JP4759209B2 - Image display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a brightness value that can be displayed on the same screen in a display device using a plasma display panel or the like that performs multi-gradation display by dividing one TV field of an image into a plurality of subfield images and displaying them. The present invention relates to an image display apparatus capable of displaying an image with a wide dynamic range by enlarging the ratio between the maximum value and the minimum value.
[0002]
Furthermore, the present invention provides a display device that displays a multi-tone display by dividing one TV field of an image into a plurality of sub-field images and displays a gradation disturbance in a halftone display that occurs during moving image display. The present invention relates to a multi-tone image display device that can be displayed with improvement.
[0003]
[Problems to be solved by the invention]
When a multi-tone image is displayed using a display panel that is based on binary display as in the case of using a plasma display panel or the like, one TV field of the image is divided into a plurality of subfields, and each subfield is displayed. There is known a method of displaying an image by giving a predetermined luminance weight to a field and controlling the presence or absence of light emission for each subfield.
[0004]
For example, in order to display 256 gradations, one TV field of the input image signal is divided into eight subfields, and the luminance weight of each subfield is set to “1”, “2”, “4”, “8”. , “16”, “32”, “64”, “128”. If the input image signal is an 8-bit digital signal, it is assigned to the eight subfield images in order from the least significant bit. Each subfield image is a binary image.
[0005]
On the other hand, in the image display using the CRT, the CRT itself has a so-called inverse gamma characteristic, and the minimum luminance value is “1” even if the maximum luminance value is a value corresponding to a value proportional to “255”. It becomes a value corresponding to a value proportional to the following decimal, and the so-called dynamic range is a sufficient value of 255 or more.
However, in the plasma display panel, the light emission characteristics are linear, and the gradation value is displayed as the sum of the light emission luminances that is approximately proportional to the weight of the subfield. Therefore, the minimum luminance value is a value corresponding to “1”, the maximum The luminance value is a value corresponding to the total weight “255” of each subfield, and since the minimum luminance value is larger than that of the CRT, the image display has a narrow dynamic range.
[0006]
On the other hand, increasing the number of subfields to increase the displayable gradation value is not easy due to restrictions such as the discharge speed of the plasma display, and the maximum value of the number of subfields that can normally be limited is limited.
Further, it is known that in the conventional method of displaying 256 gradations using 8 subfields, a so-called pseudo contour-like remarkable gradation disturbance occurs in moving image display.
[0007]
Therefore, as one method of eliminating this gradation disturbance, an attempt has been made to detect the motion of an image and change the encoding for each pixel or region.
This is because, for example, the encoding method is changed for each area of the image, and 256 gradation values are emitted with respect to the input 256 gradations in the still image portion, and the gradation values are limited in the moving image portion. To emit light. In this way, in the moving image portion, encoding is performed to ensure a certain degree of continuity of the change in the light emission pattern with respect to the monotonous change in the gradation value of the input image signal. Contour reduction can be expected. Further, the original sufficient gradation is ensured in the still image portion.
[0008]
However, with only such a conventional method, since the encoding is switched at the boundary between the moving image portion and the still image portion, a switching shock at this portion may be observed depending on the image. In particular, this switching shock may be seen in the vicinity of an image boundary where an object moves with a flat portion as a background.
The present invention has been made in view of the above-described problems, and is a display using a plasma display panel or the like that performs multi-gradation display by dividing and displaying one TV field of an image into a plurality of subfield images. A first object of the present invention is to provide an image display device capable of displaying an image with a truly wide dynamic range by expanding the ratio between the maximum value and the minimum value of luminance values that can be displayed on the same screen. To do.
[0009]
A second object of the present invention is to provide a multi-tone image display device which can display images with improved gradation disturbance in halftone display that occurs during moving image display, and which can display images without noticeable switching shock. To do.
[0010]
[ Task Means for solving the problem]
In order to achieve the first object, according to the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to An image display device that displays an image in multiple gradations, and includes a subfield having a luminance weight less than ½ of a luminance weight of a subfield having the next largest luminance weight.
[0011]
Further, the present invention is an image display device in which one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of the 1TV field in multiple gradations. The subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the i-th smallest luminance weight is W _i When W ₁ + W ₁ + W ₂ + ... + W _n <W _{n + 1} A luminance weight is assigned so that n is present.
