JP2908463B2 - Image encoding apparatus and image encoding method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to an image encoding apparatus and an image encoding method relating to a compression encoding method for a still image or a moving image such as a videophone or an electronic camera. About.

(Prior Art) When compressing and encoding a still image or a moving image of a videophone, an electronic camera, or the like, there is a demand to encode one screen within a predetermined number of encoding bits as efficiently as possible. is there.

In such a case, the problem is how to allocate a predetermined number of coded bits in the screen, but with regard to image coding, the S / N ratio (signal-to-noise ratio) is improved and subjective evaluation is performed. The most important issue is how to improve it. At this time, if it is known which part of the screen the image viewer actually looks at (evaluates), more coding bits are assigned to that part and coding processing is performed. The subjective assessment for the person will be improved (if not). For example, if a snapshot is taken of a person standing in a certain scenery, the most noticeable part is the human, and the image quality of this part greatly contributes to the overall subjective evaluation.

However, when a picture contains both coarse and fine parts, the fine part of the pattern or the part with the fineness corresponding to the frequency band that responds most sensitively to human visual characteristics In addition, a method of allocating a large number of coded bits to perform a coding process has been considered. For this reason, in the case of a picture in which the entire screen can be uniformly evaluated, the subjective evaluation can be strangely improved as a whole, but as described above, an image in which a human is standing in a certain scenery is used. In particular, when the background is a fine pattern, a large number of coded bits are taken in the background portion, and the number of coded bits allocated to the human portion where image quality is most important is reduced. For this reason, there is a disadvantage that the subjective evaluation is not improved and the subjective evaluation is degraded in some cases even though the adaptive processing is performed according to the fineness of the picture.

(Problems to be Solved by the Invention) As described above, conventionally, the adaptive processing that emphasizes the subjective evaluation has not been sufficiently performed. There was a problem that the subjective evaluation as a standard did not improve.

Therefore, the present invention solves these problems, and performs the most noticeable part in one screen, or the part where the person who views the processed image wants to emphasize the image quality, or performs the encoding process. For the part where the person on the side wants to improve the image quality best, distinguish that part from the others in advance,
By allocating more coding bits,
It is an object of the present invention to provide an image coding method that improves the image quality of the portion and improves the subjective evaluation of the entire screen.

[Configuration of the invention]

(Means for Solving the Problems) The present invention provides a means for evaluating the fineness of a picture for each area of an input image divided into a plurality of areas, and an evaluation for each area based on positional information of the area in a screen. Means for correcting the value, means for assigning the number of coded bits of the input image for each area based on the corrected evaluation value, and coding of the input image for each area according to the number of coded bits assigned there And an image encoding apparatus and method.

Further, the present invention provides a means for evaluating the fineness of a pattern for each area of an input image divided into a plurality of areas, and a method for evaluating each pattern in consideration of positional information of the area on a screen and an evaluation result of the area. A moving image encoding apparatus and method comprising: means for assigning the number of encoding bits of an input image; and means for encoding the input image for each area according to the number of encoding bits assigned thereto.

Further, the present invention is a means for calculating the amount of information for each region of the input image divided into a plurality of regions, means for weighting the amount of information for each region based on the position information of the region in the screen,
Means for allocating the number of coding bits of the input image based on the weighted information amount of each area, and means for coding the input image of each area according to the number of coding bits allocated therefor. Image encoding apparatus and method.

The present invention also provides a means for calculating an information amount for each region of an input image divided into a plurality of regions, and a position information on a screen of the region and an information amount for each region in consideration of each region. An image encoding apparatus and method comprising: means for assigning the number of encoding bits of an input image; and means for encoding the input image for each area according to the number of encoding bits assigned there.

According to the present invention, a means for evaluating the fineness of a pattern for each partial image for an input image classified into a plurality of partial images, and correcting an evaluation value for each partial image based on positional information of the partial image in a screen Means, means for allocating the number of coded bits of the partial image based on the corrected evaluation value for each partial image, and means for coding the partial image according to the coded bit number allocated therefor. Image encoding apparatus and method.

The present invention also provides a means for calculating an information amount for each partial image for an input image classified into a plurality of partial images, and a means for weighting the information amount for each partial image based on positional information of the partial image in a screen. Means for assigning the number of encoded bits of the partial image based on the weighted information amount of each partial image, and means for encoding the partial image according to the assigned number of encoded bits. An image encoding device and method.

