JP3986945B2 - Image enlargement device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image enlargement apparatus, and more particularly to an image enlargement apparatus that enlarges image data input as a bit stream.
[0002]
[Prior art]
Conventionally, various methods for enlarging an image have been proposed. A typical example is a method using a frame memory (for example, Patent Document 1). In Patent Document 1, a memory that stores digital image signals, a memory reading unit that sequentially reads pixel data from the memory, and an image S that is read by the memory reading unit. _n Each of the pixel signals S _n-1 , S _n-2 , S _n-3 Successive first, second and third delay means for forming a pixel signal S _n-1 And pixel signal S _n-2 The pixel signal S is obtained from the position of the interpolated pixel S ′ between _n , Pixel signal S _n-1 , Pixel signal S _n-2 , Pixel signal S _n-3 1st, 2nd, 3rd and 4th coefficient generation circuits for generating interpolation coefficients respectively corresponding to each of the pixel signals S _n And interpolation coefficient K _n An image interpolating apparatus including a signal synthesizing circuit that takes the sum of multiplications of the above is described.
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 11-53530
[0004]
[Problems to be solved by the invention]
However, in Patent Document 1, a large-scale field memory for temporarily storing image data is required, and the cost for the field memory is required. Further, the enlarged image cannot be read from the field memory while the original image is being written to the field memory. On the other hand, while the enlarged image is being read from the field memory, the image cannot be written to the field memory. For this reason, there is a problem that the FPS (the number of frames transferred per second) of the frame of the enlarged image becomes 1/2 or less of the FPS of the input image.
[0005]
In order to solve this problem, the dual port memory can be solved by using a dual port (dual-port) memory capable of writing and reading data as a field memory. Is expensive and further increases the cost.
[0006]
The present invention has been made to solve the above-described problems, and one object of the present invention is to provide an image enlarging apparatus capable of enlarging an image with a small amount of memory without providing a frame buffer. That is.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, according to one aspect of the present invention, an image enlarging device is an image enlarging device for enlarging image data in which pixel data is arranged in a predetermined order, and is delimited by a horizontal synchronization signal. Pixel data for one line is sequentially input within the horizontal synchronization period, at least one dot buffer for storing the input pixel data, at least one line buffer for storing horizontal data, and dots Horizontal expansion means for generating new pixel data based on the pixel data stored in the buffer, adding to the input pixel data and outputting to the line buffer, and new horizontal data based on the horizontal data stored in the line buffer Horizontal direction data is generated, and the newly generated horizontal direction data is added to the stored horizontal direction data and output. And means, vertical expansion means, the generated new horizontal data, and outputs the period you do not enter the pixel data into a dot buffer.
[0008]
According to the present invention, since the generated new horizontal data is output during a period in which no pixel data is input, an image enlarging apparatus capable of enlarging an image with a small memory without providing a frame buffer Can be provided.
[0009]
Preferably, pixel data is input to the dot buffer from a device that outputs pixel data for one line within the horizontal synchronization period in which the horizontal blanking period is expanded, and the vertical expansion means stores the stored horizontal direction data. New horizontal data generated by the vertical enlargement means is output at the output transfer rate.
[0010]
According to the present invention, pixel data is input from a device that outputs pixel data for one line within a horizontal synchronization period in which the horizontal blanking period is expanded. Therefore, new horizontal data generated within the horizontal blanking period can be output at a transfer rate at which the stored horizontal data is output.
[0011]
Preferably, the pixel data is input to the dot buffer from a device that outputs pixel data for one frame consisting of a plurality of lines within a vertical synchronization period that is divided by a vertical synchronization signal and in which the vertical blanking period is extended, and the vertical synchronization is performed. The period includes a vertical blanking period exceeding a period in which the generated horizontal data and the horizontal data stored in the line buffer used for generating the generated horizontal data are output.
[0012]
According to the present invention, pixel data is input from a device that outputs pixel data for one frame composed of a plurality of lines within a vertical synchronization period that is divided by a vertical synchronization signal and in which the vertical blanking period is expanded. And a vertical blanking period exceeding a period during which the generated horizontal data and the horizontal data stored in the line buffer used for generating the generated horizontal data are output. For this reason, the enlarged pixel data can be output within the vertical synchronization period of the input pixel data.
[0013]
Preferably, pixel data is input to the dot buffer from a device that outputs pixel data with a fixed horizontal synchronization period, and the vertical expansion means has a transfer rate that is faster than the transfer rate for outputting the stored horizontal data The new horizontal data generated by the vertical enlargement means is output.
[0014]
According to the present invention, pixel data is input from a device that outputs pixel data with a fixed horizontal synchronization period, and a new one generated by the vertical enlargement means at a transfer rate faster than the transfer rate at which the horizontal data is output. Horizontal data is output. For this reason, it is possible to enlarge an image without reducing the number of frames per unit time.
[0015]
Preferably, the dot buffer receives pixel data for one line in the horizontal synchronization period from a device that outputs the pixel data while fixing the horizontal synchronization period, and the transfer rate at which the vertical enlargement unit outputs the pixel data is: It is determined according to the transfer rate at which pixel data is input to the dot buffer.
[0016]
According to the present invention, the transfer rate at which the pixel data for one line is input in the horizontal synchronization period from the device that outputs the pixel data with the horizontal synchronization period fixed, and the vertical enlargement means outputs the pixel data is the dot buffer. It is determined in accordance with the transfer rate at which pixel data is input to. For this reason, since the generated new horizontal direction data is output during the period when the pixel data of the horizontal synchronization period is not input, the image can be enlarged without reducing the number of frames per unit time.
