KR20000044802A - Matrix panel driving device of single panel thin film array-actuated system - Google Patents

Abstract

PURPOSE: A matrix panel driving device is provided to improve the color fineness by resetting the color signal applied at each unit cell during the period of a certain color projection before the next color light projection. CONSTITUTION: A device comprises a driving control part(310), a gate driving part(320), a source driving part(330), a rest driving part(340), and a TMA matrix panel(350). The TMA matrix panel resets the input color signal when the reset signal is input through the reset line. The source driving part sequentially provides the red, green, and blue color signal to each source line of the TMA matrix panel. The gate driving part sequentially provides the driving signal to each gate line of the TMA matrix panel. The reset driving part sequentially provides the reset signal to each reset line in the TMA matrix panel. The unit cell includes a first MOS transistor, an actuator, and a second MOS transistor. The source line is connected to the source terminal and the gate line is connected to the gate terminal in the first MOS transistor and one end of the actuator is connected with the common electrode and the other end is connected with the drain terminal of the first MOS transistor.

Description

Matrix panel drive system of single plate TMA system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive device for thin film mirror arrays (hereinafter referred to as TMA) systems, and more particularly to a drive device for driving a TMA matrix panel of a single-plate TMA system.

As is well known, TMA is a color light generated from a light source, for example, M * N (M, N: positive integer) in which R (Red), G (Green), B (Blue) light is installed in the TMA matrix panel. After being incident on a group of matrix mirrors, the image is reflected at a predetermined angle to generate an image, which is a kind of projection image display device.

The TMA system includes an R matrix panel, a G matrix panel, and a B matrix panel, and irradiates R, G, B light in a one-to-one correspondence with the R, G, B matrix panels, and generates an image by the reflected light. A three-plate type TMA system and one frame period are time-divided into an R light irradiation period, a G light irradiation period, and a B light irradiation period to sequentially irradiate R, G, and B light onto one matrix panel, thereby applying the reflected light to the reflected light. It can be divided into a single plate type TMA system for generating images.

The present invention relates to a single plate TMA system, in which figures for explaining a conventional single plate system are illustrated.

Referring to FIG. 1A, a matrix panel includes M * N unit cells 100 arranged in a matrix structure and includes M gate lines G ₁ to G _M and N source lines S ₁ to S _N. do. Referring to FIG. 1B, each unit cell includes a MOS transistor 10, an actuator 20 having one end connected to a drain terminal of the MOS transistor 10, and a mirror (not shown). Here, the actuator 20 drives the mirror, and the common electrode COM is applied to the other end of the actuator 20.

In addition, the unit cells 100 on the same horizontal line are commonly connected to the gate line, and the unit 100 cells on the same vertical line are commonly connected to the source line.

Therefore, when a driving signal is applied to the gate terminal of the MOS transistor 10 through a predetermined gate line, the MOS transistor 10 is turned on, and a color signal, that is, an R signal, is transmitted through the source terminal of the turned on MOS transistor 10. The G signal or the B signal is provided to the actuator 20. The actuators 20 of each unit cell adjust the angle of the mirror to correspond to the applied color signal to reflect the incident light, thereby generating an image.

In the single-plate type TMA system using the matrix panel having such a structure, one frame image is formed through three scans in one frame period, which will be described with reference to FIG. 2.

As shown in FIG. 2A, in the single plate type TMA system, R light irradiation, G light irradiation, and B light irradiation are sequentially performed for one frame period.

R signal is input to each source line (S ₁ to S _N ) during the R light irradiation period, and G signal is input to each source line (S ₁ to S _N ) during the G light irradiation period, The B signal is input to the source lines S ₁ to S _N. In addition, as shown in FIG. 2B, a driving signal is sequentially provided from G ₁ to G _M during the R light irradiation period, and again a driving signal is sequentially provided from G ₁ to G _M during the G light irradiation period. During the light irradiation period, a driving signal is provided sequentially from G ₁ to G _M.

2C to 2E illustrate a color signal holding period input to each unit cell.

FIG. 2C shows the sustain period of the R signal of the unit cells connected to the G ₁ line, FIG. 2D shows the sustain period of the R signal of the unit cells connected to the G _R line, and FIG. 2E shows the unit connected to the G _M line. The sustain period of the R signal of the cells is shown.

As shown in FIGS. 2C to 2E, the R signal applied to each unit cell is maintained in R light irradiation period units. Therefore, the sustain period of the R signal applied to the unit cell during the R light irradiation period overlaps with the G light irradiation period. For example, as shown in FIG. 2B, when a driving signal is applied to the G _M line during the R light irradiation period, the R signal is transmitted through the source lines S ₁ to S _N to the unit cells connected to the G _M line. Is applied, and the R signal applied to each unit cell is maintained for a predetermined period, as shown in Fig. 2E.

