KR101524476B1 - Driving apparatus for led display - Google Patents

Abstract

In a driving apparatus for an LED display which includes a plurality of pixels arranged on an X-Y matrix and N data lines and M scan lines for driving the pixels, disclosed is the driving apparatus for the LED display which includes a first ghost suppressing unit which applies a first suppressing signal which is activated for a first preset time to the M scan lines in the off section of a scan signal which is successively applied to the M scan lines and a second ghost suppressing unit which applies a second suppressing signal which is activated for a second preset time to the N data lines in the off section of the scan signal which is successively applied to the M scan lines. The first suppressing signal and the second suppressing signal are applied to prevent the first preset time and the second preset time from overlapping.

Description

DRIVING APPARATUS FOR LED DISPLAY [0002]

The present invention relates to an LED display driving apparatus, and more particularly, to a driving apparatus capable of suppressing a ghost phenomenon of an LED display.

1 is a configuration diagram of an LED display driving apparatus 100 according to a first embodiment of the present invention. ₂ shows timing diagrams of scan lines SL ₁ , SL ₂ , SL ₃ ,..., SL _M of the general dynamic type LED display driver 100, 200, 300, 400.

In the case of a dynamic LED driving apparatus such as the LED display driving apparatus 100 according to the first embodiment of the present invention, the scan lines (SL ₁ , SL ₂ , SL ₃ , ..., The parasitic capacitors act largely on the data lines SL ₁ and SL _M and the data lines DL ₁ and DL ₂ and the data lines DL _{3 to} DL _N. The distinction between the lines SL ₁ , SL ₂ , SL ₃ , ..., SL _M becomes unclear, which is called a ghost phenomenon.

Specifically, as an example of the ghost, when a transition to the second switch K K + 1 switch (SW _{K +1)} from (SW _K) occurs, the energy charged by the parasitic capacitances of the K scanning lines (SL _K) that did not fully discharged, the K + 1 switch is turned on (on) for the predetermined period of time (SW _{K +1),} and wherein the data lines _{(DL 1, DL 2, DL} 3, ..., DL N) is when a certain period of time on , The pixel coupled to the _K th scan line SL _K , that is, the LED (Light Emitting Diode) cell is momentarily turned on.

Another ghosting phenomenon is related to the parasitic capacitors present in the data lines (DL ₁ , DL ₂ , DL ₃ , ..., DL _N ) of the LED display (DSP), also referred to as the channel line. When the scan lines SL ₁ , SL ₂ , SL ₃ , ..., SL _M are turned off and the data lines DL ₁ , DL ₂ , DL ₃ , ..., DL _N are also turned off, _1, SL _2, SL _3, ..., _M SL) when the naturally be a parasitic capacitor is discharged in the off interval (TB) and scan lines (SL _{k +1)} is turned on, the actual data line (DL _1, DL _{2 , DL 3, ..., DL N} ) (DL 1, this need not be the whole data lines _{DL 2, DL 3, ...,} DL N) is not a parasitic capacitor is discharged in a short time want while charging the next scan line (SL _{k + 1} ) LED cell is turned on.

In order to solve the above-mentioned problems, various methods such as the following have been developed and a visible effect has been confirmed.

3 is a configuration diagram of an LED display driving apparatus 200 according to a second embodiment of the present invention. As can be seen from FIG. 3, a resistor is connected to the scan lines SL ₁ , SL ₂ , SL ₃ ,..., SL _M to pull down the scan lines. And the efficiency of the entire system is deteriorated.

4A is a configuration diagram of the LED display driving apparatus 300 according to the third embodiment of the present invention, and FIG. 4B is a configuration diagram of a switch used in the LED display driving apparatus 300 according to the third embodiment of the present invention.

The LED display driving apparatus 300 according to the third embodiment of the present invention is a push-pull type display apparatus in which a switch configuration is added to compensate for the disadvantages of the LED display driving apparatus 200 according to the second embodiment of the present invention. ) Type. However, the LED display driving apparatus 300 according to the third embodiment also has a disadvantage that the cost is increased.

In addition, the LED display driving apparatus 200 according to the second embodiment and the LED display driving apparatus 300 according to the third embodiment of the present invention have the following additional side effects.