According to the present invention, a portion for improving image quality in one screen is determined in advance, and the portion is weighted so as to be distinguished from other portions and a larger number of encoded bits are allocated to the portion. At the time of actual encoding, in order to end the encoding process of each part with the number of encoded bits allocated in advance,
Despite the same code amount as before in the entire screen,
This is a method in which the subjective evaluation of a portion where the image quality is desired to be improved is improved, so that the overall subjective evaluation is also improved.

The position, size, or shape of the part where the image quality is to be improved is fixed (fixed type: in the case of a photograph, for example, the important part is often located at the center of the screen. A large number of coded bits are allocated while distinguishing the vicinity of the center from the others), or set by selecting from those prepared in advance (selection type), or by freely changing the position or shape. It is conceivable that the user can set the information (free type).

In addition, regarding the weighting process for the part where the image quality is desired to be improved, the weighting value is also fixed type, selective type,
A free type is conceivable, but it is also possible to use a method of adjusting the weighting values adaptively at their boundaries so that the resolution of the weighted part and the resolution of the other parts are connected smoothly. is there.

(Operation) In this way, a part of one screen where the image quality is desired to be improved is determined in advance, and the part is weighted to be distinguished from other parts, and a larger number of coding bits are allocated to the part. In the actual encoding, the subjective evaluation of the part where the image quality is to be improved is improved by terminating the encoding processing of the part with the allocated number of encoded bits, and finally the subjective evaluation of the entire screen is also improved. It is possible to do.

(Example) Hereinafter, an example of the present invention is described with reference to drawings.

FIG. 1 is a block diagram of a transmitting side and a receiving side according to an embodiment of the present invention. After the image input from the input device 101 is taken into the frame memory 102, the block dividing circuit 1
03 is divided into blocks.

On the other hand, from the block dividing circuit 103, information indicating the position of the current block in one screen is output, and the information is sent to the high image quality required position setting circuit 104. This is the part where the image quality within one screen is desired to be improved (the part where weighting is performed when determining the number of coding bits of that part)
The position, shape, weighting value, etc. can be input from outside.

For example, as shown by hatched portions in FIGS. 2A to 2C, the size of the weighted portion is changed by an external operation, or the position of the weighted portion is changed as shown in FIG. 2D. It is possible. Further, the weighting value may be a continuous function as shown in (a) of FIG. 3 (a diagram showing the weighting value W for the block on the straight line 210), or (b) As shown in FIG. It is also conceivable to assign a sharp weight only to the diagonally shaded portion as shown in (c). However, in this case, the continuity of the resolution between the diagonally shaded portion and the other portions is impaired, and block distortion occurs there. Therefore, the methods (a) and (b) are more preferable since the subjective evaluation may be deteriorated.

Ideally, the position, shape, weighting value, etc. of the weighting part can be freely set,
In some cases, the type may be limited due to restrictions such as hardware scale and encoding processing time. In this case, in addition to the example shown in FIG. 2, for example, as shown in FIGS. 4 (a) to 4 (c), a human shape is assumed in advance, and (a) for close-up, (b) distant view For (c) multiple people, etc.
It is also conceivable to set a weighted portion by selecting from among these. Further, the method is not limited to only humans, but may be a method in which a wide and general figure is prepared and its position and size can be changed as shown in FIGS. 5 (a) to 5 (c). Furthermore, as shown in (d), it is also possible to determine the center position C of the portion to be weighted, and set the inside of the circle when a circle having a radius D is drawn therefrom as the weighted portion. Alternatively, as shown in FIG.
It is also conceivable to use two straight lines in each of the horizontal and vertical directions (both can be freely moved) and to set the weighted portion in the hatched portion surrounded by these four straight lines. In this case, the four lines do not need to be straight lines, and the moving directions of the lines need not be only horizontal and vertical directions. still,
The setting to the high image quality required position setting circuit 104 can be selected or set by a dial. For example, in the case of FIG. 4 (a)
(B)... (C) are inputted in the frame memory in advance and one of them is selected from outside. In the case of FIG. 6, two straight lines are moved by dials and monitored.
The image transmitted from the input device 101 on the real time 100 is also matched.

