KR100498283B1 - Structure for matrix of mim fed - Google Patents

Abstract

The present invention relates to a matrix structure of a metal-insulator-metal field emission display. The matrix of a conventional metal-insulator-metal field emission display has a simple passive matrix structure, so that the display has a large area and its length and resistance This increase caused a large drop in voltage, and thus left and right brightness of the screen was different. In view of the above problems, the present invention provides a plurality of data electrodes, a plurality of scan electrodes perpendicularly intersecting the plurality of data electrodes, and a plurality of data electrodes and a plurality of scan electrodes in an area formed by the plurality of data electrodes and the plurality of scan electrodes. A metal-insulator-metal structure conducting a first transistor according to an applied driving voltage to store data of the data electrode in a capacitor, and conducting a second transistor by data stored in the capacitor to receive a common voltage on one side. It consists of a plurality of pixels that drive the cell and reset the metal-insulator-metal structure cell at a high voltage through a resistor without using a reset pulse, converting the matrix into an active matrix type, Reduces the applied current, prevents the voltage from being lowered by the resistance of the scan electrode, Improvement of the brightness and Sikkim addition has the effect of ensuring the uniformity of the brightness. In addition, it is possible to automatically reset after driving without using a reset pulse, thereby improving image quality by reducing the characteristic difference between pixels, and simplifying the driving circuit by omitting the driving circuit for generating a reset pulse. .

Description

Matrix Structure of Metal-Insulator-Metal Field Emission Display {STRUCTURE FOR MATRIX OF MIM FED}

The present invention relates to a matrix structure of a metal-insulator-metal field emission display. In particular, the present invention relates to a matrix structure of a metal-insulator-metal field emission display. One metal-insulator-metal field emission display relates to a matrix structure.

In general, a metal-insulator-metal (MIM) type display in which the electrode has a large resistance and requires a low voltage and a high current among the matrix displays, and the voltage applied by the resistance difference of the scan electrode is lowered when driving the large screen. Differences occur in left and right brightness.

The MIM type display uses a much lower voltage (a few V to 10V) and a higher current than other flat panel displays.

The problem does not occur in the small display, but in the large-screen MIM display, the voltage is lowered due to the resistance of the scan electrode because the voltage used is low. Therefore, a voltage of a desired value can be applied to the scan electrode relatively far from the driving circuit applying the voltage. The difference in brightness occurs on the screen, and the matrix structure of the conventional MIM FED and its operation will be described in detail with reference to the accompanying drawings.

FIG. 1 is a cross-sectional view of a pixel of a general MIM FED, in which a scan electrode 2 is positioned on a lower substrate 1, and an insulating film 3 and a data electrode 4 are disposed on an upper surface of the scan electrode 2. ) Has a laminated structure.

When the voltage difference between the scan electrode 2 and the data electrode 4 increases, electrons are excited from the data electrode 4, and electrons excited to the anode 5 are moved by the electric field of the upper and lower plates to move the screen. Will be displayed.

At this time, the driving voltage applied to the scan electrode 2 and the data electrode 4 has a range of several V to 10V.

FIG. 2 is a plan view showing the arrangement of a simple matrix type, that is, a passive matrix type data electrode and a scan electrode in the MIM FED. As shown in FIG. A passive matrix is positioned in the direction perpendicular to the data electrode 4.

In the passive matrix structure, the scan electrode 2 increases in length as the area becomes larger, and the resistance also increases.

In this state, a voltage difference is generated between one side of the scan electrode 2 directly connected to the driving circuit and the scan electrode 2 at a position far from the driving circuit, thereby causing a difference in brightness on the left and right sides of the screen. do.

The resistance of the scan electrode 2 of the large screen MIM FED is usually about 100 ohm, and the current used uses a voltage of 100 to 400 mA.

Simply multiplying the resistance value and the current value shows the degree of voltage drop, and may occur when the voltage drop of at least 10V occurs and the drive itself is not available.

3 is a driving waveform diagram of a conventional MIM FED. As shown in FIG. 3, the driving voltages SCAN1 to SCANn for driving each scan electrode 2 have a negative voltage at the time of driving the scan electrode 2. Is applied in the form.

After displaying one frame by such an operation, the driving voltages SCAN1 to SCANn are applied in the form of a pulse having a positive voltage, which is called a reset pulse.