However, since the G light is irradiated before the R signal holding period of the unit cells connected to the G _M line ends, the unit cells connected to the G _M line reflect the G light corresponding to the R signal currently being maintained. will be. This action directly affects the color purity, and the lower the screen, the worse the color purity.

Accordingly, an object of the present invention is to provide a matrix panel driving apparatus of a single plate type TMA system in which color signals applied to each unit cell are maintained only within a corresponding color light irradiation period, so that color purity is constant.

In order to achieve the above object, the present invention provides a single-plate TMA that time-divides one frame period into an R light irradiation period, a G light irradiation period, and a B light irradiation period, and sequentially irradiates a corresponding color light during each of the time-divided irradiation periods. A matrix panel driving device of a system, comprising: M * N unit cells arranged in a matrix structure of M columns in a horizontal direction and N columns in a vertical direction, in which M gate lines and M reset lines correspond one to one. N source lines correspond one-to-one to the N column, and the unit cells on the same horizontal line are commonly connected to the corresponding gate line and the reset line, and the unit cells on the same vertical line are common to the corresponding source line. Each of the unit cells may be connected through the connected source line when a driving signal is applied through the connected gate line. Sikidoe reflecting the color lights corresponding to the inputted color signal, the reset signal is input via the reset line, TMA matrix panel for resetting the input color signal; A source driver sequentially providing R, G, and B color signals to the source lines of the TMA matrix panel one-to-one corresponding to the R light irradiation period, the G light irradiation period, and the B light irradiation period; A gate driver provided to each gate line of the TMA matrix panel which sequentially provides a driving signal to each gate line in the TMA matrix panel during the R light irradiation period, the G light irradiation period, and the B light irradiation period; A reset signal is sequentially provided to each reset line in the TMA matrix panel after a predetermined time after the irradiation time of the R light, after a predetermined time after the irradiation time of the G light, and after a predetermined time after the irradiation time of the B light. However, the time point for providing the reset signal to the last reset line is characterized by comprising a reset driver before the start of irradiation of the next light.

1a and 1b is a view showing the configuration of a conventional TMA matrix panel,

2A to 2E are timing diagrams for explaining the operation of the conventional TMA matrix panel.

3 is an overall configuration diagram of a matrix panel driving apparatus according to an embodiment of the present invention;

4A and 4B are detailed structural diagrams of a matrix panel according to an embodiment of the present invention;

5A to 5C are timing diagrams for explaining the operation of the matrix panel according to the embodiment of the present invention;

<Description of the code | symbol about the principal part of drawing>

310: driving control unit 320: gate driving unit

330: source driver 340: reset driver

350: TMA Matrix Panel

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram of the matrix panel driving apparatus according to the embodiment of the present invention, and FIGS. 4A and 4B show a detailed block diagram of the TMA matrix panel according to the embodiment of the present invention. A timing diagram is shown according to an embodiment of the present invention.

In FIG. 3, the matrix panel driving apparatus includes a driving controller 310, a gate driver 320, a source driver 330, a reset driver 340, and a TMA matrix panel 350. 4A and 4B, detailed configuration diagrams of the TMA matrix panel 350 are shown.

Referring to FIG. 4A, the TMA matrix panel 350 includes M * N unit cells 352 arranged in a matrix structure of M columns in a horizontal direction and N columns in a vertical direction, and M gate lines G in M columns. ₁ to G _M ) and M reset lines R ₁ to R _M correspond one-to-one, and N source lines S ₁ to S _N correspond one-to- _one to N columns.

In addition, the unit cells on the same horizontal line are commonly connected to the corresponding gate line and the reset line, and the unit cells 352 on the same vertical line are commonly connected to the corresponding source line.

Referring to FIG. 4B, each unit cell 352 has an MOS transistor 50 having a source line connected to a source end and a gate line connected to a gate end thereof, and one end connected to a drain end of the MOS transistor 50. At the other end, the actuator 60 to which the common electrode COM is connected, the source terminal is connected to the drain terminal of the MOS transistor 50, the reset line is connected to the gate terminal, and the common electrode COM is connected to the drain terminal. MOS transistor 70.

3, 4, and 5, the source driver 330 provides the R signal to the source lines S ₁ to S _N of the TMA matrix panel 350 during the R light irradiation period, and emits G light. on, and the G signal in the period available to the source lines (S ₁ to S _N) of TMA matrix panel 350, B the source lines (S ₁ to S _N) of the B signal in the light irradiation period TMA matrix panel 350, to provide.

