KR100776543B1 - Apparatus for converting resolution - Google Patents

Abstract

An apparatus for converting the resolution size is provided to make it possible to convert a low-resolution image to a high-resolution image and display the high-resolution image clearly, thereby preserving the display compatibility between various product groups. A sample frequency horizontally converting unit(11) multiplies a sample frequency correspondingly to a horizontal frequency conversion rate. A poly-phase horizontal filter(12) operates the first phase value from the sample frequency multiplied by the sample frequency horizontally converting unit, and performs scaling filtering on image data by reading a horizontal interpolation filter coefficient correspondingly to the first phase value. A horizontal filter bank(13) stores the horizontal interpolation filter coefficient correspondingly to the first phase value. A line memory(14) sequentially stores previous lines of a poly-phase vertical filer(16). A sample frequency vertically converting unit(17) multiplies the sample frequency correspondingly to a vertical frequency conversion rate. The poly-phase vertical filter operates the second phase value of the sample frequency multiplied by the sample frequency vertically converting unit, and performs scaling filtering on the image data by reading a vertical interpolation filter coefficient correspondingly to the second phase value. A vertical filter bank(15) stores the vertical interpolation filter coefficient correspondingly the second phase value.

Description

Resolution converter {APPARATUS FOR CONVERTING RESOLUTION}

1 is a control circuit block diagram schematically showing a concept of a resolution conversion of the present invention.

2 is a control circuit block diagram of a resolution converting apparatus according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

11: sample frequency horizontal converter 12: polyphase horizontal filter

13 horizontal filter bank 14 line memory

15: sample frequency vertical converter 16: polyphase vertical filter

17: vertical filter bank

The present invention relates to a resolution converting device, and more particularly, to a resolution converting device for clearly and clearly expressing a low resolution image as a high resolution image in display compatibility between various product families.

In the case of a product provided with a display device, a display device having various resolutions may be provided in consideration of characteristics of the product. That is, the mobile application product is provided with a display device of mostly low resolution (320 x 244) in consideration of mobility and portability. On the other hand, products that are placed in a fixed place or require a high resolution is provided with a display device of high resolution (1024 x 768, 1600 x 1200, 1920 x 1080, ...).

As such, it is related to display compatibility between product families having different resolutions according to the use, and receives (downloads) low-resolution QVGA (320 x 244) images output from mobile application products and wires them to display devices such as PC monitors and large TVs. Alternatively, when the wireless connection is expressed, there is a disadvantage in that the distortion and staircase of the image are seen.

Various interpolation techniques have been proposed to compensate for these shortcomings, but there is a fundamental problem of decreasing the sharpness because the frequencies used by the display apparatus are fixed. Especially, in the case of TV, the broadcasting station itself is fixed at 15.75 (KHZ) when the horizontal and vertical frequencies are horizontal and 60 (HZ) when it is vertical. Since the operation is performed at a low level, there is a problem that the sharpness of the screen is significantly lowered due to the low resolution.

Accordingly, an object of the present invention is to solve the problems of the prior art, frequency multiplication and color corresponding to the resolution so that a low resolution image can be clearly and clearly expressed as a high resolution image in display compatibility between various product lines. The present invention provides a resolution conversion apparatus corresponding to a resolution conversion using a compensation technique.

One aspect for achieving the above object of the present invention, the sample frequency horizontal converter for multiplying the input sample frequency corresponding to the horizontal frequency conversion rate; A polyphase horizontal filter that calculates a face value at the multiplied sample frequency, reads a horizontal interpolation filter coefficient to correspond to the face value, and performs scaling filtering on the input image data; A horizontal filter bank for storing horizontal interpolation filter coefficients which are band limiting filter information of a specific frequency corresponding to the face value; A line memory sequentially storing previous lines of a polyphase vertical filter described below; A sample frequency vertical converter which multiplies the input sample frequency by a vertical frequency conversion rate; A polyphase vertical filter that calculates a face value at the multiplied sample frequency, reads a vertical interpolation filter coefficient corresponding to the face value, and performs scaling filtering on the input image data; And a vertical filter bank for storing vertical interpolation filter coefficients, which are band limiting filter information of a specific frequency, in response to the face value.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a control circuit block diagram schematically showing a concept of a resolution conversion of the present invention.

As shown in FIG. 1, the present invention is largely composed of a sample frequency controller 1, a scaler 2, a filter coefficient memory 3, and a high resolution filter 4. As shown in FIG.

The sample frequency controller 1 performs frequency conversion corresponding to the resolution to convert the input sample frequency.

The scaler 2 performs scaling filtering in response to the resolution conversion.

The filter coefficient memory 3 divides and stores the band limiting filter coefficient according to the face information, and then provides the band limiting filter coefficient in response to the request of the scaler 2.

The high resolution filter 4 is a high frequency component compensation filter provided to compensate for blurring caused by interpolation filtering at the output of the scaler 2.

In this way, in response to the conversion of the resolution, the sample frequency controller 1 converts to the corresponding frequency, and the converted frequency is supplied to the scaler 2 to perform scaling filtering on the image signal input to the scaler 2. Will be performed. At this time, in order to perform scaling filtering, a process of reading an optimal interpolation filter coefficient stored in the filter coefficient memory 3 must be preceded.

2 is a control circuit block diagram of a resolution converting apparatus according to an embodiment of the present invention.

As shown in FIG. 2, in the resolution converting apparatus of the present invention, a sample frequency horizontal converter 11 for multiplying an input sample frequency in correspondence with a horizontal frequency conversion rate for converting horizontal resolution first and multiplied samples A poly-phase horizontal filter that calculates a face value at a frequency, reads a horizontal interpolation filter coefficient corresponding to the face value, and performs scaling filtering on the input image data, and a specific value corresponding to the face value. A horizontal filter bank 13 is provided which stores horizontal interpolation filter coefficients which are band limited filter information of frequencies.

