JP2002189445A - Image display device and its driving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display device which uses EL elements and always displays a high quality image by eliminating induced electric charges caused by the changes in external environment while the elements are turned off. SOLUTION: An organic EL element 5 is turned on by a turn on start pulse Ps inputted to an active element circuit during a turn-on time Td and turned off by a turn off pulse Pe. During a turned off time interval of the element 5, a reset pulse Pr having a pulse width that is correspondingly set to a video signal level is inputted to a setting number of times active element circuit and the element 5 is reset. Induced electric charges generated onto the element 5 by the changes in external environment during the turned off time interval are eliminated by the turned on time of a next field and a complete reset is conducted. Thus, video data writing to the element 5 in a next time is conducted to the element 5, which is a complete reset state, in a highly precise manner and the occurrence of quality deterioration of a display image caused by the changes in the external environment is completely prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an image display device for displaying an image corresponding to an input video signal on a display panel using an EL element, and a driving method thereof.

[0002]

2. Description of the Related Art By applying a drive voltage to an electrode sandwiching an EL material, an EL (electroluminescence: electroluminescence) which emits light when a luminescent center substance of the excited EL material returns to a ground state is used. EL that emits light
The panel is a FA (Factory Automation) conventionally used as an electronic display for displaying images.
)) Not only in the fields of equipment and financial terminals,
In recent years, utilization in the field of workstations has been promoted by taking advantage of the feature that high precision and large display capacity can be displayed.

[0003] This type of EL panel includes E in a binder.
There are a dispersion type EL panel in which an L material is dispersed and a display pattern is formed by a screen printing method, and a thin film EL panel having a multilayer thin film structure in which a base material to which a luminescent center substance is added is used as an EL material and sandwiched by electrodes. The dispersion type EL panel has a voltage-
Since the steepness of the rise of the luminance characteristic is insufficient and is not suitable for matrix driving, it is often used mainly as a planar light source of a backlight.

By the way, as the EL material of the thin film EL panel used for the matrix drive, an inorganic EL material such as ZnS has been conventionally used, but the driving voltage required for light emission of sufficient luminance is about 200 V. However, there is a difficulty in making the whole structure compact, and in recent years, thin-film EL panels using various organic EL materials have been developed. In this type of thin-film organic EL panel, a luminance of several hundreds to several thousand cd / m ² can be obtained with a driving voltage of 10 V or less, so that there is great expectation for use in a workstation field in the future.

[0005]

SUMMARY OF THE INVENTION A conventional thin film E of this kind
In an image display apparatus provided with an L panel, an active element circuit including a MOS transistor for driving a plurality of EL elements disposed at intersections of scanning lines and drive lines arranged in a matrix to emit light is provided. In the memory of the CPU which controls the operation of the pixel, the optimum light emission level data and the optimum light emission time data for driving the corresponding EL element are stored in advance based on the pixel signal level applied to the EL element according to the input video signal. ing. During the image display operation, the signal level of the input video signal is detected,
The optimum light emission level data and the optimum light emission time data of the EL element corresponding to the detection signal level are read from the memory,
The EL element is driven to emit light by the active element circuit based on the read light emission level and light emission time. In this case, the input of a lighting start pulse to the active element circuit causes the active element circuit to emit light and the EL element emits light, and the input of a turn-off pulse to the active element circuit turns off the EL element in the lighting state. Image display is performed under optimal conditions corresponding to the video signal.

[0006] By the way, it is known that an EL element has a relatively large variation in operating characteristics including light emission luminance with respect to an ambient temperature, and after the EL element is turned off in one field, the EL element is turned off in the next field. In the light-off period until the element emits light, the active element circuit is in a non-drive state. In this case, external noise may enter the active element circuit due to a change in the external atmosphere, and at this time, the EL element is affected by the operating characteristics of the EL element which fluctuates due to a change in the ambient temperature.
Induced charges may be generated in the device. As described above, when an induced charge is generated in the EL element in the light-off state due to a change in the external atmosphere, the pixel video data of the input video signal to the EL element is not accurately written in the next field. This causes the quality of the displayed image to deteriorate.