As described above, the setting of the weighting portion is performed by the dial in the high image quality required position setting circuit 104, and the weighting value is determined by the weighting circuit 105 using the address information corresponding to the setting. The block signal output from 103 is also sent to the information amount calculation circuit 106, where the amount of information in the block (the amount indicating the fineness of the picture, which is subjected to variance, standard deviation, or band pass filtering) Is calculated by multiplying the information amount in the multiplication circuit 107 (weighted) to obtain a final information amount. It is sent to the information amount accumulation circuit 108. Here, the weighted information amount Bn (n = 1, 2,... N; N is the total number of blocks on one screen) of each block is stored for one screen, and the total information amount A
(= B ₁ + B ₂ +... B _N ) is calculated.

Thereafter, the input image stored again in 102 is divided into blocks at 103 and sent to the encoding circuit 110 for each block. On the other hand, since the weighted information amount for each block is already stored in the information amount accumulation circuit 108, the ratio Bi / A of the information amount Bi of the block currently transmitted to 110 and the total information amount A is output from here, It is sent to the bit distribution circuit 109.
Here, xi = X · Bi / A is calculated for a preset total number of coded bits X of one screen (which can be input from the outside), and xi is transmitted as 110 as the number of coded bits of the block. Can be In 110, the block signal transmitted from 103 is encoded so that the number of bits exceeds the number of encoded bits of xi or even if the number of encoded bits exceeds the number of bits, the excess is within a predetermined range. Performs the processing, transmission line 111
(By this processing, even if the entire screen is within the predetermined total number of coded bits or exceeds the total number of coded bits, the excess is within the predetermined range. Encoding processing becomes possible).

On the other hand, on the receiving side, the signal sent from 111 is decoded by decoding circuit 112, and the reproduced image is displayed on monitor 113. That is, decoding is performed by a very simple process on the receiving side.

FIG. 7 shows a part of the transmitting side (first embodiment) of another embodiment of the present invention.
It is a block diagram which shows (150 part of the figure).

The signal sent from the information amount calculation circuit 106 is stored in the information amount accumulation circuit 301 for each block, and the ratio of the information amount of each block to the total information amount in one screen (108 in the embodiment of FIG. 1). The bit allocation determination circuit 3
Sent to 02. Here, similarly to the processing in 109, the number of coded bits of each block is determined, but the weighting processing has not yet been performed at this stage.

On the other hand, based on the signal sent from the weighting circuit 105, the bit shift setting circuit 303 shifts the number of coded bits between blocks (a part of the coded bit Move to the number of coded bits). For example, as shown in FIG. 8, when weighting is performed on five blocks near the center, the movement of the number of encoded bits as shown in the figure is determined by the magnitude of the weight value.

That is, in the weighting part, 1 to 10 bits are added in addition to the number of coding bits determined in 302, while the total number of coding bits of the entire screen needs to be kept constant. From the unweighted surrounding blocks (for example, as shown in the figure, if there are 25 blocks in one block line, the unweighted surrounding blocks are the remaining 20 blocks), and the uniform bits are subtracted. It is sent to the instruction bit redistribution circuit 304. 304
In response to this instruction, addition and subtraction of the number of bits are performed on the number of bits encoded in each block. As a result, as shown below, the output state (a) from 302 (output information: number of coded bits for each block)... A ₉ , a ₁₀ ,
a _11, a _12, ... with respect to a _16, a ₁₇ ..., the output state from 304 (output information: final encoding bit number allocation after weighting of each block) is (b) ... a ₃ -1 , a ₁₀ −1, a ₁₁ −1, a ₁₂ −1, ... a
₁₆ −1, a ₁₇ −1, and as a result, weighting is performed.

The number of code bits determined in 304 is sent to the encoding circuit 110, and the same encoding processing as that described in the embodiment of FIG. 1 is performed.

