JP2001324955A - Brightness adjusting device and electric field discharge type display element - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stabilize brightness by preventing variation as much as possible in the display brightness caused by variation in an anode current, in a display element. SOLUTION: An anode current value detecting part 11 detects an average current value of the anode current for a period of time T. A display data amount detecting part 14 counts a display data amount in the period of time T. A reference current value output part 15 generates and outputs a reference value (reference current value) of the anode current from the counted display data amount. In the comparison part 17, the average current value is compared with the reference current value, and when they do not coincide with each other, a gate voltage adjusting part 18 adjusts a gate voltage to vary the anode current. The average anode current value is varied and is made equal to the reference value. An FED can be driven with the anode current made to a preset reference constant current. Phosphor brightness of the anode is kept constant irrespective of variation in the ambient temperature.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a brightness adjusting device for adjusting the light emission brightness of a display element.

[0002]

2. Description of the Related Art FIG. 4 shows a field emission display (hereinafter referred to as FE).
FIG. 2 is a cross-sectional view showing an example of a field emission device (hereinafter abbreviated as FEC) used as an electron emission source in D). On the inner surface of the insulating cathode substrate 1, a cathode electrode 2 made of a conductive material and a cathode wiring 3 are formed in a predetermined pattern. A resistance layer 4 made of α-Si or the like is formed thereon. An insulating layer 5 is formed on the resistance layer 4, and a gate electrode 6 is further formed thereon. A through hole 7 is formed in the insulating layer 5 and the gate electrode 6 at positions corresponding to the cathode electrode 2, and the resistive layer 4 is exposed. A triangular pyramid-shaped emitter 8 is formed on the resistive layer 4 exposed at the bottom of the through hole 7.
In the present example, the cathode electrode 2 and the gate 6 constitute a matrix.

Although not shown in FIG. 4, an anode substrate is provided above the cathode substrate 1 on which the FEC is formed, facing the same at a predetermined interval. On the inner surface of the anode substrate facing the FEC, a solid light emitting portion including an anode and a phosphor is formed. A spacer member is provided between the outer peripheral portions on the inner surface sides of the cathode substrate 1 and the anode substrate facing each other, and forms an envelope of the FED. The inside of the envelope is evacuated and held in a high vacuum atmosphere.

In driving the FED, a predetermined potential is always applied to the anode, and a display signal is applied to a drive circuit to drive the FEC. That is, one of the cathode electrode 2 and the gate electrode 6 of the FEC is scanned, and a display signal is supplied to the other in synchronization with the scanning. Electrons are emitted from the emitters 8 at the intersections of the selected matrix, and strike the opposing position of the anode to emit light at that portion.

[0005] This is a type in which electrons are emitted to an anode having a phosphor in an envelope in which a high-vacuum atmosphere is formed to emit light. In a light emitting element in which a resistance (resistance layer 4) for adjusting a potential is provided, the anode current may fluctuate remarkably due to a change in the ambient temperature, which may cause a problem that the light emission luminance appears.

[0006] Such a change in the anode current is due to the fact that the resistance value of the voltage adjusting resistor (resistor layer 4) provided in the electron emitting portion (emitter 8 in the FED) changes at ambient temperature. Therefore, a temperature compensating device having a device for removing such a cause has been proposed.

This is a temperature compensation device of the monitor resistance value detection type. This device has a monitor resistance pattern on a cathode substrate in an envelope of the FED as a means for detecting an ambient temperature. This monitor resistance pattern is α
-Si, and has a characteristic that the resistance value of s changes with temperature. The change from the reference temperature is obtained by detecting the change in the resistance value of the monitor resistance pattern by an external circuit. Based on this, the gate voltage is automatically adjusted to obtain a constant current characteristic of the anode voltage. In addition, there has been a device such as an FED in which a temperature sensor is provided outside a display element.