[0017]
Preferably, the dot buffer is supplied with pixel data for one frame composed of a plurality of lines within a vertical synchronization period from a device that outputs pixel data while fixing a vertical synchronization period divided by a vertical synchronization signal. The enlarging means is used to generate horizontal data generated in the vertical blanking period of the vertical synchronization period and the generated horizontal data when pixel data for one frame is input to the dot buffer. The horizontal data stored in the line buffer is output.
[0018]
According to the present invention, pixel data for one frame consisting of a plurality of lines is input within a vertical synchronization period from a device that outputs pixel data while fixing the vertical synchronization period divided by the vertical synchronization signal. When pixel data is input, horizontal data generated during the vertical blanking period of the vertical synchronization period, and horizontal data stored in the line buffer used to generate the generated horizontal data Is output. For this reason, the enlarged pixel data can be output within the vertical synchronization period of the input pixel data.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the same reference numerals indicate the same or corresponding members, and redundant description will not be repeated.
[0020]
<First Embodiment>
FIG. 1 is a diagram illustrating an enlarged example of a transfer image. FIG. 1A shows the transferred image 10 before being enlarged, and FIG. 1B shows the enlarged image 10A after being enlarged. The transfer image 10 is data in which a plurality of pixel data are arranged in a horizontal direction (horizontal direction in the drawing) and a vertical direction (vertical direction in the drawing). This transfer image 10 is input as bit stream data S to the image enlargement apparatus. The bit stream data S of the transfer image 10 is data in which pixel data is arranged one-dimensionally, and the arrangement order is determined in the order of the horizontal direction and the vertical direction. The horizontal arrangement order is from the left side to the right side of the drawing, and the vertical arrangement order is from the upper side to the lower side of the drawing. That is, the bit stream data of the transfer image 10 is arranged from the leftmost pixel data of the first line to the rightmost pixel data in the order of the right pixel data, and then the leftmost pixel data of the second line, The rightmost pixel data is arranged in order of the right pixel data. In this way, the pixel data is arranged one-dimensionally, and the rightmost pixel data on the last line becomes the last pixel data.
[0021]
Here, only one screen (one frame) is shown, but when the transfer image 10 has a plurality of frames, the bit stream data S follows the pixel data of the first frame and then the pixel data of the next frame. Are arranged.
[0022]
Referring to FIG. 1B, the enlarged image 10A shows a case where the transfer image 10 is enlarged in the horizontal direction and the vertical direction. In the bit stream data S2 of the enlarged image 10A, pixel data is arranged in the same manner as the bit stream of the transfer image 10.
[0023]
Here, for explanation, an example is shown in which the transfer image 10 is enlarged 3/2 times in the horizontal direction and the vertical direction with the upper left corner of the transfer image 10 as a reference. In this embodiment, the enlargement standard is the upper left corner of the transfer image 10, but other pixels may be used as the standard.
[0024]
The bit stream data S (L1) of the first line of the transfer image 10 is expanded in the horizontal direction to become the bit stream data S2 (L1) of the first line of the enlarged image 10A, and the bit stream of the second line of the transfer image 10 The data S (L2) is expanded in the horizontal direction to form the second-line bit stream data S2 (L2) of the enlarged image 10A, and the third-line bit stream data S (L3) of the transferred image 10 is expanded in the horizontal direction. As a result, the bit stream data S2 (L4) of the fourth line of the enlarged image 10A is obtained, and the bit stream data S (L4) of the fourth line of the transfer image 10 is enlarged in the horizontal direction to display the fifth line of the enlarged image 10A. The bit stream data S2 (L5) is used. On the other hand, the bit stream data S2 (L3) of the third line of the enlarged image 10A includes the bit stream data S2 (L1) of the first line, the bit stream data S2 (L2) of the second line, and the fourth line of the enlarged image 10A. Bit stream data S2 (L4) and the fifth line bit stream data S2 (L5).
[0025]
Similarly, if n is a positive number, the bit stream data S (L (2n−1)) of the (2n−1) -th line of the transfer image 10 is expanded in the horizontal direction and the ( 3n-2) -bit bit stream data S2 (L (3n-2)), and the (2n) -th line bit stream data S (L (2n)) of the transfer image 10 is enlarged in the horizontal direction. The bit stream data S2 (L (3n-1)) of the 10Ath (3n-1) th line is used. The bit stream data S2 (L3n) of the third n line of the enlarged image 10A is the bit stream data S2 (L (3n-2)) and (3n-1) of the (3n-2) line of the enlarged image 10A. Generated from the bit stream data S2 (L (3n-1)) of the line, the bit stream data S2 (L (3n + 1)) of the (3n + 1) th line, and the bit stream data S2 (L (3n + 2)) of the (3n + 2) line Is done.
[0026]
FIG. 2 is a block diagram illustrating a schematic configuration of the image enlargement apparatus according to the first embodiment. Referring to FIG. 2, image enlargement apparatus 100 includes an image output apparatus 102 that outputs bit stream data S, and an image enlargement unit 101.
[0027]
The image output apparatus 102 outputs the bit stream data S in which the pixel data of each pixel of the transfer image 10 illustrated in FIG.
[0028]
The image enlargement unit 101 includes a horizontal direction enlargement circuit 110 and a vertical direction enlargement circuit 120. The horizontal enlargement circuit 110 includes a shift register 111 for sequentially storing input bit stream data S, a coefficient storage unit 112 that stores coefficients, multipliers 113A to 113D, and an adder 114.