Assuming _M scan lines SL ₁ , SL ₂ , SL ₃ , ..., SL _M , for example, after the first scan line SL ₁ is turned on, all the scan lines SL ₁ to SL _M , The pull-down or push-and-pull operation is always performed in the OFF period TB and the reverse voltage is applied to the LED cells (i.e., pixel cells) connected to the second scan line SL ₂ to the M scan line SL _M Thereby causing destruction of the LED cell. When a specific LED cell is damaged by such a cause, the remaining LED cells connected to the corresponding data lines DL ₁ , DL ₂ , DL ₃ , ..., DL _N are not turned off, .

SUMMARY OF THE INVENTION It is an object of the present invention to solve the technical problems as described above, and it is an object of the present invention to provide an LED display drive device capable of eliminating the ghost phenomenon of an LED display.

It is still another object of the present invention to provide an LED display driving apparatus capable of preventing a reverse voltage that can be applied to an LED cell that may be involved in removing a ghost phenomenon of an LED display, thereby increasing the lifetime of the LED cell.

The LED display driving apparatus of the present invention is an apparatus for driving an LED display including a plurality of pixels arranged in an XY matrix and M scan lines and N data lines for driving the plurality of pixels, A first ghost suppression unit for applying a first suppression signal activated during a first predetermined period of the scan signal, which is sequentially applied to the M scan lines, to the M scan lines; A second ghost suppression unit for applying a second suppression signal to the N data lines, the second suppression signal being activated for a second predetermined period of a scan signal sequentially applied to the M scan lines; And at least one of them.

Specifically, it is preferable that the 1-ghost suppression unit pulls down the M scan lines by applying the first suppression signal activated to a low level for the first predetermined time period to the M scan lines Do.

The second ghost suppression unit may be configured to pull up the N data lines by applying the second suppression signal activated at a high level to the N data lines for the second predetermined time period .

Preferably, when the LED display driving apparatus includes both the first ghost suppression unit and the second ghost suppression unit, the first suppression signal and the second suppression signal are set so that the first predetermined time and the second predetermined time do not overlap in time, And the second suppression signal is applied.

According to the LED display driving apparatus of the present invention, the ghost phenomenon of the LED display can be eliminated. Also, according to the present invention, a reverse voltage that can be applied to the LED cell, which may be involved in removing the ghost phenomenon of the LED display, can be prevented, and the lifetime of the LED cell can be increased.

1 is a configuration diagram of a conventional LED display driving apparatus according to a first embodiment;
2 is a timing diagram of a scan line of a general dynamic type LED display driving apparatus.
3 is a configuration diagram of an LED display driving apparatus according to a second embodiment of the present invention.
4A is a configuration diagram of an LED display driving apparatus according to a third embodiment of the related art.
4B is a configuration diagram of a switch used in the LED display driving apparatus according to the third embodiment of the related art.
5 is a configuration diagram of an LED display driving apparatus according to a preferred embodiment of the present invention.
6 is an explanatory view of a ghost phenomenon of a typical LED display;
7 is a timing diagram of an LED display driving apparatus according to a preferred embodiment of the present invention.
8 is an exemplary diagram of a first ghost suppression unit and a second ghost suppression unit;

Hereinafter, a LED display driving apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It should be understood that the following embodiments of the present invention are only for embodying the present invention and do not limit or limit the scope of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

5 is a configuration diagram of an LED display driving apparatus 400 according to a preferred embodiment of the present invention.

5, the LED display driving apparatus 400 according to an embodiment of the present invention includes a switch unit 410, a driving unit 420, and a control unit 430. As shown in FIG.

Switch unit 410, is input from the scanning signal (S (SL _1), S (SL _2), S (SL _3), ..., S (SL _M)), the control unit 430 as shown in Figure 2 receiving each of the scan lines _{(SL 1, SL 2, SL} 3, ..., SL M) and the scan signal _{(S (SL 1), S} (SL 2), S (SL 3), ..., S (SL M)) by .

The driving unit 420 is basically composed of the data lines DL ₁ , DL ₂ , DL ₃ , ... of the LED display DSP by the respective driver stages 421 (1), 421 (2), 421 DL _N ) to drive the LED display (DSP). The driving unit 420 of the present invention may include a first ghost suppression unit 422 and a second ghost suppression unit 423 to detect a ghost or a shadow that may occur in the LED display DSP. And suppresses the phenomenon.