[0008]

However, according to the temperature compensation device of the monitor resistance detection type, the resistance value of the monitor resistance varies from element to element, and adjustment is required for each display element (each FED). Therefore, it was difficult to realize constant and stable temperature compensation for all products. In addition, in the case where a temperature sensor is provided outside the display element such as an FED, the temperature inside the display element cannot be detected, and since the temperature sensor is outside, it is easily affected by some heat source other than the ambient temperature. There was a problem.

SUMMARY OF THE INVENTION It is an object of the present invention to stabilize the luminance of a display element by preventing a change in display luminance caused by a change in anode current as much as possible.

[0010]

According to a first aspect of the present invention, there is provided a brightness adjusting device including a first electrode provided with a display surface and a resistor (resistance layer) for adjusting a potential, according to display data. An average current value for detecting an average current value of a first electrode within a predetermined time range in a brightness adjustment device for adjusting the brightness of a display device including a second electrode (emitter 8) from which electrons are emitted. Unit (Anode current value detection unit 11)
A display data amount detector (14) for counting a total display data amount given to the second electrode within a predetermined time range;
A reference current value output section (15) for providing a reference current value of the first electrode with respect to the display data amount, and an average current value from the average current value detection section and a reference current value from the reference current value output section are compared. A comparing section (17), and a voltage adjusting section (gate voltage adjusting section 18) for adjusting a voltage when display data is given to the second electrode according to a result of the comparison in the comparing section.
And

According to a second aspect of the present invention, there is provided a brightness adjusting device comprising: an anode having a phosphor; a resistor (resistance layer) for adjusting a potential; In a brightness adjusting device for adjusting the display brightness of a field emission display device having a gate (gate electrode 6) for controlling electron emission and having a field emission element driven according to display data, a predetermined time range An average current value detecting unit (anode current value detecting unit 11) for detecting an average current value of the anode within the display unit; and a display data amount detecting unit (counting the total display data amount given to the field emission element within a predetermined time range). 14), a reference current value output unit (15) for giving a reference current value of the anode to the display data amount, an average current value from the average current value detection unit, and a reference current value from the reference current value output unit (17), and a voltage adjustment unit (gate voltage adjustment unit 18) that adjusts the gate voltage when display data is given to the field emission element according to the comparison result in the comparison unit. ing.

According to a third aspect of the present invention, there is provided a field emission display device, comprising: an anode having a phosphor; and an emitter (8) provided with a resistor (resistance layer 4) for adjusting a potential and emitting electrons. Gate to control electron emission from emitter
(Gate electrode 6), a field emission device driven according to display data, an average current value detection unit (anode current value detection unit) for detecting an average current value of the anode within a predetermined time range, A display data amount detection unit (14) for counting a total display data amount given to the field emission element within a predetermined time range, a reference current value output unit (15) for giving a reference current value of the anode to the display data amount, A comparing unit (17) for comparing an average current value from the average current value detection unit with a reference current value from the reference current value output unit; and a gate (gate electrode 6) when display data is given to the field emission device. )
And a voltage adjustment unit 18) that adjusts the voltage according to the result of the comparison in the comparison unit.

[0013]

FIG. 1 shows an example of an embodiment of the present invention.
This will be described with reference to FIG. This example relates to an FED having a brightness adjusting device. The structure of FED itself is
This is basically the same as that shown in FIG. 4, and a description thereof will be omitted.

FIG. 1 is a block diagram showing the structure of the FED 10 (graphic display) and the brightness adjusting device of this embodiment. An anode current value detection unit 11 is connected to the anode side of the FED 10, and can detect an average current value of the anode current in the time range T.

Here, the time range T can be arbitrarily determined. For example, the time (one frame) during which one display screen is driven by the drive display of the present apparatus may be the time range T. In the FED of this example, in the operation of driving the FEC in a matrix and displaying the anode, as shown in FIG. 2, the solid anode has n lines (1, 2,...).
It is considered that the driving is divided into n), and the display data is usually different for each line driving. Therefore, usually, the value of the current flowing through the anode is also different for each line driving. This may be detected by the anode current value detector 11 to obtain an average value. More specifically, an average value may be obtained by calculating the integral of the anode current value within one frame by means such as a low-pass filter.

