KR100200134B1 - Pixel correction apparatus by analog type for projector - Google Patents

Abstract

The present invention relates to a projector in which a pixel correction operation for correcting a manufacturing error of the AMA member is simply performed in an analog manner by a comparator composed of a single OP amplifier in a projector that reproduces an image of a projection type image through an AMA member. An analog pixel correction device is provided.

Accordingly, in the present invention, the image correction data from the correction data memory 24 is temporarily stored through the data storage unit 26 by the address and the control signal from the address generator 22, and then the AMA device 30 In a pixel correction apparatus of a projector output as correction data for an input image signal for correcting manufacturing errors, digital conversion of image correction data through the data storage unit 26 is sequentially performed so as to be synchronized with a synchronization signal according to the image signal. And an analog pixel correction unit 28 which sequentially receives the image signal in the analog state and the image correction signal through the data inverse conversion unit 27 and matches the pixels by an analog method. Characterized in that configured.

Description

Pixel correction device by analog method of projector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pixel correction device using an analog method of a projector. More particularly, the present invention relates to a pixel driving device for driving an AMA member in a projection type projector having a plurality of AMA (Actuated Mirror Array) members corresponding to pixels. The present invention relates to an analog pixel correction device of a projector in which pixel correction for correcting a manufacturing error of the AMA member is performed in an analog manner.

Currently, a projector as a projection type image display device employing an AMA member or device has been proposed and is being developed for practical use. The AMA device is for driving a plurality of pixels provided on a screen of 640 x 480 dimensions, for example. A plurality of pixel driving elements composed of, for example, MOS transistors corresponding to the number of pixels are formed in an active matrix substrate arranged in a matrix array form, and images are formed on the active matrix substrate corresponding to each pixel and provided from each pixel driving element. The actuator is inclinedly deformed in accordance with the signal voltage to modulate incident light (ie, optical path control).

According to a projector using such an AMA device, the AMA device comprises an active matrix substrate (i.e., an AMA panel) and a plurality of actuators formed on the AMA panel and corresponding to the number of pixels reflecting incident light.

In the AMA panel, for example, if a screen of 640 x 480 is assumed, a plurality of pixel driving elements arranged in a matrix array form corresponding to the total number of pixels constituting the screen are provided. To reproduce an image by tilting the actuator corresponding to each pixel driver in response to the pixel driver in accordance with the image signal voltage, controlling the pixel driver in the form of a matrix array based on the image signal voltage corresponding to each pixel. A row / column driver circuit portion is provided for driving the pixel driver for driving odd pixels and even pixels in the row / column direction of the AMA panel.

Further, in the case of driving the pixel driving element set in the AMA panel by the row / column driving circuit section, the tolerance due to the flatness or the nonuniformity of the flatness accompanying the manufacture of the actuator formed on the AMA panel is caused. In order to eliminate nonuniformity of pixel driving, correction data for the original error in manufacturing including the overall flatness of the actuator formed on the corresponding AMA panel is calculated and added (or subtracted) to the image signal voltage when the AMA panel is driven. It is provided in the row / column driving circuit unit in such a manner that correction for the original error in manufacturing the AMA panel is performed.

FIG. 1 is a block diagram illustrating a pixel compensator of a general projector. In FIG. 2, reference numeral 2 denotes a synchronization separator for separating a horizontal synchronization signal, a vertical synchronization signal, and a color subcarrier (fsc; approximately 3.58 MHz) from an image signal. 4 denotes an address generator which generates an address signal and a control signal by combining the vertical synchronization signal separated by the synchronization separation unit 2, the horizontal synchronization signal, and the clock signal 4fsc by the color subcarrier frequency. For example, assuming a screen of 640 x 480, the total number of pixels of the screen is 307,200, and the address required for driving the pixels of the whole is 2 ⁰ -2 ¹⁸ .

Further, reference numeral 6 denotes correction data made of, for example, a nonvolatile semiconductor memory (ROM) in which an error correction value for the flatness of each actuator provided correspondingly to the pixel driving elements constituting the AMA device 10 is stored as image correction data. The image correction data stored in the correction data memory 6 indicates the memory and calculates the image correction data for correcting the error of the flatness at the time of manufacture previously measured by the AMA device 10 to form a ROM table. And correction data for a corresponding pixel are sequentially output based on the address and control signal output from the address generator 4.