[0012]
As a result, when all combinations of selectable luminance values (gradation values) are rearranged in the order of luminance values (gradation values), a portion where the luminance (gradation) jumps can be generated. Since the ratio of the maximum luminance value that can be expressed as follows can be increased as compared with the prior art, image display with a wide dynamic range can be realized.
[0013]
Further, the present invention is an image display device in which one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of one TV field in multiple gradations. The subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the jth smallest luminance weight is W _j When W _i + W ₁ + W ₂ + ... + W _n <W _{n + 1} The luminance weight is assigned such that n and i of 2 or more exist.
[0014]
As a result, when all combinations of selectable luminance values (gradation values) are rearranged in the order of luminance values (gradation values), a portion where the luminance (gradation) jumps can be generated, and thereby the minimum luminance value Since the ratio of the maximum luminance value that can be expressed as follows can be increased as compared with the prior art, image display with a wide dynamic range can be realized. Further, this allows the jump width of the luminance value to be controlled in accordance with the gradation value of the input image signal. For example, the higher brightness value allows the jump width of the brightness value, and further sets the maximum displayable brightness value. Can be set large.
[0015]
In the present invention, a 1TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of the 1TV field in multiple gradations. An image display device configured to control a maximum display luminance according to characteristics of an input image signal, wherein a TV field including a plurality of subfields configured by a combination of predetermined luminance weights is set as a reference TV field, The sum of the luminance weights of all the subfields in the coding pattern used to display the display TV field to be displayed at present is compared with the sum of the luminance weights of all the subfields in the coding pattern used when displaying the reference TV field. When the ratio is K, the symbol used to display the display TV field The sub-pattern has a luminance weight calculated by multiplying the luminance weight of the predetermined subfield in the reference TV field by a coefficient of K or less, and the luminance weight of the predetermined subfield in the reference TV field exceeds K And a subfield having a luminance weight calculated by multiplying by a coefficient.
[0016]
As a result, when trying to control the maximum luminance value that can be displayed according to the maximum gradation value of the image and the distribution level of the high gradation region, the minimum luminance value that can be displayed is always kept small, and the maximum luminance value that can be displayed Can be controlled as needed. In general, in an image including a relatively bright part, if the maximum luminance value that can be displayed more than necessary is increased, a display device such as a plasma display panel having a high correlation with light emission luminance and power consumption consumes power as a whole. Since it may increase, it is desirable to control the maximum displayable luminance value according to the content of the image. When performing such control, for example, even if the maximum luminance value that can be displayed is increased, for example, a subfield having a small luminance weight always maintains a relatively small value, while a subfield having a relatively large luminance weight is used. Since the luminance weight is changed according to the desired maximum displayable luminance value, the ratio between the minimum luminance value and the maximum luminance value can be increased, and the image can be displayed even if the maximum luminance value is displayed large. The portion close to the black level of the image does not rise, and the contrast is not impaired.
[0017]
Here, the coefficient equal to or less than K and the coefficient exceeding K may be coefficients set based on a rule defined by the order of the magnitude of the luminance weight of each subfield in the reference TV field.
Here, the coefficient set based on the rule defined by the order of the magnitudes of the luminance weights may be a coefficient that increases monotonously according to the order of the magnitudes of the luminance weights.
[0018]
Here, the coefficient set based on the rule defined by the order of the magnitudes of the luminance weights can be an equal coefficient according to the order of the magnitudes of the luminance weights.
Here, the coefficient set based on the rule defined by the order of the magnitudes of the luminance weights can be a ratio coefficient according to the order of the magnitudes of the luminance weights.
Here, the subfield belonging to the subfield group calculated by multiplying by a coefficient of K or less is a subfield fixed to a luminance weight obtained by multiplying a settable minimum value among a plurality of possible values among the K values. Can be included.
[0019]
Here, the approximate values of the ratios of the luminance weights of the three subfields selected in ascending order of the luminance weight of the subfield are “1: 2: 3”, “1: 2: 4”, “1: 2: 5”. , “1: 2: 6”, “1: 3: 7”, “1: 4: 9”, “2: 6: 12”, and “2: 6: 16”. The luminance weights of the subfields in at least two of the coding patterns determined according to the characteristics of the desired input image signal can be configured.