[0029]
The shift register 111 is a buffer for storing pixel data for four pixels, and has a shift register configuration. The bit stream data S input to the image enlargement unit 101 is stored in order in the shift register 111. Pixel data for four pixels is stored in four buffers of the shift register. While the pixel data for four pixels is stored, the first two pixels are sequentially output to the vertical enlargement circuit 120 via the adder 114. At this time, the output pixel data is not processed at all by the adder 114, that is, the pixel data is output as it is.
[0030]
When the pixel data for four pixels is stored in the shift register 111, the pixel data stored in the shift register 111 is output at a time. Here, the nth pixel data is stored in the fourth buffer, the (n + 1) th pixel data is stored in the third buffer, and the (n + 2) th data is stored in the second buffer. ) Pixel data is stored, and the (n + 3) th pixel data is stored in the first buffer. The nth pixel data (S (n-3)) stored in the fourth buffer is output to the multiplier 113D and the (n + 1) th pixel stored in the third buffer. The data (S (n−2)) is output to the multiplier 113C, and the (n + 2) th pixel data (S (n−1)) stored in the second buffer is supplied to the multiplier 113B. The (n + 1) th pixel data (S (n−3)) output and stored in the first buffer is output to the multiplier 113A. Predetermined coefficients from the coefficient storage unit 112 are input to the multipliers 113A, 113B, 113C, and 113D. Then, the multiplier outputs a value obtained by multiplying the input coefficient and the pixel data to the adder 114. The adder 114 adds the values input from the multipliers 113 </ b> A, 113 </ b> B, 113 </ b> C, and 113 </ b> D, and outputs the obtained sum to the vertical direction expansion circuit 120. In this way, pixel data of a new pixel following the first two pixels is generated by the horizontal direction expansion circuit 110.
[0031]
Here, an example has been described in which new pixel data is generated using the pixel data of the previous and subsequent four pixels and the coefficients stored in the coefficient storage unit 112, but the quality of the enlarged image 10A is determined by this generation process. Is done. Other methods can be used as the enlargement method executed by the horizontal enlargement circuit 110. Further, the number of buffers included in the shift register 111 is not limited to four, and at least one buffer may be provided.
[0032]
As described above, the horizontal expansion circuit 110 expands the bit stream data S input using the shift register 111 in the horizontal direction. Since the bit direction data S is continuously input, the horizontal direction enlargement circuit 110 outputs the pixel data for three pixels to the vertical direction enlargement circuit 120 while the pixel data for two pixels is stored in the shift register. To do. For this reason, the horizontal expansion circuit 110 executes processing with a clock that is at least 3/2 times the transfer clock to which the bit stream data S is input, and outputs pixel data expanded in the horizontal direction.
[0033]
Since the shift register 111 has a buffer for four pixels, the horizontal enlargement circuit 110 outputs new pixel data for horizontal enlargement based on pixel data of four adjacent pixels, and an input bit stream All bit stream data S can be output without losing data S. For this reason, the shift register 111 plays a role of a buffer material for performing the enlargement process in the horizontal direction without losing the continuity of the bit stream data S input to the horizontal enlargement circuit 110.
[0034]
In the horizontal expansion circuit 110, since the shift register 111 has a buffer for four pixels, the bit stream data S1 output to the vertical expansion circuit 120 is the bit stream data S input to the horizontal expansion circuit 110. In order to output the pixel data accumulated in the buffer, the output is delayed.
[0035]
The vertical enlargement circuit 120 sequentially stores the bit stream data S1 output from the horizontal enlargement circuit 110 to store pixel data for one line, and the coefficients are stored in the first to fourth line buffers 121A to 121D. A coefficient storage unit 122 for storing, multipliers 123A to 123D, and an adder 124 are included.
[0036]
The first to fourth line buffers 121A to 121D are buffers for storing pixel data for one line of the bit stream data S1 output from the horizontal enlargement circuit 110, and have a shift register configuration.
[0037]
The pixel data of the bit stream data S1 is stored in the order of the first line buffer 121A, the second line buffer 121B, the third line buffer 121C, and the fourth line buffer 121D. Then, the pixel data for four lines are stored in the first to fourth line buffers 121A to 12D. While the pixel data for four lines are stored, the first two lines of pixel data are output from the vertical enlargement circuit 120 via the adder 124. At this time, the output pixel data is not processed at all by the adder 124. That is, the pixel data is output as it is.
[0038]
At the stage where the pixel data for four lines are stored in the first to fourth line buffers 121A to 12D, the pixel data for one line stored in each of the first to fourth line buffers 121A to 12D is stored in each line. Output in the order stored in the buffer. Here, pixel data (S1 (Ln)) of the nth line is stored in the fourth line buffer 121D, and pixel data (S1 (L (n + 1)) of the (n + 1) th line is stored in the third line buffer 121C. The pixel data (S1 (L (n + 2)) of the (n + 2) -th line is stored in the second line buffer 122B, and the pixel data (S1 of the (n + 3) -th line is stored in the first line buffer 121A. Description will be made assuming that (L (n + 3)) is stored.
[0039]
The nth line pixel data (S1 (L (n))) stored in the fourth line buffer 121D is output to the multiplier 123D in the order stored, and the (n + 1) th pixel data stored in the third line buffer 121C. The pixel data (S1 (L (n + 2)) of the (n + 2) th line that is output to the multiplier 123C and stored in the second line buffer 121B in the order in which the pixel data (S1 (L (n + 1))) of the line is stored. Are output to the multiplier 123B in the order in which they are stored, and the pixel data (S1 (L (n + 2)) of the (n + 2) th line stored in the third line buffer 121C is output to the multiplier 123A in the order in which they are stored. In the multipliers 123A to 123D, the coefficients input from the coefficient storage unit 122 and the pixel data input from the line buffers 121A to 121D are displayed. Is added to the adder 124. The adder 124 adds the values input from the multipliers 123A, 123B, 123C, and 123D, and outputs the obtained sum. Thus, pixel data of a new line following the first two lines is generated by the vertical direction enlargement circuit 120.