The control unit 430 generates scan signals S (SL ₁ ), S (SL ₂ ), S (SL ₃ ), ..., S (SL _M ), a data signal, And the operation of the driving unit 420.

More specifically, the operation of the first ghost suppression unit 422 and the second ghost suppression unit 423 of the present invention will be described.

5, in the case of a general LED display (DSP), a plurality of pixels arranged on an XY matrix and M scan lines SL ₁ , SL ₂ , SL ₃ , ..., SL _M and N data lines DL ₁ , DL ₂ , DL ₃ , ..., DL _N. Each of the pixels are LED (Light Emitting Diode, a light emitting diode), a cell is configured, the anode of the LED cell of scan lines _{(SL 1, SL 2, SL} 3, ..., SL M) is the negative electrode, the data line (DL _1, DL _{2, DL 3, ..., DL} N) is connected to each scanning signal _{(S (SL 1), S} (SL 2), S (SL 3), ..., is applied to the data signal S (SL _M)) The LED cell is operated.

6 is an explanatory view of a ghost phenomenon of a general LED display (DSP). 6, each LED cell constituting the LED display DSP includes a first parasitic capacitor C _par1 connected to the anode and a second parasitic capacitor C _par2 connected to the cathode, The ghost phenomenon occurs by the capacitor C _par1 and the second parasitic capacitor C _par2 .

That is, when the transition to the first K + 1 switch (SW _{K +1)} proceed from the K switch (SW _K), the energy charged by the first parasitic capacitance (C _par1) of the K scanning lines (SL _K) When the data lines DL ₁ , DL ₂ , DL ₃ , ..., DL _N are turned on at this time, the Kth scan line (SW _{K + 1} ) pixel, that is, LED cell is momentarily illuminated in the connected (SL _K).

Further, scan lines (SL _1, SL _2, SL _3, ..., SL _M) is turned off (Off), and a data line (DL _1, DL _2, DL _3, ..., DL _N) In addition, if the off (in Fig. 2 The second parasitic capacitor C _par2 is discharged naturally in the interval TB where all of the scan lines SL ₁ , SL ₂ , SL ₃ , ..., and SL _M are turned off and the next scan line SL _{k + 1} is turned on, even if the actual data lines DL ₁ , DL ₂ , DL ₃ , ..., DL _N are not turned on, the second parasitic capacitor C _par2 discharged in a short time is charged, The line SL _{k + 1} is turned on.

The first ghost suppression unit 422 of the present invention is configured to suppress the ghost phenomenon generated by the first parasitic capacitor C _par1 while the second ghost suppression unit 423 suppresses the ghost phenomenon generated by the second parasitic capacitor C _par2 . Respectively.

The first ghost suppression section 422 and the second ghost suppression section 423 of the present invention can be integrated on the integrated circuit chip together with the driver stages 421 (1), 421 (2), and 421 (P) And at least one of the first ghost suppression unit 422 and the second ghost suppression unit 423 may be implemented outside the integrated circuit chip.

7 is a timing diagram of an LED display driving apparatus 400 according to an exemplary embodiment of the present invention. 8 is an exemplary diagram of the first ghost suppression unit 422 and the second ghost suppression unit 423. [

The first ghost suppression unit 422 receives the scan signals S (SL ₁ ), S (SL ₂ ), and S (S ₁ ) sequentially applied to the _M scan lines SL ₁ , SL ₂ , SL ₃ , _{SL 3), ..., S (} SL M)) the scan lines of a first inhibit signal (SIG1) in some sections of the off-the interval _{(TB) M (SL 1,} SL 2, SL 3, ..., SL M) . That is, the first ghost reduction unit 422, the first predetermined time (T1), a low level (Low Level), the M scan lines first inhibit signal (SIG1) which are activated by (SL _1, SL _2, SL ₃ for ..., SL _M to pull down the _M scan lines SL ₁ , SL ₂ , SL ₃ , ..., SL _M.

The first ghost suppressor 422 can apply the first suppression signal SIG1 to discharge the charge stored in the first parasitic capacitor C _par1 to generate the first parasitic capacitor C _par1 Thereby suppressing the ghosting phenomenon caused by the ghost phenomenon.