The present invention has been made in view of the current state of operation of an image display device using an EL element as described above. A first object of the present invention is to provide an image display apparatus using an EL element in an EL display. It is an object of the present invention to provide an image display device capable of always performing high-quality image display by removing and eliminating induced charges generated due to a change in an external atmosphere during a light-off period of an element. Further, a second object of the present invention is to provide an image display device using an EL element, in which an induced charge generated due to a change in an external atmosphere is removed and eliminated in a time period during which the EL element is turned off. It is an object of the present invention to provide a driving method of an image display device which can always display a high quality image.

[0008]

In order to achieve the first object, according to the present invention, a plurality of scanning lines and a plurality of driving lines are arranged at intersections of scanning lines and driving lines arranged in a matrix. In an image display device in which an EL light emitting element is driven to emit light by an active element circuit arranged corresponding to each light emitting element, and the EL light emitting element displays an image corresponding to an input video signal, the EL light emitting element A lighting time setting means for setting a lighting time required for displaying an image of the input video signal within a maximum lighting time of the EL light emitting element; and inputting a light emission pulse to the active element circuit. Light emitting element lighting means for setting the EL light emitting element to a light emitting state during the lighting time set by the lighting time setting means; and A light emitting element extinguishing means for extinguishing the EL light emitting element by inputting a light extinguishing pulse to the active element circuit; and a light extinguishing time from the extinguishing of the EL light emitting element by the light emitting element extinguishing means to the maximum possible lighting time. A band is provided with reset means for resetting the EL element via the active element circuit by inputting a reset pulse to the active element circuit at least once.

According to such a means, the lighting time required for displaying the image of the input video signal for the EL light emitting element is set by the lighting time setting means within the maximum light emitting time of the EL light emitting element, A light emitting pulse is input to the active element circuit by the light emitting element lighting means,
During the lighting time set by the lighting time setting means, EL
The light emitting element is set to the light emitting state, and at the end of the lighting time,
The EL light emitting element is turned off by the input of the light emitting pulse to the active element circuit by the light emitting element turning off means. Further, in a light-off period from the time when the EL light-emitting element is turned off to the time when the EL element can be turned on, the reset means inputs a reset pulse to the active element circuit at least once and resets the EL element via the active element circuit. Even if an induced charge is generated in the EL element due to a change in the external atmosphere, the induced charge is removed and erased by resetting the reset means, and writing to the EL element in the next field is performed with high accuracy, and high quality is always obtained. An image is displayed.

[0010] Similarly, in order to achieve the first object,
The invention of claim 2 is different from the invention of claim 1 in that
A reset pulse condition setting means for setting a reset pulse condition including a pulse width of a reset pulse applied to the EL light emitting element is further provided.

According to such a means, in addition to the effect of the first aspect, the reset pulse condition including the pulse width of the reset pulse applied to the EL light emitting element is set by the reset pulse condition setting means. Therefore, the reset operation by the reset means is performed more accurately.

According to a third aspect of the present invention, a plurality of EL light emitting elements are arranged at intersections of scanning lines and drive lines arranged in a matrix. In a method for driving an image display device, in which light emission is driven by an active element circuit provided corresponding to a light emitting element and an image corresponding to an input video signal is displayed by these EL light emitting elements, A lighting time setting step of setting a lighting time required for displaying an image of the input video signal within a maximum lightable time of the EL light emitting element; and inputting a light emission pulse to the active element circuit, thereby performing the lighting. A light emitting element lighting step of setting the EL light emitting element to a light emitting state during the lighting time set in the time setting step; and at the end of the lighting time. A light emitting element extinguishment step of extinguishing the EL light emitting element by inputting an extinguishing pulse to the active element circuit, and an extinguishing time from the extinguishing of the EL light emitting element by the light emitting element extinguishing step to the maximum possible lighting time. A reset step of resetting the EL element via the active element circuit by inputting a reset pulse to the active element circuit at least once in the band.