[0040]
The vertical enlargement circuit 120 includes a counter and counts the timing for generating pixel data of a new line. That is, when the image is enlarged 3/2 times in the vertical direction, the counter counts 0 → 1 → 2 → 0. The counter is counted up every time pixel data for one line is output, and is reset to “0” after the counter value becomes “2”. Further, when the value of the counter reaches “2”, pixel data of a new line is output. Thereby, pixel data in which two lines are expanded to three lines is output. When the image is enlarged 4/3 times in the vertical direction, the counter counts 0 → 1 → 2 → 3 → 0. After the counter value reaches “3”, it is reset to “0”. Further, when the value of the counter reaches “3”, pixel data of a new line is output. Thereby, pixel data in which 3 lines are expanded to 4 lines is output.
[0041]
In the multipliers 123A, 123B, 123C, 123D and the adder 124, the calculation of the following equation (1) is executed. In equation (1), the bit stream data S2 output from the vertical enlargement circuit 120 is represented by S2 (L (n)) (n is a positive number) pixel data of the nth line.
[0042]
S2 (L (3n)) = S1 (L (2n-1)) * 1/6 + S1 (L (2n)) * 1/3 + S1 (L (2n + 1)) * 1/3 + S1 (L (2n + 2)) * 1 / 6
(1)
Here, an example has been described in which pixel data of a new line is generated using the pixel data of the preceding and subsequent four lines and the coefficient storage unit 122, but the quality of the enlarged image 10A is determined by this generation process. The method of generating pixel data of a new line by the vertical enlargement circuit 120 is not limited to this, and other methods can be used. Further, the number of line buffers is not limited to this, and it is less than the number of lines of the transfer image 10 and it is sufficient that there is at least one.
[0043]
As described above, the vertical expansion circuit 120 expands the input bit stream data S1 in the vertical direction using the first to fourth line buffers 121A to 121D. Since the bit stream data S2 is continuously input to the vertical enlargement circuit 120, pixel data for three lines is stored while pixel data for two lines is stored in the first to fourth line buffers 121A to 121D. Is output.
[0044]
Since the vertical direction enlargement circuit 120 stores the pixel data for four lines in the first to fourth line buffers 121A to 12D, the pixels in a new line for expanding in the vertical direction based on the pixel data of the four adjacent lines. In addition to outputting data, all the bit stream data S1 can be output without losing the input bit stream data S1. Therefore, the first to fourth line buffers 121A to 121D function as a buffer material for performing the expansion process in the vertical direction without losing the continuity of the bit stream data S1 input to the vertical expansion circuit 120. Fulfill.
[0045]
Since the vertical expansion circuit 120 includes the first to fourth line buffers 121A to 12D, the output bit stream data S2 is more line-up than the bit stream data S1 input to the vertical expansion circuit 120. In order to output the pixel data accumulated in the buffer, it is output with a delay.
[0046]
Next, the bit stream data S output from the image output apparatus 102 to the image enlargement unit 101 will be described. FIG. 3 is a diagram for explaining the bit stream data. The bit stream data is pixel data arranged in one dimension. Then, when transmitting from the image output apparatus 102 to the image enlarging unit 101, in order to synchronize between the two, a vertical synchronization signal (VSYNC) and a horizontal synchronization signal (HSYNC) are sent from the image output apparatus 102 to the image enlarging unit 101. Is sent.
[0047]
One frame of pixel data is included between the two vertical synchronization signals (VSYNC), and one line of pixel data is included between the two horizontal synchronization signals (HSYNC). A period between two horizontal synchronization signals (HSYNC) including a previous horizontal synchronization signal is called a horizontal synchronization period, and a period between two vertical synchronization signals (VSYNC) is called a vertical synchronization period.
[0048]
The horizontal synchronization period includes a horizontal synchronization signal HSYNC effective period (when HSYNC = High), a front porch (a period from when HSYNC is released to the data transfer period), and a transfer period of the input bit stream data S for one line. , The back porch (the period from the end of the data transfer period to the start of the next HSYNC). Strictly speaking, the horizontal blanking period includes a front porch and a back porch. Here, unless otherwise specified, the horizontal blanking period indicates a back porch.
[0049]
In FIG. 3, the bit stream data S is shown two-dimensionally, and only the transfer period, the horizontal blanking period, and the vertical blanking period are shown. When the bit stream data S shown in FIG. 3 is output from the image output device 102 to the image enlargement unit 101, the image enlargement unit 101 cannot enlarge the image. This will be described with reference to FIG. FIG. 4 is a diagram showing the bit stream data S input to the image enlargement unit 101 and the bit stream data S2 output from the image enlargement unit 101 in time series.
[0050]
Referring to FIG. 4, as for bit stream data S input to image enlargement unit 101, pixel data for one line is input to image enlargement unit 101 within one horizontal synchronization period. In this case, a horizontal blanking period (A) is included in the horizontal synchronization period. In the bit stream data S1 horizontally expanded by the image enlargement unit 101, the number of pixel data included in one line is 3/2 times that of the bit stream data S.