[0020]
Here, when the sum of the luminance weights of all the subfields is S, the selection is made when the gradation display corresponding to the value “R” of “0” or more and “S” or less is selected from each subfield. The combination of the subfields such that the sum of the luminance weights of the subfields is the sum of the luminance weights closest to the value “R” can be selected and displayed in gradation.
[0021]
As a result, gradation values that cannot be expressed only by combining a single subfield can be corrected by known gradation correction techniques such as error diffusion and dithering, so the minimum luminance value can be kept small and the maximum luminance that can be expressed. An image with a wide dynamic range can be displayed satisfactorily with smoothly corrected gradation while maintaining a large value.
[0022]
Here, the combination of luminance weights to be selected can be controlled by the amount of motion of the image or an approximate value of the motion of the image.
As a result, the minimum luminance value can be kept small and the maximum luminance value can be kept large, so that an image with a wide dynamic range can be displayed well with a smoothly corrected gradation, and at a portion where the image moves. It is also possible to suppress the occurrence of the moving image pseudo contour.
[0023]
Note that the generation of the moving image pseudo contour is caused by the movement of the line of sight relative to the screen on which the observer is displayed, but even if an image motion amount or an approximate value of the image motion is used, it is practical. An effect of suppressing sufficient pseudo contour is obtained.
Here, in a portion where the amount of motion of the image or the approximate value of the amount of motion of the image is large, the gradation distribution of the input image signal and the temporal distribution of the luminance weight arrangement pattern are limited to encoding having a monotonous increase correlation. Can be.
[0024]
This eliminates the control of the subfield from the ON state to the OFF state when the gradation value of the input image signal increases, or changes from the ON state to the OFF state when the gradation value of the input image signal increases. Since the luminance weight of the subfield to be controlled can be made relatively small, it is possible to display an image in which the generation of the moving image pseudo contour is further effectively suppressed.
[0025]
In order to achieve the second object, the present invention comprises a TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and the subfields can be expressed in combination. An image display device that performs different encoding according to the amount of motion by using a combination of different luminance weights depending on the amount of motion of the input image signal from the tone values, and displays an image of a desired 1 TV field in multiple gradations. In the encoding, the portion in which the image signal at the switching boundary portion of the encoding method has a predetermined characteristic is encoded so as to include a region in which a plurality of encoding methods are mixed. To do.
[0026]
In order to achieve the second object, the present invention comprises a TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and the subfields can be expressed in combination. An image display device for performing multi-tone display of an image of a desired 1 TV field by performing different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount of motion of the input image signal from among the tone values In the encoding, when the image signal at the switching boundary portion of the encoding method has a predetermined characteristic, the signal for switching the encoding method is irregularly shifted in the pixel direction. Features.
[0027]
In order to achieve the second object, the present invention comprises a TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and the subfields can be expressed in combination. An image display device for performing multi-tone display of an image of a desired 1 TV field by performing different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount of motion of the input image signal from among the tone values In the encoding, when the image signal at the switching boundary portion of the encoding method has a predetermined characteristic, the signal for switching the encoding method is regularly shifted in the pixel direction. It is characterized by.
[0028]
In order to achieve the second object, the present invention comprises a TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and the subfields can be expressed in combination. An image display device for performing multi-tone display of an image of a desired 1 TV field by performing different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount of motion of the input image signal from among the tone values In the encoding, in the portion where the image signal in the switching boundary portion of the encoding method has a predetermined characteristic, the shape in the switching boundary portion of the signal for switching the encoding method is changed to the pixel interval. It is characterized by having a shape including a polygonal line as a minimum unit as a main element.
[0029]
Even if a switching shock occurs in the image portion where the encoding method is switched by these, the generation position can be dispersed, so that the switching shock can be reduced while suppressing the moving image pseudo contour. This means that, for example, when the image encoding process is performed differently for the still image portion and the moving image portion, the transition to the encoding method switching can be performed smoothly.
[0030]
Here, the shape including a polygonal line having a pixel interval as a minimum unit as a main element can be a checkered pattern.
Here, the shape including a polygonal line having a pixel interval as a minimum unit as a main element can be a shape obtained by randomly combining polygonal lines having a pixel interval as a minimum unit.