〔The invention's effect〕

As described above, according to the present invention, a portion for improving the image quality in one screen, particularly a portion which is conspicuous to a viewer who views a reproduced image is weighted to be distinguished from other portions, and more coding is performed on the portion. Distribute the number of bits. At the time of actual encoding, by ending the encoding processing of the part with the allocated number of encoded bits, the quality of the reproduced image of the part whose quality is desired to be improved is improved, and the subjective evaluation of the part is improved. As a result, the subjective evaluation of the entire screen can be finally improved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG.
4 and 6 are diagrams showing examples of the position, size, and shape of the weighting portion, FIG. 3 is a diagram illustrating the relationship between the weighting value and the position, and FIG. FIG. 8 is a block diagram showing another embodiment, and FIG. 8 is a diagram for explaining how weighting is performed. 107: Multiplication circuit, 111: Transmission path, 150: Encoding bit allocation determination part of each block, 201: Frame (or field), 202: Boundary between weighted and non-weighted parts, 207 ... Center of weighting portion, 208... Radius from center of weighting portion (circle), 211... Weighting value, 220-223... Movable movable line for determining weighting portion, 224. part.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Yuriko Tsukahara 1 Tokoba, Komukai Toshiba-cho, Saisaki-ku, Kawasaki-shi, Kanagawa Prefecture (56) References JP-A-62-8658 (JP, A) JP-A Sho 62-281582 (JP, A) JP-A-62-220082 (JP, A) JP-A-2-262786 (JP, A) IEEE TRANSACTIONS ON COMMUNICATION S, COM-25 [11] (1977) p. 1285 -1292 (58) Fields investigated (Int.Cl. ⁶ , DB name) H04N 7/24-7/68 H04N 1/41-1/419

Claims (76)