A driver section 12 is connected to the cathode side of the FED, and a display data output section 13 is connected to the driver section 12. In driving the FED, one of the cathode electrode 2 and the gate electrode 6 is scanned, a display signal is applied to the other in synchronization with the scanning, and electrons are emitted from the emitter 8 at a desired position.

The display data output unit 13 is connected to a display data amount detection unit 14 for counting the display data amount in the time range T. The time range T may be one frame described above. A reference current value output unit 15 is connected to the display data amount detection unit 14. The display data amount detection unit 14 sends the detected display data amount to the reference current value output unit 15. The reference current value output unit 15 generates and outputs a reference value (reference current value) of the anode current by, for example, inputting a signal obtained by adding a dimming weight to the amount of display data detected by the display data amount detection unit 14. I do. The processing related to the dimming weight may be performed by the reference current value output unit 15 or may be performed by the display data amount detection unit 14. As a method of generating the reference current value, the calculation may be performed by applying the amount of display data to an arithmetic expression held in advance, or a table representing a correspondence relationship between the amount of display data and the reference current value may be provided. You may. As if you had a table,
In the case of reading the reference current value corresponding to the display data amount without performing the calculation, the ROM 16
May be connected to the reference current value output unit 15.

The anode current value detection section 11 and the reference current value output section 15 are connected to a comparison section 17. Comparison section 17
Compares the average current value from the anode current value detection unit 11 with the reference current value from the reference current value output unit 15.

The driver section 12 includes a gate voltage adjusting section 18
Is connected. The comparing unit 17 is connected to the gate voltage adjusting unit 18. The comparison unit 17 compares the average current value of the anode in the time range T (one frame in this example) with a reference current value corresponding to the data amount, and sets the gate so that the average current value becomes closer to the reference current value. A signal is sent to the voltage adjusting unit 18. Upon receiving this signal, the gate voltage adjusting unit 18 automatically adjusts the gate voltage of the FEC.

By adjusting the gate voltage, the average anode current value fluctuates and becomes equal to the reference value. Thus, the FED can be driven with the anode current being a constant current that is a predetermined reference. Irrespective of the fluctuation of the ambient temperature, the brightness of the phosphor of the anode is kept constant.

FIG. 3 is a flowchart showing the control of the present embodiment described with the above configuration. During the operation in which the FED of this example is driven and emits light, the control operation according to this flowchart is always executed. First, the anode current value detection unit 11
Detects the average current value of the anode current in the time range T (S1). The display data amount detector 14 counts the display data amount in the time range T. At this time, the dimming weight is considered (S2). The reference current value output unit generates and outputs a reference value (reference current value) of the anode current from the counted display data amount (S3). The processing related to the weight of dimming may be performed here.

In the comparison section 17, the average current value and the reference current value are compared (S4), and if they match, the anode current is kept constant. If they do not match, the gate voltage adjuster 18 adjusts the gate voltage to change the anode current (S5). As a result, the average anode current value fluctuates and becomes equal to the reference value. Thus, the FED can be driven by setting the anode current to a constant current based on a preset reference. Irrespective of the fluctuation of the ambient temperature, the brightness of the phosphor of the anode is kept constant.

In the example described above, the time range T is 1
Although the frame is exemplified, the control may be performed collectively every several frames, or the control may be performed in a time range of less than one frame, for example, for a predetermined number of lines in one frame.

In the example described above, the control of the flowchart shown in FIG. 3 is always executed during driving and light emission of the FED of the present embodiment. After the control is performed, the control may be performed periodically thereafter.