[0031]
Here, the predetermined image portion of the portion where the image signal has a predetermined characteristic may be a non-edge portion of the image signal.
Thereby, in particular, it is possible to quickly switch the encoding method in the edge portion of the image after suppressing the encoding switching shock in the non-edge portion of the image in which the shock of encoding switching is easily noticeable. Encoding suitable for each region can be performed without degrading the average signal-to-noise ratio of the entire image.
[0032]
In order to achieve the second object, the present invention provides a 1TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and a gradation that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount of motion of the input image signal from among the values, and displays an image of a desired 1 TV field in multiple gradations In the encoding, a modulation signal having a period of at least a pixel interval is applied to an image signal at a switching boundary portion of the encoding method.
[0033]
In order to achieve the second object, the present invention comprises a 1TV field composed of a plurality of subfields each having a luminance weight arranged in time order, and a gradation that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount of motion of the input image signal from among the values, and displays an image of a desired 1 TV field in multiple gradations In the encoding, the image signal at the switching boundary portion of the encoding method is subjected to modulation for shifting the display position.
[0034]
Even if a switching shock occurs in the image portion where the encoding method is switched by these, the generation position can be dispersed, so that the switching shock can be reduced while suppressing the moving image pseudo contour. This means that, for example, when the image encoding process is performed differently for the still image portion and the moving image portion, the transition to the encoding method switching can be performed smoothly.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
An image display apparatus according to an embodiment will be specifically described below with reference to the drawings.
<Embodiment 1>
[Overall configuration]
The image display apparatus according to the present embodiment uses an AC plasma display panel (hereinafter referred to as “PDP”), and emits light of a predetermined number (for example, 10) of subfields having a predetermined number of times of light emission as a luminance weight. This is an image display device that displays halftones by expressing the gray scales in total.
[0036]
FIG. 1 is a block diagram showing a configuration of an image display apparatus according to the present embodiment of the present invention.
As shown in FIG. 1, the image display device includes an inverse gamma correction circuit 2, an adder circuit 3, a still image encoding circuit 4, a moving image encoding circuit 5, a motion detection circuit 6, and a selection circuit 7. , A subfield control circuit 8, a display control circuit 9, an AC plasma display panel 10 (hereinafter referred to as “PDP 10”), a difference circuit 11, a coefficient circuit group 12, and a delay circuit group 13. .
[0037]
The inverse gamma correction circuit 2 is a circuit that performs an exponential correction process that further suppresses the light emission luminance in a portion where the gradation value of the input image signal 1 is small. That is, it is configured to output a 12-bit image signal obtained by adding a decimal 4 bits of an 8-bit input image signal. This is because the input image signal 1 is normally based on the inverse gamma characteristic of the CRT. Therefore, when the light emission luminance is digitally controlled by the number of light emission pulses as in a PDP, the level of the input image signal is reduced. Since the tone value and the light emission luminance have a linear relationship, the gradation cannot be expressed correctly, and is provided to avoid this.
[0038]
The signal that has passed through the adder circuit 3 is supplied to the still image encoding circuit 4 and the moving image encoding circuit 5. The still image encoding circuit 4 includes a lookup table in which values to be converted are associated with each gradation value of each input image signal, and performs desired encoding based on this table. FIG. 2 shows a part of the lookup table. 2 indicates the value of the input image signal, and the horizontal column indicates the value of the signal to be converted from the input image signal.
[0039]
As shown in this figure, basically, encoding is performed to convert the signal to the same value as the input image signal, but in “4”, “9”, “14”,. Middle, thick line frame 41, etc.), and encodes a nearby signal with a value different from that of the input image signal ("5" for "4", "10" for "9") , “15” in the case of “14”). This corresponds to encoding in the subfield control circuit (encoding that divides into subfields having a predetermined luminance weight) and expresses all input image signals as some values, and continuously expresses luminance values. This is to cause a jump in the changing portion of the luminance value without changing to.
[0040]
The moving image encoding circuit 5 also includes a lookup table in which values to be converted are associated with each gradation value of each input image signal, and performs desired encoding based on this table. FIG. 3 shows a part of the lookup table. Note that the vertical column at the left end of FIG. 3 indicates the value of the input image signal, and the horizontal column indicates the value of the signal to be converted from the input image signal.
