishing operation.

The erase operation according to Fig. 4D corresponding to one period of the waveforms shown in Figs. 3B, 3C and 3D III. The discharge occurs in the scanning electrode for a short time corresponding to one tenth or one fifth of the write period. Since a certain amount of time is required to generate a wall charge, the time can be shortened sufficiently to not generate a wall charge.

Write, maintain and erase operations are performed using of the above procedure.

Therefore, the driving operation according to the present Erfin reduced costs and improved reliability as the Drive circuit due to the separation of the maintenance tion and the scanning operation is kept simple. The far Ren is easier to manufacture because only one maintain circuit is needed.

Claims (15)

1. A method for controlling a plasma display screen, wherein a matrix is formed by a write anode ( 11 ) in the column direction and a scanning cathode ( 15 ) in the row direction and a discharge maintenance electrode ( 13 ) is formed parallel to the columns of a display screen, characterized ,
that a data signal having a positive waveform is supplied to a writing electrode,
a scanning signal having a negative waveform is successively fed to a scanning cathode ( 15 ) with a scanning which is reciprocal of the number of scanning lines,
supplying an alternating waveform from a predetermined period to a selected discharge maintenance electrode ( 13 ),
a predetermined voltage is supplied to a cathode ( 15 ), and
the discharge is maintained by the wall charges on the discharge discharge maintenance electrode ( 13 ) and cathode ( 15 ). 2. A method for driving a plasma display panel according to claim 1, characterized in that the sustaining electrode (13) is formed on a bottom or lower plate, or when the discharge up sustaining electrode (13) is a plate, this to a an intermediate dielectric parallel ( 14 ) having a scanning electrode. 3. A method of driving a plasma display panel according to claim 1, characterized in that the scanning electrode and discharge maintenance electrode ( 13 ) have inverted positions when said discharge maintenance electrode ( 13 ) has a strip shape. 4. A method for driving a plasma display screen according to one of claims 2 or 3, characterized in that the surfaces of the discharge maintenance electrode ( 13 ) and the scanning electrode are coated with a dielectric ( 14 ). 5. A method for driving a plasma display screen, a matrix being formed by a write anode ( 11 ) in the column direction and a scanning cathode ( 15 ) in the row direction, and a discharge maintenance electrode ( 13 ) being formed parallel to the rows of the display screen, characterized,
that a data signal having a positive waveform is supplied to a writing electrode,
a scanning signal having a negative waveform is successively supplied to the scanning electrode with a scanning which is reciprocal of the number of scanning lines,
supplying an alternating waveform with a predetermined period to a selected discharge maintenance electrode ( 13 ),
a predetermined voltage is supplied to a cathode ( 15 ),
and the discharge is maintained by the wall charges on the discharge maintaining electrode ( 13 ) and cathode ( 15 ). 6. A method for driving a plasma display panel of claim 5, characterized in accordance with that the sustain discharge electrode (13) is formed on egg ner lower plate, or when the discharge up sustaining electrode (13) is a plate, these parallel to a an intermediate dielectric (14) having scanning electrode is formed. 7. A method of driving a plasma display panel according to claim 5, characterized in that the scanning electrode and discharge maintenance electrode ( 13 ) have inverted positions when the discharge maintenance electrode ( 13 ) has a stripe-shaped shape. 8. A method for driving a plasma display screen according to claim 6 or 7, characterized in that the surface of the discharge maintenance electrode ( 13 ) and the scanning electrode are coated with a dielectric ( 14 ). 9. A method for driving a plasma display screen, wherein a matrix is formed by a write anode ( 11 ) in the column direction and a scanning cathode ( 14 ) in the row direction, and a discharge maintenance electrode ( 13 ) is formed as a plate, characterized in that
that a data signal having a positive waveform is supplied to a writing electrode,
a scanning signal having a negative waveform is successively supplied to a scanning electrode with a scanning which is reciprocal in the number of scanning lines, an alternating waveform of a predetermined period is supplied to a maintenance electrode ( 13 ),
a predetermined voltage is supplied to a cathode ( 15 ), and the discharge is maintained by wall charges on the discharge maintaining electrode ( 13 ) and cathode ( 15 ). 10. A method for driving a plasma display panel according to claim 9, characterized in that the discharge sustaining electrode is formed (13) on egg ner lower plate, or when the discharge up sustaining electrode (13) is a plate having parallel to a an intermediate dielectric (14) Scanning electrode is formed. 11. A method for driving a plasma display screen according to claim 10, characterized in that the scanning electrode and discharge maintenance electrode ( 13 ) have inverted positions when the discharge maintenance electrode ( 13 ) has a strip-like shape. 12. A method for driving a plasma display screen according to claim 10 or 11, characterized in that the surface of the maintenance electrode ( 13 ) and scanning electrode are coated with a dielectric ( 14 ). 13. A method of driving a plasma display screen, which includes a sequential circuit ( 1 ) for selecting a scanning method ( 15 ) from among a plurality of cathodes ( 15 ); accordance with a synchronous follow-conversion circuit (2) for transmitting a data signal of a de Ano (11), which was selected among a plurality of anodes (11) through the follower circuit (1); with Schalttran sistoren ( 3 ), each having an er electrode connected to the respective output terminal of the sequential circuit ( 1 ) and whose emitter are connected to a bias source; and a maintenance pulse supply circuit connected to the collector of each of the switching transistors ( 3 ), a maintenance electrode ( 13 ), and a resistor ( 4 ) connected between a general node of the plurality of cathodes ( 15 ) and ground wherein a voltage higher than the discharge ignition voltage is applied to the selected anode ( 11 ) and sense cathode ( 15 ) to initiate a discharge by supplying a changing waveform of a predetermined period to the maintenance electrode ( 13 ) before the discharge is extinguished, and a predetermined voltage is supplied to the selected scanning cathode ( 15 ) to obtain a discharge, and then a narrow pulse is applied to the selected scanning cathodes ( 15 ) to delete the discharge. 14. A method of driving a plasma display panel according to claim 13, characterized in that the plasma display panel is formed in such a manner that an anode ( 11 ) is formed on an upper plate, a maintenance electrode ( 13 ) is formed on the surface of a lower plate, and thereon a dielectric ( 14 ) is coated and a cathode ( 15 ) is completely enclosed by the dielectric ( 14 ). 15. A method for driving a plasma display screen according to claim 14, characterized in that the plasma display screen is formed in such a way that an anode ( 11 ) is formed on an upper plate and a maintenance electrode ( 13 ) and a cathode ( 15 ) alternately in parallel a lower plate are arranged.