(57) [Claims] A means for evaluating the fineness of a picture for each area of the input image divided into a plurality of areas; a means for correcting an evaluation value for each area based on positional information of the area in a screen; Means for allocating the number of coding bits of the input image for each region based on the corrected evaluation value, and means for coding the input image for each region according to the number of coding bits allocated therefor. Image encoding device. 2. The image encoding apparatus according to claim 1, wherein the means for correcting the evaluation value corrects the evaluation value of the area only when the area is located at a specific position in the screen. 3. The image coding apparatus according to claim 1, wherein said means for correcting the evaluation value changes the degree of correction of the evaluation value in accordance with positional information of the area in the screen. 4. An apparatus for correcting an evaluation value, wherein a larger number of coded bits is assigned to an image of an area located near the center of the screen than an image of an area located near the periphery of the screen. 4. The image coding apparatus according to claim 1, wherein the evaluation value is corrected. 5. The image coding apparatus according to claim 2, further comprising means for designating a specific position or a portion including the specific position in the screen. 6. A means for designating a specific position or a portion including a specific position in a screen includes a specific position or a specific position from a plurality of predetermined specific position candidates or a plurality of candidate portions including the specific position. 6. The image encoding apparatus according to claim 5, wherein a specific position in the screen or a part including the specific position is designated by selecting the part. 7. A system according to claim 2, further comprising means for changing a degree of correction of an evaluation value of an area included in a specific position or a part including the specific position on the screen. The image encoding device according to claim 1. 8. The means for designating a specific position or a portion including a specific position in a screen can be specified again in place of the specific position or a portion including the specific position in the screen once specified. Item 8. The image encoding device according to Item 5, 6, or 7. 9. A means for evaluating the fineness of a picture for each area of an input image divided into a plurality of areas, and means for each area in consideration of positional information of the area on a screen and an evaluation result of the area. An image coding apparatus comprising: means for assigning the number of coding bits of an input image; and means for coding an input image for each region according to the number of coding bits assigned there. 10. A coding bit number allocating means for each area so that a larger number of coding bits are allocated to an image located near the center of the screen than an image located near the periphery of the screen. 10. The image encoding apparatus according to claim 9, wherein the number of encoding bits of the input image is assigned. 11. The image coding apparatus according to claim 9, wherein said coding bit number allocating means is capable of newly allocating the number of coded bits for each area once allocated. And means for designating the specific position or the portion including the specific position so that a larger number of coded bits are assigned to the specific position or the portion including the specific position in the screen. The image encoding device according to claim 9, 10 or 11, wherein: 13. A means for designating a specific position or a part including a specific position in a screen includes a specific position or a specific position from a plurality of predetermined specific position candidates or a plurality of candidate parts including the specific position. By selecting the parts,
13. The image encoding device according to claim 12, wherein a specific position in the screen or a portion including the specific position is specified. 14. A method for designating a specific position or a portion including a specific position in a screen, wherein the means for specifying the specific position or the portion including the specific position in the screen once specified can be specified again. Item 14. The image encoding device according to Item 12 or 13. 15. A means for calculating an information amount for each area of an input image divided into a plurality of areas, a means for weighting the information amount for each area based on positional information of the area in a screen, and a means for weighting the information amount. Means for allocating the number of coding bits of the input image based on the amount of information for each area, and means for coding the input image for each area according to the number of coding bits allocated therefor. Encoding device. 16. A means for weighting the information amount for each area,
The information amount for each area is weighted only when the area exists at a specific position in the screen.
15. The image encoding device according to 15. 17. A means for weighting the information amount for each area,
17. The image encoding device according to claim 15, wherein a degree of weighting is changed according to position information of the region in a screen. 18. A means for weighting the information amount for each area,
The information amount for each area is weighted such that a larger number of encoded bits is assigned to an image of an area located near the center of the screen than an image of an area located near the periphery of the screen. 18. The image encoding device according to 15, 16, or 17. 19. A system according to claim 19, further comprising means for designating a specific position on the screen or a portion including the specific position.
19. The image encoding device according to 16, 17 or 18. 20. A means for designating a specific position or a part including a specific position in a screen includes a specific position or a specific position from a plurality of predetermined specific position candidates or a plurality of candidate parts including the specific position. By selecting the parts,
20. The image encoding device according to claim 19, wherein a specific position in the screen or a portion including the specific position is specified. 21. A system according to claim 16, further comprising means for changing a degree of weighting of an information amount for each area included in a specific position or a part including the specific position in the screen.
21. The image encoding device according to 18, 19 or 20. 22. A means for designating a specific position or a part including a specific position in a screen can be specified again in place of the specific position or a part including the specific position in the screen once specified. Item 22. The image encoding device according to Item 19, 20 or 21. 23. A means for calculating the amount of information for each region of an input image divided into a plurality of regions, and the position information on the screen of the region and the amount of information for each region in consideration of each region. An image coding apparatus comprising: means for assigning the number of coding bits of an input image; and means for coding an input image for each area according to the number of coding bits assigned there. 24. A coding bit number allocating means for each area so that a larger number of coding bits are allocated to an image located near the center of the screen than an image located near the periphery of the screen. 24. The image coding apparatus according to claim 23, wherein the number of coding bits of the input image is assigned. 25. The image coding apparatus according to claim 23, wherein the coded bit number allocating means is capable of newly allocating the number of coded bits for each area once allocated. 26. Means for designating a specific position or a part including a specific position so that a larger number of coded bits are assigned to a specific position or a part including the specific position in a screen. The image encoding device according to claim 23, 24 or 25, wherein: 27. A means for designating a specific position or a part including a specific position in a screen includes a specific position or a specific position from a plurality of predetermined specific position candidates or a plurality of candidate parts including the specific position. By selecting the parts,