According to such a method, in the lighting time setting step, the lighting time required for displaying the image of the input video signal for the EL light emitting element is set within the maximum possible lighting time of the EL light emitting element, In the light emitting element lighting step, a light emitting pulse is input to the active element circuit, and the EL light emitting element is set to the light emitting state during the lighting time set in the lighting time setting step. At the end of the lighting time, the light emitting element is turned off. The EL light emitting element is extinguished by the input of the extinguishing pulse to the active element circuit in the step. Further, in a light-off time period from the time when the EL light emitting element is turned off to the time when the EL element can be turned on, at the reset step, a reset pulse is input to the active element circuit at least once, and the EL element is reset via the active element circuit. , Due to changes in the external atmosphere,
Even if the induced charge is generated in the L element, the induced charge is removed and lost by the reset in the reset step, writing to the EL element in the next field is performed with high accuracy, and a high-quality image display is always performed.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below based on an embodiment of an image display device with reference to FIGS. FIG. 1 is an explanatory diagram showing a configuration of a main part of an embodiment of the present invention relating to an image display device, and FIG. 2 is an explanatory diagram showing an operation of the present embodiment in comparison with a conventional operation.

In the present embodiment, as shown in FIG. 1, a panel control circuit 2 for controlling an image display operation of the display panel 1 for a display panel 1 for displaying an input video signal as an image.
And a video signal processing circuit 3 that performs signal processing for image display on the input video signal, and is connected to the display panel 1.
Are provided with MOS transistors Tr1 to Tr4, a capacitor Cs and an organic EL element 5, and a pulse control circuit 2
Is provided with a start pulse output circuit 2a and a control pulse output circuit 2b. In the display panel 1, the drain of the MOS transistor Tr1 is
The source of the transistor Tr2 and the MOS transistor T
connected to the source of the MOS transistor Tr2
Is the gate of the MOS transistor Tr3, M
The gate of the OS transistor Tr4 and one pole of the capacitor Cs are connected. Further, the other pole side of the capacitor Cs is connected to the source of the MOS transistor Tr4 and the MOS transistor Tr4.
The organic EL element 5 is connected to the drain of the transistor Tr3, and is connected between the drain of the MOS transistor Tr4 and the ground. The output terminal of the start pulse output circuit 2a is connected to the gate of the MOS transistor Tr1, and the output terminal of the video signal processing circuit 3 is
The output terminal of the control pulse output circuit 2b is connected to the source of the transistor Tr1 and the gate of the MOS transistor Tr2.

In this embodiment, a CPU (not shown) that controls the overall operation of the apparatus is required of the organic EL element 5 based on the video data Dv of the pixel corresponding to the organic EL element 5 of the input video signal. A lighting time setting means for setting a lighting time is provided.
Reset in which the pulse width of the reset pulse to be output and the number of times of pulse output are set in accordance with the signal level of the video data Dv in an extinguishing time period from the extinguishment to the maximum possible lighting time Tm of the organic EL element 5 in one field A pulse condition setting means is provided.

The operation of this embodiment having such a configuration will be described. When a video signal to be displayed in the present embodiment is input to the present embodiment, video data Dv of a pixel corresponding to the video signal is input to the source of the MOS transistor Tr1, and the signal level in one field of the input video signal Is detected, and based on the detection level, the lighting time setting means of the CPU sets the maximum lighting time Tm of the organic EL element 5 in one field shown in FIG.
As shown in FIG. 3B, a lighting time Td required for displaying an image with an optimum visual feeling is set according to the signal level of the input video signal. At the same time, according to the signal level of the input video signal, as shown in FIG.
In an extinguishing time zone Tr from the extinguishing of the L element 5 to the maximum possible lighting time Tm, the pulse width of the reset pulse output from the control pulse output circuit 2b and the number of times of outputting the reset pulse are set.

In displaying an image of an input video signal according to the present embodiment, a lighting start pulse Ps from a start pulse output circuit 2a of the pulse control circuit 2 is supplied by a command from the CPU as shown in FIG. Is MOS
The lighting start pulse Ps from the control pulse output circuit 2b of the pulse control circuit 2 is applied to the gate of the MOS transistor Tr2 at the same time as applied to the gate of the transistor Tr1 as shown in FIG. Then, the video data Dv of the pixel of the input video signal whose signal level has been set by the video signal processing circuit 3 is applied to the MOS to be applied to the source.
When the transistor Tr1 is turned on and the MOS transistor Tr1 is turned on, the MOS transistor Tr2 to which the lighting start pulse Ps is applied to the gate is turned on.
When a gate voltage is applied to the gates of the OS transistors Tr3 and Tr4 and a predetermined voltage is applied to one pole of the capacitor Cs, the capacitor Cs is charged for a predetermined time.

