JP2007251723A - Projection type video display apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a projection type video display apparatus in which a trapezoidal distortion correction amount can be prevented from being restricted even when a high-resolution video signal or high-frequency video signal is inputted as an input video signal. <P>SOLUTION: In the projection type video display apparatus which comprises a trapezoidal distortion correction means for correcting trapezoidal distortion generated in a projection video image based on an input video signal, a conversion means is provided for converting a video signal to be corrected by the trapezoidal distortion correction means (scaler 2, trapezoidal distortion correction part 5) so as to reduce the quantity of information thereof. Said conversion means is provided in a frame buffer memory controller 3 and converts RGB24 data of a high-resolution or high-frequency input video signal into YUV422 16-bit data of which the quantity of information is reduced, through color space conversion. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a projection display apparatus such as a liquid crystal projector, and more particularly to its trapezoidal distortion correction function.

  Generally, the liquid crystal projector is installed below or above the screen so that the liquid crystal project body does not hinder the viewer's line of sight or the viewer does not hinder projection from the liquid crystal project body. Therefore, the image displayed on the liquid crystal panel is projected with an inclination with respect to the screen. For example, when projecting from below, the optical path length increases as it goes upward, and the enlargement ratio increases. For this reason, when a rectangular original image is displayed as it is on the liquid crystal panel, the projected image projected onto the screen becomes a trapezoidal shape that is long in the vertical direction and long in the horizontal direction on the upper side, and this is called keystone distortion (keystone distortion). Is. Therefore, usually, the keystone correction (also referred to as keystone correction) is performed on the original image so that the projected image is similar to the original image. Specifically, a corrected image having a trapezoidal shape opposite to the projected image when no correction is performed is created, and this corrected image is displayed on the liquid crystal panel.

As this type of prior art, there is one described in Patent Document 1, for example. In the prior art described in Patent Document 1, a formed image on a liquid crystal panel surface formed based on an input video signal is projected by irradiation light from a light source, and the projected image light is screened through an optical system means. In the liquid crystal display device to be enlarged and displayed, a plurality of distance detection means provided at a plurality of different positions on the front surface of the liquid crystal display device main body, respectively detecting the distance between the liquid crystal display device main body and the screen, A processing circuit for performing processing for forming an image based on the input video signal on the liquid crystal panel surface, comprising a memory for storing pixel data corresponding to the input video signal, and for each line of pixel data in the memory By changing the timing of writing and reading, a video processing circuit capable of thinning out pixel data for each line, and the distance detecting means Based on the detection result, an inclination angle of the liquid crystal display device body with respect to the screen is calculated, and on the basis of the calculation result, the video processing is performed so as to correct the trapezoidal distortion of the projection screen caused by the inclination angle of the liquid crystal display device body. And correction control means for automatically controlling the circuit.
JP 2000-122617 A (G09G 3/36)

  However, in the conventional technology as described above, since pixel data (RGB data) corresponding to the input video signal is processed as it is, if a high-resolution video signal or a high-frequency video signal is input, it is accessed during keystone distortion correction. The bandwidth of the memory to be used becomes a bottleneck, and the amount of trapezoidal distortion correction is limited, and there is a problem that sufficient trapezoidal distortion correction cannot be performed.

  Therefore, the present invention has been made to solve such problems, and even if a high-resolution video signal or a high-frequency video signal is input as an input video signal, the trapezoidal distortion correction amount is limited. It is an object of the present invention to provide a projection display apparatus that can prevent the above-described problem.

  In order to achieve the above-described object, the invention according to claim 1 of the present application provides a projection-type image display device including a trapezoidal distortion correcting unit that corrects a trapezoidal distortion generated in a projected image based on an input image signal. The present invention is characterized by comprising conversion means for converting the video signal to be corrected by the trapezoidal distortion correction means so that the amount of information is reduced.

  The invention according to claim 2 is characterized in that the conversion means converts RGB data of an input video signal having a high resolution and a high frequency into YUV data having a reduced information amount by color space conversion.

  The invention according to claim 3 is characterized in that the converting means converts RGB 24-bit data of an input video signal into YUV 16-bit data.

  According to the invention described in claim 1 of the present application, since the amount of information of the video signal to be corrected by the trapezoidal distortion correcting unit can be reduced by the converting unit, a high-resolution video signal or a high frequency can be used as the input video signal. Even if the video signal is input, it is possible to prevent the trapezoidal distortion correction amount from being limited, and to perform sufficient trapezoidal distortion correction.