[0025]

According to the present invention, utilizing the fact that the display data amount is proportional to the anode current value, the average value of the anode current detected at a certain time interval and the display value provided for the display at the time interval are used. The drive is controlled based on the result of comparison with a standard anode current value corresponding to the data amount. Accordingly, it is possible to keep the anode current fluctuation due to a temperature change as well as the anode current fluctuation due to other factors, and to maintain the anode current at a desirable constant value, thereby suppressing the luminance fluctuation. In addition, when this technology is applied to a current emission type light emitting device, since the fluctuation of the anode current is prevented, a decrease in the electron emission capability of the emitter of the field emission device can be prevented. The qualitative is corrected. Therefore, according to the present invention, the aging work which has conventionally been indispensable in the manufacture of the current emission type light emitting device becomes unnecessary.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an example of an embodiment of the present invention.

FIG. 2 is a diagram showing a change in an anode current value within one frame in an example of an embodiment of the present invention.

FIG. 3 is a flowchart illustrating control according to an example of an embodiment of the present invention.

FIG. 4 is a cross-sectional view showing the structure of the FED.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Cathode board, 2 ... Cathode electrode, 3 ... Cathode wiring,
4 ... resistive layer, 5 ... insulating layer, 6 ... gate electrode, 7 ... through hole,
8 Emitter, 10 FED as graphic display, 11 Anode current value detector, 13 Display data output unit, 14 Display data amount detector, 15 Reference current value output unit, 17 Comparison unit, 18 Gate voltage adjustment unit.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Hiroyuki Tanaka 629 Oshiba, Mobara-shi, Chiba Futaba Electronics Co., Ltd. (72) Inventor Katsumi Takayama 629 Oshiba, Mobara-shi, Chiba Futaba Electronics Co., Ltd. (72) Inventor Kazuichi Suzuki 629 Oshiba, Mobara-shi, Chiba Futaba Electronics Co., Ltd. F-term (reference) 5C080 AA18 BB05 DD03 EE28 FF09 JJ02 JJ05 JJ06 JJ07

Claims (3)

[Claims] 1. A display device comprising: a first electrode provided with a display surface; and a second electrode provided with a resistor for adjusting a potential and emitting electrons in accordance with display data. An average current value detection unit that detects an average current value of the first electrode within a predetermined time range, and a display data amount that counts a total display data amount given to the second electrode within a predetermined time range. A detection unit; a reference current value output unit for providing a reference current value of the first electrode with respect to the display data amount; and comparing an average current value from the average current value detection unit with a reference current value from the reference current value output unit. And a voltage adjustment unit that adjusts a voltage when display data is given to the second electrode according to a result of the comparison by the comparison unit. 2. An electric field having an anode having a phosphor, an emitter provided with a resistor for adjusting a potential for emitting electrons, and a gate for controlling electron emission from the emitter, driven in accordance with display data. A brightness adjustment device for adjusting the display brightness of a field emission display device having an emission element, an average current value detection unit for detecting an average current value of the anode within a predetermined time range, and an electric field within a predetermined time range. A display data amount detection unit that counts a total display data amount given to the emission element, a reference current value output unit that provides a reference current value of the anode with respect to the display data amount, and an average current value from the average current value detection unit. A comparing unit for comparing the reference current value from the reference current value output unit with a reference current value; and a gate voltage when display data is given to the field emission element according to the comparison result in the comparing unit. Brightness adjusting device having a voltage adjustment section for adjusting. 3. An anode having a phosphor, an emitter provided with a resistor for adjusting a potential to emit electrons, and a gate for controlling electron emission from the emitter, and driven in accordance with display data. Field emission element, an average current value detection unit for detecting an average current value of the anode within a predetermined time range, and a display data amount detection for counting a total display data amount given to the field emission element within a predetermined time range A reference current value output unit that provides a reference current value of the anode with respect to the display data amount; and a comparison unit that compares an average current value from the average current value detection unit with a reference current value from the reference current value output unit. And a voltage adjusting unit that adjusts a voltage of a gate when display data is given to the field emission element according to a result of the comparison in the comparison unit.