[0051]
Within the horizontal blanking period (A), pixel data of a new line generated by the image enlargement unit 101, for example, pixel data (S2 (L3)) of the third line (L3) must be output. However, as shown in FIG. 4, since the horizontal blanking period (A) is short, before the image enlargement unit 101 outputs the pixel data (S2 (L3)) of the third line (L3), The bit stream data S (S (L5)) of the fifth line is input. Therefore, it is necessary to output the bit stream data S2 (S2 (L4) of the fourth line, and it is not possible to output the pixel data (S2 (L3)) of the third line (L3).
[0052]
Since the pixel data for four lines are stored in the first to fourth line buffers 121A to 121D as in the horizontal direction, the vertical blanking after the bit stream data S for one frame is input. Within a period, pixel data for two lines stored in the first to fourth line buffers 121A to 121D and pixel data of a new line generated from them must be output. In the vertical enlargement circuit 120 of the image enlargement unit 101 according to the present embodiment, a new line is generated from a total of 4 lines, ie, two lines before and after. However, for the final line, a new line is generated from the previous two lines. In addition, when the input image data is composed of odd lines, two lines for generating the final line cannot be secured, so that no new line is generated. Therefore, the vertical blanking period is a period exceeding the period for outputting the pixel data stored in the first line buffer 121A and the second line buffer 121B and the pixel data of the line generated from the pixel data. is necessary. This is because the pixel data of the next frame is input from the image output device 102 to the image enlargement unit 101.
[0053]
However, since the vertical blanking period of the input bit stream data S is short, the image enlarging unit 101 uses the pixel data stored in the first line buffer 121A and the second line buffer 121B and the pixel data thereof. Before the pixel data of the generated line is output, the pixel data of the next frame is input. Therefore, it is necessary to output the enlarged bit stream data S2 (S2 (L1)) from the next frame, and the pixel data (S2 (L3)) of the third line (L3) cannot be output.
[0054]
For this reason, in the image enlarging apparatus 100 in the present embodiment, the image output apparatus 102 outputs the bit stream data S by enlarging the horizontal blanking period and the vertical blanking period.
[0055]
FIG. 5 is a diagram for explaining the bit stream data S output from the image output apparatus 102 according to the present embodiment. In FIG. 5, the bit stream data S is shown two-dimensionally, and only the transfer period, the horizontal blanking period, and the vertical blanking period are shown. Referring to FIG. 5, the horizontal blanking period (B) is longer than the horizontal blanking period (A). As the horizontal blanking period (B) is expanded, the horizontal synchronization period is expanded. The horizontal synchronization period is set to a period necessary for outputting two lines of pixel data expanded in the horizontal direction.
[0056]
In addition, the vertical blanking period is extended. The vertical blanking period is a period necessary for outputting pixel data stored in the first line buffer 121A and the second line buffer 121B and pixel data of a line generated from the pixel data.
[0057]
FIG. 6 is a diagram showing the bit stream data S input to the image enlargement unit 101 and the bit stream data S2 output from the image enlargement unit 101 in time series. Referring to FIG. 6, for bit stream data S input to image enlargement unit 101, pixel data for one line is input to image enlargement unit 101 for each horizontal synchronization period. In this case, a horizontal blanking period (B) is included in the horizontal synchronization period. The bit stream data S1 horizontally expanded by the image enlarging unit 101 is composed of pixel data in which the number of pixel data in one line is 3/2 times that of the bit stream data S.
[0058]
Within the horizontal blanking period (B), pixel data of a new line generated by the image enlargement unit 101, for example, pixel data (S2 (L3)) of the third line (L3) is output. Therefore, as shown in FIG. 6, since the horizontal blanking period (B) is expanded, the image enlarging unit 101 performs pixel data (S2 (L3) of the third line (L3) within the horizontal blanking period (B). )) Can be output.
[0059]
Further, since the vertical blanking period is expanded, before the bit stream data S of the next frame is input, the pixel data stored in the first line buffer 121A and the second line buffer 121B, and their Pixel data of a line generated from the pixel data can be output.
[0060]
The image output device 102 outputs image data (bit stream data S) in which pixel data is arranged in a predetermined order. Then, as shown in FIG. 5, a horizontal synchronization signal is output, and pixel data (for example, S (L1)) for one line is output within a horizontal synchronization period divided by the horizontal synchronization signal. Further, as shown in FIG. 6, after pixel data for one line is output (for example, S (L4)), a horizontal blanking period (horizontal blanking period (B)) exceeding the period in which the pixel data is output. ), The next horizontal sync signal is output. Therefore, as described above, the image enlargement unit 101 can output the pixel data (S2 (L3)) of the third line (L3) within the horizontal blanking period (B).
[0061]
Further, as shown in FIG. 6, the image output apparatus 102 supplies pixel data (for example, S (L1)) for one line in a period less than half of the horizontal synchronization period in order to secure the horizontal blanking period. You may make it output.
[0062]
As described above, in the image enlarging apparatus 100 according to the present embodiment, the bit stream data S is output from the image output apparatus 102 to the image enlarging unit 101 while enlarging the horizontal blanking period and the vertical blanking period. Therefore, the image enlarging unit 101 can output the enlarged bit stream data S2 while the bit stream data S for one frame is input without losing the bit stream data S.
[0063]
Further, without providing a frame buffer, only the shift register having four pixel data and the first to fourth line buffers 123A to 12D for four lines can be expanded in the horizontal direction and the vertical direction. For this reason, it is possible to enlarge an image with a small amount of memory.