In addition, the gate driver 320 generates a driving signal for driving the TMA matrix panel 350 in the R light irradiation period (FIG. 5A) and sequentially provides the gate signal from the gate line G ₁ to the gate line G _M. In addition, a driving signal for driving the TMA matrix panel 350 is generated in the G light irradiation period (FIG. 5A) and sequentially provided from the gate line G ₁ to the gate line G _M , and the B light irradiation period (FIG. 5A). A driving signal for driving the TMA matrix panel 350 is generated at 5a) and sequentially provided from the gate line G ₁ to the gate line G _M (see FIG. 5B).

After a predetermined time elapses after the irradiation of the R light starts, the reset driver 340 generates a reset signal for resetting the TMA matrix panel 350 and sequentially from the reset line R ₁ to the reset line R _M. After the predetermined time elapses after the irradiation of the G light starts, a reset signal for resetting the TMA matrix panel 350 is generated and sequentially provided from the reset line R ₁ to the reset line R _M. After a preset time elapses after the irradiation of the B light starts, a reset signal for resetting the TMA matrix panel 350 is generated and sequentially provided from the reset line R ₁ to the reset line R _M ( See FIG. 5C).

The driving controller 310 controls the above-described operations of the source driver 330, the gate driver 320, and the reset driver 340 based on the synchronization signal included in the image signal.

The operation of the matrix panel driving device having such a configuration is as follows. For example, when the R light irradiation is started, the source driver 330 provides an R signal on each source line S ₁ to S _{N. In addition} , when the R light irradiation is started, the source driver 330 provides a gate line. The gate driving signal is sequentially provided from G ₁ to the gate line G _M.

When a gate driving signal is applied to each gate line G ₁ to G _R , the MOS transistor 50 of each unit cell connected to each gate line is turned on. When the MOS transistor 50 is turned on, the R signal on the source line is input to the actuator 60 via the source terminal and the drain terminal of the MOS transistor 50. The actuator 60 adjusts the angle of the mirror (not shown) in response to the input R signal, and then keeps the angle of the mirror corresponding to the R signal (Fig. 5B).

At this time, the MOS transistor 70 is turned off.

On the other hand, the reset driver 340 sequentially provides a reset signal from the reset line R ₁ to the reset line R _M after a predetermined time elapses after the irradiation of the R light starts. When a reset signal is applied to each reset line R ₁ to R _R , the MOS transistors 70 of the unit cells connected to each reset line are turned on. When the MOS transistor 50 is turned on, the R signal held in the actuator 60 is discharged to the common electrode COM side via the MOS transistor 70, whereby the actuator 60 is reset.

In the above, the operations of the driving control unit 310, the gate driving unit 320, the source driving unit 330, the reset driving unit 340, and the TMA matrix panel 350 mainly focusing on the R light irradiation period have been described. The irradiation cycle and the B light irradiation cycle also perform the same functions as described above.

As described above, according to the present invention, the color signal applied to each unit cell during the predetermined color light irradiation period is reset before the next color light irradiation, thereby improving color purity.

Claims (2)

In a matrix panel driving apparatus of a single-plate TMA system which time-divides one frame period into an R light irradiation period, a G light irradiation period, and a B light irradiation period, and sequentially irradiates corresponding color light during each of the time-divided irradiation periods: M * N unit cells arranged in a matrix structure of M columns in a horizontal direction and N columns in a vertical direction, wherein M gate lines and M reset lines correspond one-to-one to M columns, and N source lines to N columns. The one-to-one correspondence unit cells on the same horizontal line are commonly connected to the corresponding gate line and the reset line, and unit cells on the same vertical line are commonly connected to the corresponding source line. When the driving signal is applied through the connected gate line, the light reflects color light corresponding to the color signal input through the connected source line, and when the reset signal is input through the reset line, the input color signal is reset. TMA matrix panel to make; A source driver sequentially providing R, G, and B color signals to the source lines of the TMA matrix panel one-to-one corresponding to the R light irradiation period, the G light irradiation period, and the B light irradiation period; A gate driver provided to each gate line of the TMA matrix panel which sequentially provides a driving signal to each gate line in the TMA matrix panel during the R light irradiation period, the G light irradiation period, and the B light irradiation period; A reset signal is sequentially provided to each reset line in the TMA matrix panel after a predetermined time after the irradiation time of the R light, after a predetermined time after the irradiation time of the G light, and after a predetermined time after the irradiation time of the B light. Wherein the reset signal is provided to the last reset line before the start of irradiation of the next light. The method of claim 1, wherein the unit cells are: A first MOS transistor having a source line connected to a source end and a gate end connected to the gate line; An actuator having one end connected to the drain end of the first MOS transistor and the other end connected to the common electrode; And a second MOS transistor having a source terminal connected to a drain terminal of the first MOS transistor, a reset line connected to a gate terminal, and a common electrode connected to a drain terminal.