The reset pulse is a signal output only at a specific time point at which an image signal is not input. When the reset pulse is applied, the voltage charged by the display of the previous frame may be removed.

However, the reset pulse is a signal that is applied only between a frame and a frame, that is, a short time point at which an image signal is not input. Accordingly, the pulse width is limited.

If a reset pulse is not applied for a period sufficient for a reset as described above, a case in which no reset occurs occurs and image quality deteriorates in the display of the next frame.

As described above, the matrix structure of the conventional MIM FED has a simple passive matrix structure, and as the display becomes large, the length and resistance of the scan electrode increase, so that the voltage decreases and the brightness of the left and right sides of the screen is different. .

In addition, after one frame is displayed by a simple matrix structure, a reset pulse is applied to reset and the next frame is displayed. However, there is a problem that the reset pulse does not occur correctly due to a short application period of the reset pulse.

In view of the above problems, the present invention provides a uniform screen brightness over a large display screen and provides a matrix structure of the MIM FED capable of discharging a voltage charged in a cell without using a reset pulse. have.

The above object is a driving voltage applied to a scan electrode in a region formed by a plurality of data electrodes, a plurality of scan electrodes perpendicularly intersecting the plurality of data electrodes, and a plurality of data electrodes and a plurality of scan electrodes. According to the present invention, a plurality of pixels store data of a data electrode and use the stored data to drive a cell of a metal-insulator-metal structure and to reset a cell of the metal-insulator-metal structure without using a reset pulse. It is achieved by the configuration as described in detail with reference to the accompanying drawings, the present invention as follows.

FIG. 4 is a matrix structure diagram of the MIM FED of the present invention, and has an active matrix structure including a plurality of cells (CELL) driven by the scan electrode 2 and the data electrode 4 as shown.

Each cell CELL is commonly connected to the scan electrode 2 for each electrode, and is also connected to ground.

FIG. 5 is a circuit configuration diagram of the cell CELL in FIG. 4, and as shown therein, the transistor T1 is electrically controlled according to the potential of the scan electrode 2 to switch the data of the data electrode 4; ; A capacitor Cs for receiving and storing data through the transistor T1; A transistor (T2) electrically controlled by data stored in the capacitor (Cs); A diode D1 connected between the source and the drain of the transistor T2; The MIM cell receives a common voltage COM on one side, and the other side is connected to the source of the transistor T2, and when the transistor T2 is earthed, it is connected to ground and emits light by the potential difference between the common voltage COM and the ground. (MIM); A resistor R1 is applied to reset the MIM cell MIM by applying a current caused by the high voltage 15V to the other side of the MIM cell MIM.

Hereinafter, the present invention configured as described above will be described in more detail.

FIG. 6 is a waveform diagram of a driving signal for driving the MIM FED of the present invention. As shown in FIG. 6, each of the plurality of scan electrodes 2 is sequentially arranged in accordance with data of the data electrode 4 when displaying one frame. Drive.

First, when the scan electrode driving signal is applied to the scan electrode 2, the transistor T1 applied to the gate is applied according to the driving signal applied to the scan electrode 2 and the voltage of the data electrode 4 connected to the source. The conduction state is determined.

In FIG. 6, while the low potential is applied to the scan electrode 2, the transistor T1 is turned on to transmit data applied to the data electrode 4.

Then, the data of the transferred data electrode 4 is charged in the capacitor Cs.

When the capacitor Cs is charged in this manner, the transistor T2 is turned on by the voltage charged in the capacitor Cs.

When the transistor T2 is conducted as described above, since the common voltage COM and the ground voltage GND of 10V are applied to the two electrodes of the MIM cell MIM, light is emitted by the potential difference.

The common voltage COM is an AC pulse voltage or a constant DC voltage.

In this case, the voltage of 15V applied through the resistor R1 does not affect the circuit, and gray scales may be implemented according to the voltage charged in the capacitor Cs, that is, the size of data.

This makes it possible to continuously emit the MIM cell (MIM) for the entire frame, increase the overall brightness of the display, and can be reduced compared to the conventional passive matrix method.

Then, when the driving voltage of the scan electrode 2 becomes 0V, the transistor T1 is turned off.