[0064]
<Second Embodiment>
When the image enlarging apparatus 100 according to the first embodiment outputs the bit stream data S by the image output apparatus 102, the vertical blanking period and the horizontal blanking period are expanded. The image enlarging apparatus 100 in the embodiment outputs the bit stream data S from the image output apparatus 102 at the timing shown in FIG. 3 and increases the processing speed of the image enlarging unit 101. That is, the processing speed of the image enlargement unit 101 is increased, and the transfer speed for outputting newly generated pixel data is increased (the transfer clock is increased). The other points are the same as those of the image enlargement apparatus according to the first embodiment, and therefore, different points will be mainly described here.
[0065]
As described with reference to FIG. 4, when the bit stream data S is output from the image output device 102 at the timing shown in FIG. 3, pixel data (for example, the third line) of the newly generated line ( S2 (L3)) could not be output. However, by increasing the processing speed of the image enlarging unit 101 and making the transfer speed of the pixel data of the newly generated line faster than the transfer speed of the pixel data of the horizontally expanded line, the pixel data of the previous line After the output of (S2 (L2)) is completed, the pixel data (S2 (L3)) of the newly generated line is output before the pixel data (S2 (L4)) of the subsequent line is output. It becomes possible. Further, by increasing the processing speed of the image enlargement unit 101 and increasing the transfer speed for outputting pixel data during the vertical blanking period before the pixel data of the next frame is input, the first line buffer 121A It is possible to output pixel data stored in the second line buffer 121B and pixel data of a line generated from the pixel data.
[0066]
Therefore, the vertical enlargement circuit 120 increases the processing speed, and transfers the newly generated line pixel data transfer rate from the horizontally expanded line pixel data transfer rate stored in the line buffers 121A to 121D. Also make it faster. This transfer rate is a transfer rate at which pixel data of a newly generated line can be output within the horizontal blanking period (A).
[0067]
Further, the vertical enlargement circuit 120 increases the processing speed and the transfer speed for outputting pixel data in the vertical blanking period. With this transfer speed, the pixel data stored in the first line buffer 121A and the second line buffer 121B and the pixel data of the line generated from the pixel data can be output within the vertical blanking period. Transfer rate.
[0068]
FIG. 7 is a diagram illustrating, in time series, the bit stream data S input to the image enlargement unit 101 and the bit stream data S2 output from the image enlargement unit 101 according to the second embodiment. Referring to FIG. 7, for bit stream data S input to image enlargement unit 101, pixel data for one line is input to image enlargement unit 101 for each horizontal synchronization period. In this case, a horizontal blanking period (A) is included in the horizontal synchronization period. The bit stream data S1 horizontally expanded by the image enlarging unit 101 is composed of pixel data in which one line is 3/2 times that of the bit stream data S.
[0069]
Since the processing speed of the image enlargement unit 101 is high and the transfer speed of pixel data is high, pixel data of a new line generated within this period, for example, pixel data of the third line (L3) (S2 (L3)) Can be output. Further, since the transfer speed of the image enlargement unit 101 in the vertical blanking period is high, the bit stream data S of the next frame is stored in the first line buffer 121A and the second line buffer 121B before being input. Pixel data and pixel data of a line generated from the pixel data can be output.
[0070]
As described above, the image enlarging apparatus 100 according to the second embodiment outputs pixel data obtained by enlarging the input pixel data in the horizontal direction at the transfer speed of the pixel data input as the bit stream data, and performs the vertical direction. The pixel data of the line newly generated for enlarging the image data is output at a transfer rate faster than the transfer rate of the input pixel data. For this reason, in addition to the effect of the image enlarging apparatus 100 in the first embodiment, an image can be enlarged in the horizontal direction and the vertical direction without enlarging the horizontal synchronization period and the vertical synchronization period. Furthermore, since the horizontal synchronization period and the vertical synchronization period are not expanded, the image can be expanded without reducing the number of frames output per unit time.
[0071]
Furthermore, when the image output apparatus 102 outputs the transfer image 10 as the bit stream data S, the present invention can also be applied when the horizontal blanking period and the vertical blanking period cannot be extended.
[0072]
<Third Embodiment>
The image enlargement apparatus 100 according to the second embodiment is one in which the image output apparatus 102 outputs the bit stream data S at the timing shown in FIG. 3. In the image enlargement apparatus 100 according to the third embodiment, The image output device 102 outputs the bit stream data S at a timing at which the transfer period is shortened without expanding the horizontal synchronization period and the vertical synchronization period. Accordingly, the processing speed of the image enlargement unit 101 is increased, and the transfer speed of the output bit stream data S2 is shortened. The other points are the same as those of the image enlargement apparatus according to the second embodiment, and therefore, different points will be mainly described here.
[0073]
FIG. 8 is a diagram for explaining the bit stream data S output from the image output apparatus 102 according to the present embodiment. In FIG. 8, the bit stream data S is shown two-dimensionally, and only the transfer period, the horizontal blanking period, and the vertical blanking period are shown. Comparing FIG. 8 with FIG. 3, since the transfer rate is high (transfer clock is high) and the transfer period is shortened, the horizontal blanking period (C) is equal to the horizontal blanking period even though the horizontal synchronization period is the same. It is longer than (A). The horizontal synchronization period (C) is set to a period necessary to output two lines of pixel data expanded in the horizontal direction at a high transfer rate.
[0074]
In addition, the vertical blanking period is extended. Note that when the vertical blanking period is expanded without increasing the vertical synchronization period, the horizontal synchronization period may be shortened. In the vertical blanking period, the pixel data stored in the first line buffer 121A and the second line buffer 121B and the pixel data of the line generated from the pixel data are output at a high transfer rate. It is a necessary period.