Reference numeral 8 denotes that when the correction data in the pixel unit corresponding to the address generated by the address generator 4 is read out from the correction data memory 6, the read image correction data is temporarily stored and then rewritten. Represents a data storage section made of, for example, SRAM for output.

In addition, reference numeral 10 denotes an analog-to-digital converter (ADC) for digitally converting a predetermined video signal, and 12 denotes an analog-digital converter, which is provided through the data storage unit 8 corresponding to the digitally converted video data and the video data. A digital pixel correction unit which applies the image correction data to each pixel by matching the image correction data in a pixel matching method and outputs the corrected pixel driving data, and 14 denotes an AMA device (AMA device) by analog converting the pixel corrected image data. 16) shows a digital-analog converter (DAC) output as an image drive signal.

The pixel correction apparatus of the projector having such a component reads the image correction data in pixel units at positions corresponding to the addresses sequentially provided by the address generator 4 from the correction data memory 6, and sequentially stores the data storage unit ( 8) and then temporarily applied to the digital pixel correction unit 12, the digital pixel correction unit 12 in the data storage unit 8 for the image signal digitally converted through the ADC (10) As the image driving data provided are matched on a pixel-by-pixel basis and the corrected pixel driving data is output, the analog driving pixel driving signal can be supplied to the AMA device 16 through the DAC 14.

Accordingly, the pixel error caused by the manufacturing error of each AMA element included in the AMA device 16 can be corrected accurately.

However, in the pixel correction device of such a projector, after digitally converting the input image signal through the ADC 10, the digital image correction data provided from the data storage unit 8 is digitally matched by pixel matching. Since the pixel correction can be performed in such a manner, multi-stage data processing is required, and the digital pixel correction unit 12 is composed of a plurality of logic gates, for example, to input and output 8-bit image data and 8-bit image correction data. Since the digital line to be output should be provided, the area of the overall PCB substrate is increased, there is a disadvantage that it acts as a major factor in the cost increase for providing a plurality of circuit elements or circuit chips.

Accordingly, the present invention has been made in view of the above circumstances, and in the projector which reproduces the projection type image through the AMA member, a compensator in which a pixel correction operation for correcting a manufacturing error of the AMA member is performed by a single OP amplifier It is an object of the present invention to provide a pixel correction device using an analog method of a projector so that the analog method can be easily achieved.

According to the analog pixel correction apparatus of the projector according to the present invention for achieving the above object, the image correction data from the correction data memory is temporarily stored through the data storage unit by the address and the control signal from the address generator. A pixel correction apparatus of a projector outputted as correction data for an input image signal for correcting a manufacturing error of an AMA device, wherein the image correction data through the data storage unit is sequentially digitally synchronized with a synchronization signal according to the image signal. A pixel correction by the analog method of the projector comprising a data inverse conversion unit for converting and an analog pixel correction unit for sequentially receiving the image signal in the analog state and the image correction signal through the data inverse conversion unit and matching the pixels by an analog method. Provide the device.

According to the present invention configured as described above, in the projection type projector employing the AMA member, the image correction data for correcting the manufacturing error of the AMA member and the image signal to be reproduced are analogized through a single comparator (OP amplifier). Pixel matching is performed to correct the pixels of the video signal.

1 is a block diagram showing a pixel correction apparatus of a general projector;

2 is a circuit diagram illustrating a pixel compensator using an analog method of a projector according to the present invention.

Explanation of symbols on the main parts of the drawings

20: synchronous separator, 22: address generator,

24: correction data memory (ROM), 26: data storage unit (SRAM),

27: DAC, 28: Analog Pixel Compensation Government,

30: AMA device, 32: comparator (OP amplifier).

Hereinafter, the present invention configured as described above will be described in detail with reference to the accompanying drawings.