Next, the voltage between both electrodes of the capacitor Cs becomes M
When a voltage is applied between the gate and source of the OS transistor Tr4, a drain current _ID flows through the MOS transistor Tr4, and the organic EL element 5 emits light for a preset lighting time Td. As shown in (b), the control pulse output circuit 2b of the pulse control circuit 2
Outputs a turn-off pulse Pe, and is applied to the gate of the MOS transistor Tr2.
Is turned ON, the remaining charge of the organic EL element 5 flows out, and the organic EL element 5 is turned off.

Then, in the turn-off time period Tr from turning off of the organic EL element 5 to reaching the maximum turn-on time Tm, as shown in FIG. The reset pulse Pr having the generated pulse width is output from the control pulse output circuit 2b by the reset pulse condition setting means for the preset number of reset pulse outputs. In the present embodiment, as shown in FIG.
r is output from the control pulse output circuit 2b of the panel control circuit 2 three times and applied to the gate of the MOS transistor Tr2. For this reason, in an extinguishing time period Tr from turning off of the organic EL element 5 to reaching the maximum possible lighting time Tm, for example, extraneous noise is generated in the EL element 5 whose operating characteristics tend to fluctuate due to a change in ambient temperature. Even if an induced charge is generated in the EL element 5 through the active element circuit due to a change in external atmosphere such as intrusion into the active element circuit, the induced charge is reduced by applying the reset pulse Pr to the gate of the MOS transistor Tr2. All are erased and the organic EL element 5 is completely reset. Therefore, the writing of the video data Dv of the pixel of the input video signal to the organic EL element 5 in the next field is accurately performed, and it is possible to completely prevent the deterioration of the display image quality due to the change of the external atmosphere. become.

As described above, according to the present embodiment, the organic EL element 5 is turned on for the lighting time Td by the lighting start pulse Ps from the panel control circuit 2, and is turned on by the light-off pulse Pe from the panel control circuit 2. Although the EL element 5 is turned off, the reset pulse condition setting means is provided in the turn-off time period Tr from turning off the organic EL element 5 to writing the video data Dv of the pixel of the input video signal to the organic EL element 5 in the next field. Reset pulse Pr having a pulse width preset according to the signal level of the input video signal.
Is input to the active element circuit for a preset number of times, and the organic EL element 5 is reset a set number of times. Therefore, in the turn-off time period Tr from turning off the organic EL element 5 to lighting in the next field, all the induced charges generated in the organic EL 5 based on the change of the external atmosphere are lost when the next field is turned on, and the next field is turned off. Since the writing of the video data Dv of the pixels to the organic EL element 5 in the above is performed with high accuracy to the organic EL element 5 in a completely reset state, the deterioration of the display image quality due to the change of the external atmosphere is reduced. Generation can be completely prevented.

[0022]

According to the first aspect of the present invention, a plurality of EL light emitting elements respectively arranged at intersections of scanning lines and drive lines arranged in a matrix are arranged corresponding to each light emitting element. The active element circuit is driven to emit light, and these EL light emitting elements perform image display corresponding to the input video signal. The lighting time setting means causes the EL light emitting element to display an image of the input video signal. The required lighting time is set within the maximum possible lighting time of the EL light emitting element, a light emitting pulse is input to the active element circuit by the light emitting element lighting means, and the lighting time is set by the lighting time setting means. , The EL light emitting element is set to the light emitting state, and at the end of the lighting time, the light emitting element extinguishing means inputs an extinguishing pulse to the active element circuit. L-emitting element is turned off. further,
According to the present invention, in an extinguishing time period from the extinguishing of the EL light emitting element to the maximum possible lighting time, the reset means inputs a reset pulse to the active element circuit at least once, and resets the EL element through the active element circuit. Therefore, even if an induced charge is generated in the EL element due to a change in the external atmosphere, the induced charge is removed and lost by resetting the reset means, and the E field in the next field is reduced.
Writing to the L element is performed with high accuracy, and high-quality image display can always be performed.