[0075]
FIG. 9 is a diagram showing the bit stream data S input to the image enlargement unit 101 and the bit stream data S2 output from the image enlargement unit 101 in time series. Referring to FIG. 9, for the bit stream data S input to the image enlargement unit 101, pixel data for one line is input to the image enlargement unit 101 for each horizontal synchronization period. In this case, the horizontal synchronization period includes a horizontal blanking period (C). The bit stream data S1 horizontally expanded by the image enlarging unit 101 is composed of pixel data in which one line is 3/2 times that of the bit stream data S.
[0076]
Within the horizontal blanking period (C), pixel data of a new line generated by the image enlargement unit 101, for example, pixel data (S2 (L3)) of the third line (L3) is output. Accordingly, as shown in FIG. 9, since the horizontal blanking period (C) is expanded without increasing the horizontal synchronization period by increasing the transfer rate of the input pixel data, the horizontal blanking period In (C), the image enlargement unit 101 can output the pixel data (S2 (L3)) of the third line (L3).
[0077]
Further, since the vertical blanking period is extended, before the bit stream data S of the next frame is input, the pixel data stored in the first line buffer 121A and the second line buffer 121B, and their The pixel data of the line generated from the pixel data can be output. The image output device 102 outputs image data (bit stream data S) in which pixel data is arranged in a predetermined order. Then, as shown in FIG. 3, a horizontal synchronization signal is output, and as shown in FIG. 9, one line of pixel data (for example, S (L1)) is output in a period less than half of the horizontal synchronization period. To do.
[0078]
As described above, the image enlargement apparatus 100 according to the third embodiment does not need to be as fast as the processing speed of the image enlargement unit 101 of the image enlargement apparatus 100 according to the second embodiment, and the second embodiment. The same effects as those of the image enlargement apparatus 100 can be obtained.
[0079]
The invention shown below is also included in the present invention.
(1) An image enlarging apparatus includes: an image output unit that outputs pixel data for one line within a horizontal synchronization period divided by a horizontal synchronization signal;
At least one dot buffer for sequentially storing pixel data output from the image output means;
At least one line buffer for storing horizontal data;
Horizontal enlargement means for generating new pixel data based on the pixel data stored in the dot buffer, adding to the pixel data output from the output means, and outputting to the line buffer;
Vertical expansion means for generating new horizontal data based on the horizontal data stored in the line buffer, and adding the generated new horizontal data to the stored horizontal data for output. ,
The image output means does not output pixel data while outputting new horizontal data generated by the vertical enlargement means.
[0080]
(2) The image output means includes a vertical synchronization signal output means for outputting a vertical synchronization signal,
Output pixel data for one frame consisting of multiple lines within the vertical synchronization period delimited by the vertical synchronization signal,
The vertical synchronizing signal output means outputs pixel data for one frame and then newly outputs the horizontal direction data stored in the line buffer by the vertical enlargement means and the horizontal direction data stored in the line buffer. After the generated horizontal data is output, the next vertical synchronization signal is output.
[0081]
(3) Preferably, the image output means outputs pixel data within a fixed horizontal synchronization period,
The vertical direction enlargement means outputs new horizontal direction data generated at a transfer rate faster than the transfer rate for outputting the stored horizontal direction data.
[0082]
(4) Preferably, the image output means outputs pixel data for one line in a fixed horizontal synchronization period,
The vertical enlargement unit outputs pixel data at a transfer rate determined according to a transfer rate at which the image output unit outputs pixel data.
[0083]
(5) An image output device that outputs image data in which pixel data is arranged in a predetermined order,
Horizontal synchronization signal output means for outputting a horizontal synchronization signal;
Image output means for outputting pixel data for one line within a horizontal synchronization period divided by a horizontal synchronization signal;
The horizontal synchronizing signal output means outputs the next horizontal synchronizing signal after the pixel data for one line is output and after the horizontal blanking period exceeding the period for outputting the pixel data elapses.
[0084]
(6) An image output device that outputs image data in which pixel data is arranged in a predetermined order,
Horizontal synchronizing signal output means for outputting a horizontal synchronizing signal at a predetermined interval of a horizontal synchronizing period;
Image output means for outputting pixel data for one line in a period less than half of the horizontal synchronization period.
[0085]
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an enlarged example of a transfer image.
FIG. 2 is a block diagram showing a schematic configuration of an image enlargement apparatus according to the first embodiment.
FIG. 3 is a diagram for explaining bit stream data;
4 is a diagram showing, in time series, bit stream data S input to the image enlargement unit 101 and bit stream data S2 output from the image enlargement unit 101. FIG.
FIG. 5 is a diagram for explaining bit stream data S output by an image output unit according to the first embodiment.
FIG. 6 is a diagram showing, in time series, bit stream data S input to an image enlargement unit and bit stream data S2 output from the image enlargement unit in the first embodiment.
FIG. 7 is a diagram showing, in time series, bit stream data S input to an image enlargement unit and bit stream data S2 output from the image enlargement unit in the second embodiment.
FIG. 8 is a diagram for explaining bit stream data S output by an image output unit according to a third embodiment.
FIG. 9 is a diagram showing, in time series, bit stream data S input to an image enlargement unit and bit stream data S2 output from an image enlargement unit in the third embodiment.
[Explanation of symbols]
100 image enlargement device, 101 image enlargement unit, 102 image output device, 110 horizontal enlargement circuit, 111 shift register, 112, 122 coefficient storage unit, 113A-113D, 123A-123D multiplier, 114, 124 adder, 120 vertical Direction expanding circuit, 121A to 121D line buffer, S, S1, S2 bit stream data.