[0041]
As shown in this figure, basically, encoding is performed by converting the input image signal into a signal having the same value, but in “4”, “9”, “14”,. Similarly to the above, all the input image signals are expressed by some value and the luminance value is continuously changed in the same manner as described above. First, in order to cause a jump in the change portion of the luminance value, the signal is encoded into a signal in the vicinity of the gradation value with a value different from the input image signal (in the case of “4”, “5”, “9” "10" and "15" in the case of "14"). Further, the moving image encoding circuit 5 performs unique encoding not performed by the still image encoding circuit 4. That is, as shown in the column with the shaded area 51 in FIG. 3, in the predetermined input image signals having values such as “40”, “50”, “70”, “80”,. Although the sum of the luminance weights of the subfields can be displayed on the panel, the input image signal may have a value close to that (for example, an input image signal with a value of “40” so as to ensure the correlation between the input image signal and the light emission pattern). For example, if the input image signal has a value of “30” or “50”, it is converted into “60”.
[0042]
FIG. 4 is a block diagram showing a detailed configuration of the motion detection circuit 6.
As shown in this figure, the motion detection circuit 6 includes two frame memories 61A and 61B for storing each frame of the image signal supplied from the inverse gamma correction circuit, a difference circuit 62, and a motion detection signal generation. Circuit 63.
As a result, the difference circuit 62 reads the image signal from the frame memories 61A and 61B, compares the frame to be displayed from the previous frame with the image signal for the previous two frames and calculates the difference value for each pixel. The difference value is supplied to the motion detection signal generation circuit 63. The motion detection signal generation circuit 63 determines that the difference value exceeds the reference value, and determines that the moving image is the reference value. Is generated and output to the selection circuit 7.
[0043]
Next, the selection circuit 7 is supplied from the still image encoding circuit 4 and the moving image encoding circuit 5 with a motion detection signal indicating whether the image is a still image or a moving image supplied from the motion detection circuit as a selection signal. One of the image signals is selected and supplied to the subfield control circuit 8 and the difference circuit 11.
FIG. 5 is a block diagram showing a configuration of the subfield control circuit 8.
[0044]
As shown in this figure, the subfield control circuit 8 includes a subfield conversion circuit 81, a write address control circuit 82, and frame memories 83A and 83B.
The write address control circuit 82 generates an address designation signal for designating a write address to the frame memory based on the horizontal synchronization signal (Hsyc) and the vertical synchronization signal (Vsyc) separated from the image signal.
[0045]
The subfield conversion unit 81 is a circuit that receives the supply of the image signal from the selection circuit 7 and converts the image signal corresponding to each pixel into 10-bit field information having a predetermined weighting determined in advance. . Specifically, a predetermined table is used by a look-up table in which information to be converted is determined according to the gradation level of the input image signal (the signal before passing through the still image coding circuit and the moving image coding circuit). The image signal is divided into a number of subfields. Note that the division processing for each pixel is performed in synchronization with a pixel clock generated by a PLL circuit (not shown).
[0046]
The field information is a set of 1-bit subfield information indicating which time zone in one TV field, that is, which subfield is lit / unlit. Here, the field information corresponding to each pixel generated in this manner is designated by a physical address by an address designation signal from the write address control circuit 82 and is stored in the frame memories 83A and 83B for each line, each pixel, and each field. Written every screen.
[0047]
FIG. 6 shows the correspondence with information to be converted in accordance with the gradation level of the input image signal in the subfield conversion unit 81.
In FIG. 6, each input signal is assigned to “1”, “2”, “5”, “10”, “20”, “33”, “48”, “66”, “87”, “111” in time order. In this table, the correspondence between the input image signal for converting into the on / off information of the 10-bit subfields SF1 to SF10 having luminance weights that change and the combination of the converted subfields is shown. The vertical column indicates the value of the input image signal, and the horizontal column indicates 10-bit field information to be converted from the input image signal. In this figure, the subfield marked “1” is “ON (lit)”, and the other subfields indicate that the field period is “OFF (non-lit)” (the same applies hereinafter). .