That is, Fig. 2 is a circuit configuration diagram showing an analog pixel correction device of a projector according to the present invention. In the device of the present invention, reference numeral 20 denotes a vertical synchronization signal, a horizontal synchronization signal, and a color sub-frame from an image signal to be reproduced. A synchronization separator for separating a carrier frequency signal is shown, and 22 denotes an address generator for generating an address and a control signal by a clock signal generated by the separated vertical / horizontal synchronization signal and the color subcarrier frequency signal.

Further, reference numeral 24 denotes image correction data corresponding to the pixel of the video signal of the video signal to be reproduced, and sequentially corrects the image by the address from the address generator 22. A correction data memory in which data is read is shown, and 26 denotes a data storage unit for temporarily storing image correction data sequentially read out from the correction data memory 24 by the control signal from the address generator 22.

Reference numeral 27 denotes a DAC for synchronously analog-converting image correction data temporarily stored and sequentially output through the data storage unit 26 to the video signal to be reproduced.

Reference numeral 28 denotes the AMA device 30 by sequentially receiving the image signal V _A and the image correction signal V _B analog-converted by the DAC 27. An analog pixel correction unit for correcting an error generated during manufacturing by an analog method, wherein the image signal V _A through the resistor R1 and the image correction signal V through the resistor R2 are applied to the non-inverting terminal +. _B ) is input, and the comparator 32 receives the output signal V ₀ divided by the voltage divider resistors R3 and R4 through its inverting terminal (-).

Here, the signal (V ₋ ) applied to the non-inverting terminal (−) side of the comparator 28 is represented by 1/2 V ₀ by the voltage divider R 3 and R 4, so that V ₀ = 2 V ₋ , the ratio Since the signal (V ₊ ) applied to the inverting terminal (+) side is V _A + V _B / 2, eventually V ₀ = 2 (V _A + V _B / 2) = V _A + V _B. Accordingly, pixel correction is possible by pixel matching between the image signal V _A and the image correction signal V _B through the comparator 32.

Next, the operation of the present invention made as described above will be described in detail with reference to FIG.

First, when the synchronization separator 20 separates the vertical / horizontal synchronization signal and the color subcarrier frequency signal of the video signal V _A to be reproduced, the address generator 22 separates the vertical / horizontal synchronization signal. And a control signal generated in synchronization with a clock signal generated by the color subcarrier frequency signal, and the correction data memory 24 sequentially stores the image correction data stored in accordance with the address from the address generator 22. On the other hand, the image correction data read sequentially is temporarily stored through the data storage unit 26.

At this time, the DAC 27 converts the image correction data temporarily stored by the data storage unit 26 to the image signal V _A synchronously and analogizes the comparator of the analog pixel correction unit 28. 32 outputs the image signal V _A and the image correction signal V _B through the non-inverting terminal (+) and is divided by the voltage dividing resistors R3 and R4 through the inverting terminal (-). The signal V ₀ is input again.

Accordingly, the comparator 32 matches the image signal V _A and the image correction signal V _B to generate the output signal V ₀ in the pixel-corrected state, and thus the AMA device 30 as an image driving signal. By being applied to, it is possible to normally correct the pixel error appearing in the manufacturing of the AMA device 30.

According to the present invention made as described above, it is possible to perform the pixel correction for the manufacturing error of the AMA member in the analog method in the projector employing the AMA member, so that not only multi-stage data processing is required, The area of the PCB board occupied by the circuit chip is greatly reduced, and manufacturing costs can be greatly reduced.

Claims (2)

The image correction data from the correction data memory 24 is temporarily stored through the data storage unit 26 by the address and the control signal from the address generator 22, and then the manufacturing error of the AMA device 30 is corrected. In the pixel correction device of the projector output as correction data for the input image signal for A data inverse converter 27 for converting image correction data through the data storage unit 26 sequentially to be synchronized with a synchronization signal according to an image signal; An analog pixel correction unit 28 which sequentially receives the image signal V _{A in} the analog state and the image correction signal V _B through the data inverse conversion unit 27, and matches pixels by an analog method; Pixel correction device according to the analog method of the projector, characterized in that the configuration. 2. The analog pixel correction unit 28 receives the image signal V _A and the image correction signal V _B through the first input terminal +, and the second input terminal And a comparator (32) receiving the output signal (V ₀ ) divided by the voltage divider resistors (R3, R4) through-).