Here, a line memory 14 for sequentially storing the previous line of the polyphase vertical filter 16 is provided so as to be made between the horizontal resolution conversion and the vertical resolution conversion process.

On the other hand, in the resolution converting apparatus of the present invention, for converting the vertical resolution, a sample frequency vertical converter 15 for multiplying the input sample frequency corresponding to the vertical frequency conversion rate, and calculates the face value from the multiplied sample frequency And a polyphase vertical filter 16 that reads the vertical interpolation filter coefficients described below corresponding to the face value and performs scaling filtering on the input image data, and a vertical band limiting filter information of a specific frequency corresponding to the face value. It consists of a vertical filter bank 17 that stores interpolation filter coefficients.

An operation process of the resolution converting apparatus of the present invention configured as described above will be briefly described.

First, it is assumed that input image data, for example, 320 * 244 samples (R or G or B, or Y or U or V) of size low resolution are input one by one in order from left to right and top to bottom. As such, the process of storing the data in a separate memory according to the sequential data flow is omitted, and the memory is also unnecessary.

On the other hand, if a sample frequency, for example, low resolution 320 (horizontal sample) * 244 (vertical line) * 60 (frame per second) = 4.685 MHz is input to the sample frequency horizontal converter 11, the sample frequency horizontal converter 11 converts the sample frequency. The sample frequency is converted and output according to the desired resolution.

That is, a new sample frequency, for example 1920 * 244 * 60 = 28 MHz, is output from the sample frequency horizontal converter 11. Therefore, for the present embodiment, the horizontal conversion rate is 1920/320 = 6. Here, the sample frequency multiplied by 6 times is generated and provided to the polyface filter.

Thus, the polyphase horizontal filter 12 calculates how much the face is at the sample frequency. According to the phase, the horizontal interpolation filter coefficient is found in the horizontal filter bank 13 and scaling filtering is performed. The resulting frame size is 1920 * 244.

Here, the horizontal filter bank 13 divides and stores the band limit filter coefficient according to the face information in order to eliminate the overlapping of the fundamental frequency band caused by the harmonics occurring in the sample frequency conversion process of the image data in advance. For example, 1024 * 6 = 186,144 band limit filter coefficients with 8-bit coefficients divided into 1,024 6-tap filters.

On the other hand, the line memory 14 is a place for temporarily storing several previous lines for the polyphase vertical filter 16. As in the previous horizontal filter example, the vertical filter should consist of six tabs to store the previous five lines of data. In other words, the line memory 14 stores 1920 * 5 = 9,600 samples. Sequential means that when the data of the next line is input like a shift register, the data of the oldest line is erased, the next oldest line data takes its place, and the empty place repeats the next oldest line data in order. It fills up.

When the horizontal resolution conversion process is completed, a vertical resolution conversion process is performed next.

That is, if a sample frequency, for example, a low resolution 1920 * 244 * 60 = 28 MHz is input to the sample frequency vertical converter 15, the sample frequency vertical converter 15 converts the sample frequency corresponding to the resolution to be converted and outputs the converted frequency. Let's go.

That is, the sample frequency vertical converter 15 outputs a new sample frequency, for example, 1920 * 1440 * 60 = 166 MHz. Therefore, for the present embodiment, the vertical conversion rate is 1440/244 = 5.9. Here, the sample frequency multiplied by 5.9 times is generated and provided to the polyphase vertical filter 16.

Accordingly, the polyphase vertical filter 16 calculates how much the face is at the sample frequency. According to the phase, the vertical interpolation filter coefficient is found in the vertical filter bank 17 and scaling filtering is performed. The resulting frame size is 1920 * 1440.

In this case, the vertical filter bank 17 divides and stores the band limiting filter coefficient according to the face information in order to eliminate the overlapping of the fundamental frequency band caused by the harmonics occurring in the sample frequency conversion process of the image data in advance. For example, 1024 * 6 = 186,144 band limit filter coefficients with 8-bit coefficients divided into 1,024 6-tap filters.

The principle and structure of the vertical filter bank 17 is the same as that of the horizontal filter bank 13. Therefore, if the frequency conversion rate is similar, the vertical filter bank 17 and the horizontal filter bank 13 may be used as one.

The present invention is not limited to the above-described embodiments, and it will be apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

As described above, according to the present invention, it is possible to receive a low resolution QVGA image output from a mobile application product and to display a clear and clear image at high resolution on a monitor for a PC and a large TV. As such, it is possible to easily solve the compatibility problem caused by the display between the various product lines having different resolutions.

Claims (3)

delete delete A sample frequency horizontal converter multiplying the input sample frequency corresponding to the horizontal frequency conversion rate; A polyphase horizontal filter that calculates a face value at the multiplied sample frequency, reads a horizontal interpolation filter coefficient to correspond to the face value, and performs scaling filtering on the input image data; A horizontal filter bank for storing horizontal interpolation filter coefficients which are band limiting filter information of a specific frequency corresponding to the face value; A line memory sequentially storing previous lines of a polyphase vertical filter described below; A sample frequency vertical converter which multiplies the input sample frequency by a vertical frequency conversion rate; A polyphase vertical filter that calculates a face value at the multiplied sample frequency, reads a vertical interpolation filter coefficient corresponding to the face value, and performs scaling filtering on the input image data; And Vertical filter bank for storing the vertical interpolation filter coefficient which is band limit filter information of a specific frequency corresponding to the face value Resolution converting apparatus comprising a.

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