[0048]
For example, in the subfield conversion circuit 81, if the image signal is “40” (the column indicated by the thick line frame 84), the subfield of luminance weights “2”, “5”, “33” is converted into the image signal. It is converted into 10-bit data “0000100110” combined and output. Note that the bit expression here is a notation in which the subfield number and the digit in the bit expression correspond to each other.
[0049]
Next, each of the frame memories 83A and 83B has an internal structure as shown in FIG. That is, the frame memory 83A includes a first memory area 83A1 that stores field information corresponding to the first half of one screen (1 to L (240 lines)), and a first half (1 to L (1 240) a second memory area 83A2 for storing field information corresponding to line).
[0050]
The frame memory 83B includes a first memory area 83B1 for storing field information corresponding to the second half of one screen (L + 1 to 2L (480) lines), and the second half of another screen (L + 1 to 2L (480). ) Line) and a second memory area 83B2 for storing field information.
The memory areas of the first memory area 83A1 (first memory area 83B1) and the second memory area 83A2 (second memory area 83B2) each include ten subfield memories SFM1 to SFM10. . With this configuration, field information relating to a combination of 10-bit subfields corresponding to two screens divided into a front half and a rear half for one screen is subfield memory SFM1 as information on lighting / non-lighting of each subfield. Written in SFM10. In the present embodiment, the subfield memories SFM1 to SFM10 are semiconductor memories having 1-bit input and 1-bit output. The frame memories 83A and 83B are two-port frame memories capable of simultaneously writing field information and reading to the display control circuit 9.
[0051]
The field information is written to the frame memories 83A and 83B by transferring the field information of the first half of one screen to the first memory 83A1, and the field information of the second half of the one screen to the first memory 83B1. Then, the two frame memories 83A are configured such that the field information of the first half of the next screen is transferred to the second memory area 83A2, and the field information of the latter half of the other screen is transferred to the second memory area 83B2. , 83B are alternately performed on the four memory areas 83A1, 83B1, 83A2, or 83B2. The field information is written into one memory area 83A1, 83B1, 83A2, and 83B2 by transferring 10-bit data output from the subfield conversion circuit 81 in synchronization with the pixel clock to 10 subfield memories SFM1 to SFM10. It is executed in such a way that it is distributed and written bit by bit. Which bit of 10-bit data is stored in which subfield memory SFM1 to SFM10 is predetermined.
[0052]
The display control circuit 9 comprises a display line control circuit 91, address drivers 92A and 92B, and a line driver 93 as shown in FIG.
The display line control unit 91 designates the memory areas 83A1, 83B1, 83A2 or 83B2, lines, and subfields to be read out to the PDP 10 in the frame memories 83A and 83B, and issues an instruction on which line of the PDP 10 is to be scanned. Is.
[0053]
The operation of the display line control unit 91 is synchronized with the writing operation to the frame memories 83A and 83B in the subfield control circuit 8 in the order of screen units. That is, the display line control unit 91 does not read the 10-bit data from the memory areas 83A2 and 83B2 (83A1 and 83B1) that are being written, but reads from the memory areas 83A1 and 83B1 (83A2 and 83B2) that have already been written. I do.
[0054]
The address driver 92A converts the subfield information corresponding to one line serially input bit by bit based on the memory area designation, read line designation and subfield designation of the display line control section 91 into the number of pixels for one line. Corresponding bits (640 bits) are converted into address pulses in parallel and output to the first half of the screen. The address driver 92B converts the subfield information into an address pulse and outputs it to the second half of the screen in the same manner as the line driver 92A.
[0055]
The line driver 93 designates to which line of the PDP 10 subfield information is written by a scanning voltage pulse.