27. The image encoding apparatus according to claim 26, wherein a specific position in the screen or a portion including the specific position is specified. 28. A means for designating a specific position or a portion including a specific position in a screen can be specified again in place of the specific position or a portion including the specific position in the screen once specified. Item 28. The image encoding device according to Item 26 or 27. 29. A means for evaluating the fineness of a picture for each partial image for an input image classified into a plurality of partial images, and correcting an evaluation value for each partial image based on positional information of the partial image in a screen. Means, means for allocating the number of coded bits of the partial image based on the corrected evaluation value for each partial image, and means for coding the partial image according to the coded bit number allocated therefor. Image encoding device. 30. The image encoding apparatus according to claim 29, wherein the means for correcting the evaluation value corrects the evaluation value of the area only when the area is located at a specific position in the screen. 31. The image encoding apparatus according to claim 29, wherein the means for modifying the evaluation value changes the degree of modification of the evaluation value according to position information of the area in the screen. 32. A means for correcting an evaluation value includes an image of an area located near the center of the screen, which is assigned a larger number of encoded bits, than an image of an area located near the periphery of the screen. 32. The image encoding device according to claim 29, wherein the evaluation value is corrected. 33. A system according to claim 33, further comprising means for designating a specific position on the screen or a portion including the specific position.
33. The image encoding device according to 30, 31, or 32. 34. A means for designating a specific position or a portion including a specific position in a screen includes a specific position or a specific position from a plurality of predetermined specific position candidates or a plurality of candidate portions including the specific position. By selecting the parts,
34. The image encoding device according to claim 33, wherein a specific position in the screen or a portion including the specific position is specified. 35. A system according to claim 30, further comprising means for changing a degree of correction of an evaluation value of a region included in a specific position or a portion including the specific position on the screen.
35. The image encoding device according to 34, wherein 36. A means for designating a specific position or a portion including a specific position in a screen, wherein the means for specifying a specific position or a portion including the specific position in the screen once specified can be newly specified. Item 35. The image encoding device according to Item 33, 34 or 35. 37. A means for calculating an information amount for each partial image for an input image classified into a plurality of partial images, and a means for weighting the information amount for each partial image based on positional information of the partial image in a screen. Means for assigning the number of encoded bits of the partial image based on the weighted information amount of each partial image, and means for encoding the partial image according to the assigned number of encoded bits. Image coding device. 38. A means for weighting the amount of information for each partial image is provided only when the region is located at a specific position on the screen.
38. The image encoding apparatus according to claim 37, wherein the information amount for each area is weighted. 39. The method according to claim 37, wherein the means for weighting the amount of information for each partial image varies the degree of weighting according to positional information of the partial image in the screen.
38. The image encoding device according to 38. 40. A means for weighting the amount of information for each partial image, such that a larger number of encoded bits is assigned to a partial image located near the center of the screen than a partial image located near the periphery of the screen. 40. The image encoding device according to claim 37, wherein the information amount is weighted for each partial image. 41. A system according to claim 41, further comprising means for designating a specific position on the screen or a portion including the specific position.
38. The image encoding device according to 38, 39 or 40. 42. A means for designating a specific position or a portion including a specific position in a screen includes a specific position or a specific position from among a plurality of predetermined specific position candidates or a plurality of candidate portions including the specific position. By selecting the parts,
42. The image encoding device according to claim 41, wherein a specific position in the screen or a portion including the specific position is specified. 43. A system according to claim 38, further comprising means for changing a degree of weighting of an information amount for each partial image included in a specific position or a part including the specific position in the screen.
39. The image encoding device according to 39, 4041 or 42. 44. A means for designating a specific position or a portion including a specific position in a screen can be specified again in place of the specific position or a portion including the specific position in the screen once specified. Item 44. The image encoding device according to Item 41, 42 or 43. 45. A step of evaluating fineness of a pattern for each area of an input image divided into a plurality of areas, a step of correcting an evaluation value of each area based on positional information of the area in a screen, and Allocating the number of coded bits of the input image based on the corrected evaluation value for each area, and encoding the input image of each area according to the allocated coded bit number. Image encoding method. 46. The image coding method according to claim 45, wherein the step of correcting the evaluation value corrects the evaluation value of the area only when the area is located at a specific position in the screen. 47. The image encoding method according to claim 45, wherein the step of correcting the evaluation value changes the degree of correction of the evaluation value according to position information of the area in the screen. 48. The step of correcting the evaluation value includes the step of assigning a larger number of coding bits to an image in an area located near the center of the screen than to an image in an area located near the periphery of the screen. 48. The image encoding method according to claim 45, wherein the evaluation value is corrected. 49. The image encoding method according to claim 46, further comprising the step of designating a specific position or a portion including the specific position in the screen. 50. A step of designating a specific position or a part including the specific position on the screen includes the specific position or the specific position from among a plurality of predetermined specific position candidates or a plurality of candidate parts including the specific position. 50. The image encoding method according to claim 49, wherein a specific position in the screen or a part including the specific position is designated by selecting the part. 51. The method according to claim 46, further comprising the step of changing a degree of correction of an evaluation value of a region included in a specific position or a portion including the specific position on the screen.