According to the second aspect of the invention, in addition to the effect of the first aspect, the reset pulse condition including the pulse width of the reset pulse applied to the EL light emitting element is set by the reset pulse condition setting means. Therefore, the reset operation by the reset means can be performed more accurately.

According to the third aspect of the present invention, a plurality of EL light emitting elements respectively arranged at intersections of scanning lines and drive lines arranged in a matrix are arranged corresponding to the respective light emitting elements. Light emission is driven by the active element circuit, and an image corresponding to the input video signal is displayed by these EL elements. In the lighting time setting step, the EL element is required to display an image of the input video signal. The lighting time is set within the maximum lighting time of the EL light emitting element, a light emitting pulse is input to the active element circuit in the light emitting element lighting step, and during the lighting time set in the lighting time setting step, the EL light emitting element is turned on. Is set to a light emitting state, and in the light emitting element extinguishing step, at the end of the lighting time, an extinguishing pulse is input to the active element circuit, and the EL light emitting element is turned off. There is turned off. Further, in the present invention, in the reset step, a reset pulse is input to the active element circuit at least once during a turn-off time period from turning off of the EL light-emitting element to a maximum lighting time, and the EL element is turned on through the active element circuit. Will be reset,
Even if an induced charge is generated in the EL element due to a change in the external atmosphere, the induced charge flows out and disappears due to the reset in the reset step, and writing to the EL element in the next field is performed with high accuracy, and the quality is always high. Can be displayed.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a configuration of a main part of an embodiment of the present invention relating to an image display device.

FIG. 2 is an explanatory diagram showing an operation of the embodiment in comparison with a conventional operation.

[Explanation of symbols]

1. Display panel 2. Panel control circuit 3. Video signal processing circuit 5. Organic EL element, Tr1 to Tr4
.MOS transistor, Cs .. capacitor, Ps ..
Lighting start pulse, Pe ··· Light off pulse, Pr ··· Reset pulse, Tm ··· Maximum lighting time, Td ·· Lighting time.

Claims (3)

[Claims] 1. A plurality of EL light emitting elements arranged at intersections of scanning lines and drive lines arranged in a matrix are driven to emit light by active element circuits arranged corresponding to the respective light emitting elements. An image display device for displaying an image corresponding to an input video signal by using these EL light emitting elements, wherein a lighting time required for displaying an image of the input video signal with respect to the EL light emitting element is set by the EL light emitting element. Lighting time setting means for setting the lighting time within the maximum lighting possible time, and inputting a light emission pulse to the active element circuit, so that the EL light emitting element emits light during the lighting time set by the lighting time setting means. A light-emitting element lighting means for setting the EL element by inputting a light-off pulse to the active element circuit at the end of the lighting time. A light-emitting element extinguishing means for extinguishing the light-emitting element; and a reset pulse is input to the active element circuit at least once during an extinguishing time period from the extinguishing of the EL light-emitting element by the light-emitting element extinguishing means to the maximum lightable time. A reset unit for resetting the EL element via the active element circuit. 2. The image display device according to claim 1,
An image display device, further comprising reset pulse condition setting means for setting a reset pulse condition including a pulse width of a reset pulse applied to the EL light emitting element. 3. A plurality of EL light emitting elements respectively arranged at intersections of scanning lines and drive lines arranged in a matrix are driven to emit light by active element circuits arranged corresponding to the respective light emitting elements. A driving method of an image display device that displays an image corresponding to an input video signal by using the EL light emitting element, wherein the lighting time required for displaying an image of the input video signal is determined for the EL light emitting element; A lighting time setting step of setting the lighting time within the maximum lighting time of the EL light emitting element; and inputting a light emission pulse to the active element circuit, so that the EL light emitting element is set for the lighting time set by the lighting time setting means. A light emitting element lighting step of setting a light emitting state; and, at the end of the lighting time, inputting a light-off pulse to the active element circuit. A light emitting element extinguishing step for extinguishing the EL light emitting element, and a reset pulse is supplied to the active element circuit during an extinguishing time period from the extinguishing of the EL light emitting element by the light emitting element extinguishing step to the maximum possible lighting time. A resetting step of resetting the EL element via the active element circuit by inputting at least once.