Claims (9)

An image enlarging apparatus for enlarging image data in which pixel data is arranged in a predetermined order,
One line of pixel data is sequentially input within a horizontal synchronization period delimited by a horizontal synchronization signal, and at least one dot buffer for storing the input pixel data;
A plurality of serially connected line buffers for storing horizontal data;
New pixel data is generated based on the pixel data stored in the dot buffer, the generated new pixel data is added to the input pixel data, and the most upstream line of the plurality of line buffers. A horizontal enlargement means for outputting to the buffer ,
Each of the plurality of line buffers holds horizontal data for one line and outputs the horizontal data according to the input order from the dot buffer.
Vertical expansion that generates new horizontal data based on the horizontal data stored in each of the plurality of line buffers , and outputs the generated new horizontal data in addition to the stored horizontal data further comprising means,
The vertical enlargement unit outputs the generated new horizontal data during a period in which no pixel data is input to the dot buffer. Pixel data is input to the dot buffer from a device that outputs pixel data for one line within a horizontal synchronization period in which a horizontal blanking period is expanded,
The vertical expansion means outputs new horizontal data generated by the vertical expansion means at a transfer rate for outputting the stored horizontal data ;
The image enlarging apparatus according to claim 1, wherein the horizontal blanking period is longer than a period in which pixel data for one line is output from the dot buffer . Pixel data is input to the dot buffer from a device that outputs pixel data for one frame consisting of a plurality of lines within a vertical synchronization period divided by a vertical synchronization signal and extending a vertical blanking period,
The vertical synchronization period includes a vertical blanking period that exceeds a period in which the generated horizontal data and the horizontal data stored in the line buffer used for generating the generated horizontal data are output. The image enlarging apparatus according to claim 2, further comprising: Pixel data is input to the dot buffer from a device that outputs pixel data with a fixed horizontal synchronization period,
2. The image according to claim 1, wherein the vertical direction enlargement unit outputs new horizontal direction data generated by the vertical direction enlargement unit at a transfer rate faster than a transfer rate of outputting the stored horizontal direction data. Enlarging device. The dot buffer receives pixel data for one line in the horizontal synchronization period from a device that outputs pixel data with a fixed horizontal synchronization period.
The image enlargement apparatus according to claim 1, wherein a transfer rate at which the vertical direction enlargement unit outputs pixel data is determined according to a transfer rate at which pixel data is input to the dot buffer. The dot buffer receives pixel data for one frame consisting of a plurality of lines within a vertical synchronization period from a device that outputs pixel data while fixing a vertical synchronization period divided by a vertical synchronization signal,
When the pixel data for one frame is input to the dot buffer, the vertical enlargement means generates the horizontal direction data generated during the vertical blanking period of the vertical synchronization period, and the generated horizontal direction data. 6. The image enlargement apparatus according to claim 4, wherein the horizontal direction data stored in the line buffer used for generation is output. The image enlarging apparatus according to claim 1, wherein each of the plurality of line buffers has a shift register configuration. An image enlargement method using an image enlargement device for enlarging image data in which pixel data is arranged in a predetermined order,
  The image enlarging device is:
  At least one dot buffer for storing input pixel data;
  A plurality of line buffers having a shift register configuration connected in series for storing horizontal data;
  New pixel data is generated based on the pixel data stored in the dot buffer, the generated new pixel data is added to the input pixel data, and the most upstream line of the plurality of line buffers. A horizontal enlargement means for outputting to the buffer,
  Each of the plurality of line buffers holds horizontal data for one line and outputs the horizontal data according to the input order from the dot buffer.
  Vertical expansion that generates new horizontal data based on the horizontal data stored in each of the plurality of line buffers, and outputs the generated new horizontal data in addition to the stored horizontal data Further comprising means,
  The image enlargement method includes:
  A step of sequentially inputting pixel data for one line into the dot buffer within a horizontal synchronization period divided by a horizontal synchronization signal;
  The vertical expansion means includes outputting the generated new horizontal data within the horizontal blanking period; and
  The image enlarging method using an image enlarging apparatus, wherein the horizontal synchronization period includes a horizontal blanking period longer than a period during which pixel data for one line is output from the dot buffer to the line buffer. An image enlargement method using an image enlargement device for enlarging image data in which pixel data is arranged in a predetermined order,
  The image enlarging device is:
  At least one dot buffer for storing input pixel data;
  A plurality of line buffers having a shift register configuration connected in series for storing horizontal data;
  New pixel data is generated based on the pixel data stored in the dot buffer, the generated new pixel data is added to the input pixel data, and the most upstream line of the plurality of line buffers. A horizontal enlargement means for outputting to the buffer,
  Each of the plurality of line buffers holds horizontal data for one line and outputs the horizontal data according to the input order from the dot buffer.
  Vertical expansion that generates new horizontal data based on the horizontal data stored in each of the plurality of line buffers, and outputs the generated new horizontal data in addition to the stored horizontal data Further comprising means,
  The image enlargement method includes:
  A step of sequentially inputting pixel data for one frame consisting of a plurality of lines within a vertical synchronization period divided by a vertical synchronization signal to the dot buffer;
  In the vertical blanking period, the vertical enlargement means generates the generated horizontal data and the horizontal data stored in the plurality of line buffers used to generate the generated horizontal data. A step of outputting,
  The vertical synchronization period is longer than a period during which the generated horizontal data and the horizontal data stored in the plurality of line buffers used for generating the generated horizontal data are output. An image enlargement method using an image enlargement device including a vertical blanking period.

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