The second ghost suppression unit 423 receives the scan signals S (SL ₁ ), S (SL ₂ ), and S (S ₂ ) sequentially applied to the _M scan lines SL ₁ , SL ₂ , SL ₃ , _{SL 3), ..., S (} SL M)) are in some sections of the off-the region (TB) a second inhibit signal (SIG2) N data lines _{(DL 1, DL 2, DL} 3, ..., DL N) . The second ghost suppression unit 423 receives the scan signals S (SL ₁ ) and S (SL ₂ ) sequentially applied to the _M scan lines SL ₁ , SL ₂ , SL ₃ , A second suppression signal SIG2 activated at a high level for a second predetermined time T2 in an interval TB in which S (SL ₃ ), ..., S (SL _M ) by applying to the data lines _{(DL 1, DL 2, DL} 3, ..., DL N), and the N data line _{(DL 1, DL 2, DL} 3, ..., DL N) pull-up (pull Up) .

To explain words, the second ghost reduction unit 423, the second inhibit signal is applied to (SIG2), a second parasitic capacitor (C _par2) the second parasitic capacitor (C _par2) and to charge the electric charges in Thereby suppressing the ghosting phenomenon.

As can be seen from FIG. 8, the first suppression signal SIG1 and the second suppression signal SIG2 receive signals inverted from the control unit 430 and use signals inverted by the transistors. At this time, it is necessary to apply a voltage (V2) higher than the cutoff voltage of the LED cell to the source of the transistor of the second ghost suppression unit 423.

When the first suppression signal SIG1 of the first ghost suppressor 422 and the second suppression signal SIG2 of the second ghost suppressor 423 are simultaneously activated and applied to the LED cell, So that it is not preferable.

Therefore, when the LED display driving apparatus 400 of the present invention includes both the first ghost suppression unit 422 and the second ghost suppression unit 423, It is preferable to apply the first suppression signal SIG1 and the second suppression signal SIG2 so that the time T1 and the second predetermined time T2 as the activation period of the second suppression signal SIG2 do not overlap in time.

Inhibition of claim 1 of the present invention as described above, the signal (SIG1) and a second inhibit signal (SIG2), respectively, M of scan lines Scan is sequentially applied to the _{(SL 1, SL 2, SL} 3, ..., SL M) signal _{(S (SL 1), S} (SL 2), S (SL 3), ..., S (SL M)) is a partial section of an off-the region (TB) a first predetermined time (T1) and a second constant Is applied to the LED cell for only the time T2, it is possible to prevent the reverse voltage that can be applied to the LED cell to the utmost, so that the lifetime of the LED cell can be increased as compared with the prior art.

DSP: LED display
100: LED display driving device according to the first embodiment of the related art
200: LED display driving device according to the second embodiment of the related art
300: LED display driving device according to the third embodiment of the related art
400: LED display driver according to a preferred embodiment of the present invention
410: switch unit 420:
430:
421 (1), 421 (2), 421 (P): driver stage
422: first ghost suppression unit 423: second ghost suppression unit
C _par1 : first parasitic capacitor C _par2 : Second parasitic capacitor
SIG1: first suppression signal SIG2: second suppression signal

Claims (4)

An apparatus for driving an LED display including a plurality of pixels arranged in an XY matrix and M scan lines and N data lines for driving the plurality of pixels,
A first ghost suppression unit for applying a first suppression signal activated for a first predetermined period of the M scan lines to the M scan lines in a period in which scan signals sequentially applied to the M scan lines are off; And
And a second ghost suppression unit for applying a second suppression signal, which is activated during a second predetermined period of time, to the N data lines during a period in which scan signals sequentially applied to the M scan lines are off,
Wherein the first suppression signal and the second suppression signal are applied so that the first predetermined time and the second predetermined time do not overlap in time. The method according to claim 1,
Wherein the 1-ghost suppression unit comprises:
Wherein the M scan lines are pulled down by applying the first suppression signal activated to a low level during the first predetermined time to the M scan lines. 3. The method of claim 2,
Wherein the second ghost suppression unit comprises:
Wherein the N data lines are pulled up by applying the second suppression signal activated at a high level for the second predetermined time to the N data lines. delete

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