50. The image encoding method according to 8, 49 or 50. 52. A step of designating a specific position or a portion including a specific position in a screen, wherein the step of specifying a specific position or a portion including the specific position in the screen once specified can be performed again. The image encoding method according to claim 49, 50 or 51. 53. A step of calculating an information amount of each area of an input image divided into a plurality of areas, a step of weighting an information amount of each area based on positional information of the area in a screen, and Allocating the number of coded bits of the input image based on the information amount of each region, and coding the input image of each region according to the allocated coded bit number. Encoding method. 54. The step of weighting the amount of information for each area is performed only when the area is at a specific position in the screen.
54. The image encoding method according to claim 53, wherein the information amount for each area is weighted. 55. The image encoding method according to claim 53, wherein the step of weighting the amount of information for each area varies the degree of weighting according to positional information of the area in the screen. 56. The step of weighting the amount of information for each area includes assigning a larger number of coding bits to an image of an area located near the center of the screen than an image of an area located near the periphery of the screen. 56. The image encoding method according to claim 53, wherein the information amount for each area is weighted. 57. The image encoding method according to claim 54, further comprising the step of designating a specific position or a portion including the specific position in the screen. 58. The step of designating a specific position or a part including the specific position on the screen includes the specific position or the specific position from a plurality of predetermined specific position candidates or a plurality of candidate parts including the specific position. 58. The image encoding method according to claim 57, wherein a specific position in the screen or a part including the specific position is designated by selecting the part. 59. The method according to claim 54, further comprising the step of changing the degree of weighting of the information amount for each area included in the specific position or the portion including the specific position in the screen.
55. The image encoding method according to 55, 56, 57 or 58. 60. A step of designating a specific position or a portion including a specific position in a screen, wherein the step of specifying a specific position or a portion including the specific position in the screen once specified can be performed again. Item 57. The image encoding method according to Item 57, 58 or 59. 61. A step of evaluating the fineness of a picture for each partial image for an input image classified into a plurality of partial images;
Correcting the evaluation value of each partial image based on the position information of the partial image in the screen, and allocating the number of encoding bits of the partial image based on the corrected evaluation value of each partial image; Encoding the partial image in accordance with the number of encoded bits. 62. The image encoding method according to claim 61, wherein the step of correcting the evaluation value corrects the evaluation value of the area only when the area is located at a specific position in the screen. 63. The image encoding method according to claim 61, wherein in the step of correcting the evaluation value, the degree of correction of the evaluation value is changed according to position information of the area in the screen. 64. The step of correcting the evaluation value includes the step of assigning a larger number of coding bits to the image of the area located near the center of the screen than to the image of the area located near the periphery of the screen. 63. The image encoding method according to claim 61, wherein the evaluation value is corrected. 65. The image encoding method according to claim 62, further comprising the step of designating a specific position or a portion including the specific position in the screen. 66. The step of designating a specific position or a portion including the specific position in the screen includes the specific position or the specific position from a plurality of predetermined specific position candidates or a plurality of candidate portions including the specific position. 66. The image encoding method according to claim 65, wherein a specific position in the screen or a part including the specific position is designated by selecting the part. 67. The method according to claim 62, further comprising the step of changing the degree of correction of the evaluation value of the region included in the specific position or the portion including the specific position on the screen.
The image encoding method according to 4, 65 or 66. 68. A step of designating a specific position or a portion including a specific position in a screen, wherein the step of specifying a specific position or a portion including the specific position in the screen once specified can be performed again. Item 65. The image encoding method according to Item 65, 66 or 67. 69. A step of calculating an information amount of each partial image for an input image classified into a plurality of partial images, and a step of weighting an information amount of each partial image based on positional information of the partial image in a screen. Assigning the number of encoded bits of the partial image based on the weighted information amount of each partial image, and encoding the partial image according to the assigned number of encoded bits. Image coding method. 70. The method according to claim 69, wherein the step of weighting the amount of information for each partial image weights the amount of information for each region only when the region is located at a specific position in the screen. Image coding method. 71. The image coding method according to claim 69, wherein the step of weighting the information amount for each partial image varies the degree of weighting according to positional information of the partial image in the screen. Method. 72. The step of weighting the amount of information for each partial image includes a step of assigning a larger number of coding bits to a partial image located near the center of the screen than to a partial image located near the periphery of the screen. 72. The image encoding method according to claim 69, wherein the information amount is weighted for each partial image. 73. The image encoding method according to claim 70, further comprising the step of designating a specific position or a portion including the specific position in the screen. 74. The step of designating a specific position or a portion including the specific position on the screen includes the specific position or the specific position from a plurality of predetermined specific position candidates or a plurality of candidate portions including the specific position. 74. The image coding method according to claim 73, wherein a specific position on the screen or a part including the specific position is designated by selecting the part. 75. The method according to claim 75, further comprising the step of changing the degree of weighting of the information amount for each partial image included in the specific position or the part including the specific position in the screen.
70. The image encoding method according to 70, 71, 72, 73 or 74. 76. The step of designating a specific position or a portion including a specific position in a screen, wherein the step of specifying a specific position or a portion including the specific position in the screen once specified can be performed again. Item 73. The image coding method according to Item 73, 74 or 75.