  According to the second aspect of the present invention, the color of the RGB data of the input video signal with high resolution and high frequency is converted by color space, and the human eye is more sensitive to changes in brightness than changes in color. By allocating a large amount of information to the luminance information, the amount of information is reduced by converting it into YUV data that can obtain a high compression rate with a small deterioration in image quality, so that deterioration in image quality can be suppressed as much as possible.

  According to the third aspect of the present invention, the amount of information can be efficiently reduced to 2/3 by converting the RGB 24-bit data of the input video signal to YUV 16-bit data.

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

  FIG. 1 is a block diagram showing a main configuration of a liquid crystal projector as a projection display apparatus according to an embodiment of the present invention.

  In the present embodiment, an input port 1 that captures an input video signal, a scaler 2 that mainly performs resolution conversion by vertical angle conversion and vertical keystone distortion correction, and a frame buffer memory controller that controls access to the frame buffer memory 3, an external memory 4 using DDR (Double Data Rate) SDRAM (Synchronous Dynamic Random Access Memory) or the like as the frame buffer memory, a trapezoidal distortion correction unit 5 for correcting a trapezoidal distortion in the horizontal direction, and a trapezoidal distortion correction. The display port 6 outputs the output video signal to a driver for driving a liquid crystal panel (not shown).

  In the present embodiment, the frame buffer memory controller 3 incorporates a color space conversion (CSC) function for converting RGB data into YUV data by color space conversion. A conversion means is realized. Incidentally, since it is necessary to return to RGB data when driving a liquid crystal panel (not shown), a CSC for color space converting YUV data to RGB data is incorporated in the frame buffer memory controller 3 or the display port 6 or the like contrary to the above. . Note that the color space conversion can be easily performed using a known conversion formula.

  The scaler 2, the frame buffer memory controller 3, the trapezoidal distortion correction unit 5, and the like are provided with a line memory used for image data processing. Further, the frame buffer memory controller 3 converts RGB 24-bit data into YUV422 16-bit data that reduces the amount of information or YUV444 24-bit that does not change the amount of information according to the resolution and frequency of the input video signal. A YUV422 mode register capable of setting whether to convert to data is provided.

  The input video signal is input via the input port 1 and stored in the external memory 4 through the frame buffer memory controller 3. Then, based on the image data of the video signal stored in the external memory 4, the scaler 2 performs resolution conversion by image angle conversion and vertical keystone distortion correction. The image data processed by the scaler 4 is stored again in the external memory 4 via the frame buffer memory controller 3.

  Since the frame buffer memory controller 3 has the line memory as described above, it can hold data for each pixel. Since the data for one pixel consists of 8-bit data for each of RGB, the total data amount is 24 bits (3 bytes). If this is stored in the external memory 4 as it is, for example, in the case of a 1080I (High Definition TeleVision) 1080I signal (resolution of 1920 × 1080 with an interlaced scan method with 1080 effective scanning lines), 1920 × 1080 pixels × 3 bytes = 62020800 It becomes a byte. The frame buffer memory controller 3 exchanges this data amount. In the case of an XGA (eXtended Graphics Array) signal with a resolution of 1024 × 768, this is 1024 × 768 pixels × 3 bytes = 2359296 bytes. Simply increasing the signal resolution increases the amount of information that must be processed. Further, the higher the frequency, the faster the information processing speed is, depending on the input signal.

  On the other hand, the bandwidth that can process data exchange is limited, and the bandwidth may be exceeded depending on a certain resolution and frequency. If it exceeds, processing cannot be performed, signal processing cannot catch up, and symptoms such as noise occur.

  When executing the trapezoidal distortion correction, the image data that has entered the scaler 2 is first compressed in the vertical direction in accordance with the keystone distortion correction amount (keystone amount) based on the tilt angle of the liquid crystal projector body detected in advance. . As described above, the scaler 2 has a line memory, interpolates and compresses input image data in the vertical direction, and writes the compressed data to the external memory 4 via the frame buffer memory controller 3. Further, the trapezoidal distortion correction unit 5 performs horizontal keystone distortion correction by applying compression (thinning) for each line. Image data that has been subjected to trapezoidal distortion correction in the horizontal direction in addition to the vertical direction is output to a driver of a liquid crystal panel (not shown) via the display port 6.

  For example, the clock of the trapezoidal distortion correction unit 5 (in this case, the display clock; DCLK) is 40 MHz. The clock of the external memory 4 (in this case, the memory clock; MCLK) is 80 MHz. Since DLCK is fixed, if trapezoidal distortion correction is applied, the line to be compressed must display an image in a short time, and thus the number of times the external memory 4 is accessed increases. The external memory 4 simultaneously uses other devices such as a CPU and a deinterlacer (converter from an interlace scan image to a progressive scan image) (not shown), and the number of times that the trapezoidal distortion correction unit 5 can access is limited. Come.