Even when the transistor T1 is turned off, the capacitor Cs has a charged voltage. As a result, the transistor T2 maintains a conduction state for a predetermined time, and the MIM cell MIM maintains light emission during this period. do.

When the transistor T2 is turned off after a certain time, the common voltage COM is continuously applied to one side of the MIM cell MIM, but a voltage of 15 V is applied to the other side through the resistor R1 rather than the ground voltage. Thus, the charges charged in the MIM cell MIM are removed.

This is to give the effect of reset which is the same effect as the application of the conventional reset pulse.

That is, as shown in the driving waveform diagram of FIG. 6, the pixel can be reset when driving of the pixel is completed without using a separate reset pulse.

The driving time and period and the reset period of the MIM cell MIM will be described in more detail.

FIG. 7 is a waveform diagram showing a pulse amplitude modulation driving time, a pulse width modulation driving time, and a reset period in each case in the driving waveform diagram of the present invention. As shown in FIG. It is driven in a section with low potential. In the figure, PWM ON is shown to indicate the time for which pulse width modulation is driven.

In this case, the remaining sections are reset sections, and as the reset time increases, the MIM cell MIM is completely reset so that there is no residual charge.

This can solve the difference in brightness due to the difference in the degree of reset between the pixels caused by the conventional short reset time.

In addition, in the case of pulse amplitude modulation, it operates in a period within one frame in which the high potential is applied to the last scan electrode from the time when the first scan electrode becomes high potential, which is also denoted as PAM ON.

At this time, the reset is performed in the remaining sections.

As described above, the present invention implements the MIM FED in an active matrix structure, thereby reducing the driving current to prevent the brightness of the screen from varying depending on the position due to the resistance of the scan electrode, and performing reset without generating a reset pulse. It becomes possible.

In addition, the reset time is further increased to completely reset the MIM cell so that no charge is accumulated, thereby preventing the screen from deteriorating at the display of the next frame.

By performing the reset without using the reset pulse, it is possible to simplify the circuit for driving the scan electrode.

As described above, the present invention converts the matrix of the MIM FED into an active matrix type to reduce the current applied to the scan electrode and the cell, prevent the voltage from being lowered by the resistance of the scan electrode, and improve the brightness of the screen. In addition to this, there is an effect of ensuring the uniformity of the brightness.

In addition, it is possible to automatically reset after driving without using a reset pulse, thereby improving image quality by reducing the characteristic difference between pixels, and simplifying the driving circuit by omitting the driving circuit for generating a reset pulse. .

1 is a cross-sectional view of a pixel of a typical MIM FED.

2 is a plan view showing the arrangement of a passive matrix data electrode and a scan electrode in a MIM FED;

3 is a driving waveform diagram of a conventional MIM FED.

4 is a matrix structure diagram of the present invention MIM FED.

FIG. 5 is a circuit diagram of a cell CELL in FIG. 4; FIG.

Figure 6 is a waveform diagram of a drive signal for driving the MIM FED of the present invention.

Fig. 7 is a waveform diagram showing a pulse amplitude modulation driving time point and a pulse width modulation driving time point and reset period in each case in the driving waveform diagram of the present invention.

* Description of the symbols for the main parts of the drawings

2: scanning electrode 4: data electrode

CELL: Cell T1, T2: Transistor

Cs: Capacitor D1: Diode

R1: Resistance

Claims (4)

A plurality of data electrodes, a plurality of scan electrodes perpendicularly intersecting the plurality of data electrodes, and a first driving voltage applied to the scan electrodes in an area formed by the plurality of data electrodes and the plurality of scan electrodes. The transistor conducts the data of the data electrode in the capacitor, conducts the second transistor by the data stored in the capacitor, drives the cell of the metal-insulator-metal structure to which the common voltage is applied to one side, and resets the pulse. A matrix structure of a metal-insulator-metal field emission display, characterized in that it consists of a plurality of pixels for resetting the cells of the metal-insulator-metal structure with a high voltage through a resistor without using. The matrix structure of a metal-insulator-metal field emission display according to claim 1, wherein each of the plurality of pixels further comprises a diode connected between a source and a drain of the second transistor. delete  The metal-insulator-metal of claim 1, wherein the capacitor stores data when the first transistor is in a conductive state, so that the second transistor is conductive even when the first transistor is turned off while one frame is displayed. Matrix structure of field emission display.