  At this time, with 1080I having a large amount of data accessed to the external memory 4, the processable time is not in time, so that only a small amount of trapezoidal distortion correction can be performed.

  Therefore, in this embodiment, in order to reduce the amount of information, 24-bit RGB data is converted to 16-bit YUV422 data by the above-described color space conversion function of the frame buffer memory controller 3. Therefore, the above-mentioned data of 1920 × 1080 pixels × 3 bytes = 6220800 bytes becomes 1980 × 1080 pixels × 2 bytes = 4147200 bytes, which is reduced to 2/3. As a result, the bandwidth (number of accesses) of the external memory 4 can be reduced and the trapezoidal distortion correction amount can be increased.

  FIG. 2 is a flowchart showing the above operation more specifically. When an input video signal enters the input port 1 (step S1), the frame buffer memory controller 3 first sets the above-described YUV422 mode register to true. It is checked whether or not (step S2).

  If the YUV422 mode register is true, the RGB 24-bit data of the input video signal (for example, 1080I) that requires a reduction in the amount of information is converted into 16-bit YUV422 data by the color space conversion function of the frame buffer memory controller 3, and the external Write to the memory 4 (Y in step S2 → step S3).

  Next, the scaler 2 reads the data from the external memory 4, interpolates and compresses the image in the vertical direction according to the keystone amount (trapezoidal distortion correction amount) detected in advance, and writes it to the external memory 4 (step S4). . Further, the trapezoidal distortion correction unit 5 reads out the data from the external memory 4 and interpolates and compresses the image in the horizontal direction according to the keystone amount (trapezoidal distortion correction amount) detected in advance (step S5). Then, the YUV data is converted into RGB data by the color space conversion function in the frame buffer memory controller 3 or the display port 6 and the like, and is supplied to the driver of the liquid crystal panel (not shown) from the output port 6 to drive the liquid crystal panel. (Step S6) An image (inverted trapezoidal shape image) corrected for trapezoidal distortion is displayed on the liquid crystal panel, and a projected image without trapezoidal distortion is displayed on the screen.

  On the other hand, if the YUV422 mode register of the frame buffer memory controller 3 is not true in step S2, RGB 24-bit data of the input video signal (for example, XGA) that does not need to reduce the information amount is converted to the color space of the frame buffer memory controller 3. It is converted into 24-bit data of YUV444 by the function and written in the external memory 4 (Y in step S2 → step S3). Thereafter, the same processing as described above is performed (steps S4 to S6).

  As described above, according to the present embodiment, the color space conversion function of the frame buffer memory controller 3 can reduce the amount of information of the video signal to be corrected for trapezoidal distortion. Even if a signal or a high-frequency video signal is input, it is possible to prevent the trapezoidal distortion correction amount from being limited, and to perform sufficient trapezoidal distortion correction.

  In addition, the RGB data of high-resolution and high-frequency input video signals is color space converted, and the human eye uses a property that is more sensitive to changes in brightness than changes in color. Since the amount of information is reduced by converting to YUV data that can obtain a high compression rate with little deterioration in image quality by assigning it, deterioration in image quality can be suppressed as much as possible.

  Further, by converting RGB 24-bit data of the input video signal into 16-bit data of YUV422, the amount of information can be efficiently reduced to 2/3.

  In the above embodiment, a liquid crystal projector using a liquid crystal panel is shown as the projection display apparatus. However, the present invention can also be applied to a projection display apparatus having another image light generation system. That is, the present invention can be applied not only to the front projection type but also to the rear projection type image display device. The present invention can also be applied to a projector of a DLP (Digital Light Processing; registered trademark of Texas Instruments (TI)) system.

The block diagram which shows the principal part structure which concerns on one Embodiment of this invention of the liquid-crystal projector as a projection type video display apparatus. The flowchart which shows the operation example.

Explanation of symbols

1 input port 2 scaler 3 frame buffer memory controller 4 external memory 5 trapezoidal distortion correction unit 6 display port

Claims (3)

In a projection display apparatus comprising a trapezoidal distortion correcting means for correcting trapezoidal distortion generated in a projected video based on an input video signal,
A projection-type image display apparatus comprising conversion means for converting an image signal to be corrected by the trapezoidal distortion correction means so that the amount of information is reduced.   2. The projection display apparatus according to claim 1, wherein the conversion means converts RGB data of an input video signal having a high resolution and a high frequency into YUV data having a reduced amount of information by color space conversion. 3. The projection display apparatus according to claim 2, wherein the conversion unit converts RGB 24-bit data of an input video signal into YUV 16-bit data.