With such a configuration of the display control circuit 9, the field information is read from the frame memories 83A and 83B to the PDP 10 as follows. Reading of field information for one screen that is divided and written in the frame memories 83A and 83B is performed by simultaneously reading data corresponding to the first half and the second half. That is, the subfield information is sequentially read out from the subfield memories SFM1, SFM2,..., SF10 for each pixel from the memory areas 83A1, 83B1. More specifically, first, subfield information corresponding to each pixel on the first line is sequentially read out bit by bit from the subfield memory SFM1 in both the memory areas 83A1 and 83B1. Then, after waiting for the line designation by the line driver 93, a latent image is formed on each first line of the first and second half screens (addressing), and then each pixel on the second line of the first and second half screens from the same subfield memory SFM1. In the same manner, the subfield information corresponding to 1 is read out and serially input to the address drivers 92A and 92B, and the bit corresponding to the number of pixels in one line, here 640-bit subfield information is output in parallel to the PDP 10 for addressing. Done. When such reading (writing) is completed up to the last line in each divided area divided into the screen, the number of discharge pulses corresponding to the luminance weight of the subfield SF1 is applied by the address driver, and the pixels are simultaneously emitted. The
[0056]
After the subfield information relating to lighting / non-lighting of the next subfield SF2 is read line by line in the same manner as described above, the addressing is performed, and then this operation is repeated until the subfield SF10. Reading (writing) is completed.
FIG. 9 shows the operation method of such a PDP. In FIG. 9, the horizontal axis indicates the time, the vertical axis indicates the number of the electrode extending in the horizontal direction of the PDP, that is, the scanning / discharge sustaining electrode, and the address of the pixel to emit light is designated by the shaded area and shaded. The pixel is caused to emit light at the portion. That is, addressing is performed by applying address pulses to the address electrodes that run in the vertical direction in accordance with the timing at which the subfield SF1 starts for all the horizontal pixels on the scan / discharge sustaining electrodes on the first line of each divided screen. Do. When the addressing of the first line of the scan / discharge sustaining electrode is completed, the same operation is repeated on the subsequent lines. When the addressing of the last scan / discharge sustaining electrode is completed in the divided screen, the process proceeds to the discharge sustaining period from time t1 to t2. During this period, a number of sustaining pulses proportional to the weighting are applied to the sustaining electrodes, but only the pixels that are instructed to emit light by the address designation are made to emit light. As will be described repeatedly, the gradation display for one TV field is completed by repeating the operations of addressing in the subfield and simultaneous lighting of all the pixels as described above.
[0057]
Then, the field information corresponding to the first half and the second half of the next screen written in another memory area in parallel with the reading is read in the same manner as described above, thereby displaying images one after another.
Next, the adder circuit 3, the difference circuit 11, the coefficient circuit group 12, and the delay circuit group 13 will be described.
[0058]
The difference circuit 11 is a circuit that calculates a difference between the image signal output from the selection circuit and the image signal that has passed through the addition circuit 3, and supplies the difference signal to each circuit of the coefficient circuit group 12.
The coefficient circuit group 12 has coefficients of 7/16, 1/16, 5/16, and 3/16.
[0059]
The delay circuit group 13 delays a signal that has passed through the coefficient circuit group 12, and specifically, one pixel (1D), one line (1H) +1 pixel (1D), one line (1H), one line (1H) -1 pixel (1D) is delayed.
The adder circuit 3 adds the image signal that has passed through the inverse gamma correction circuit 2 and the signal that has passed through the delay circuit group 13, and supplies the result to the still image encoding circuit 4, the moving image encoding circuit 5, and the difference circuit 11. To do.
[0060]
By the adder circuit 3, the difference circuit 11, the coefficient circuit group 12, and the delay circuit group 13, the difference between the gradation value that should be originally displayed and the gradation value that is actually displayed is distributed to surrounding pixels. A so-called error diffusion loop is formed.
[About the effects]
First, by setting the luminance weighting in each subfield as described above, the resolution in the low gradation value portion equivalent to that of the conventional image display device using the PDP is maintained, but cannot be obtained by the conventional one. A wide dynamic range is realized.
[0061]
FIG. 10 is a characteristic diagram and chart showing the correlation between the value of the input image signal and the light emission luminance.
As shown in FIGS. 10A and 10B, in the low gradation value portion, the light emission luminance changes smoothly and gently with respect to the input change in both the still image and the moving image. For example, when the input values are “0”, “1”, “2”, “3”, “4”, “5”, “6”, “0”, “1”, “1”, “2”, “2”, “3”, “3”.
[0062]
On the other hand, as shown in FIG. 10C, when light is emitted in a high gradation value portion, for example, all subfields, the maximum luminance value is “1 + 2 + 5 + 10 + 33 + 48 + 66 + 87 + 111” = “383”, which is a conventional “ A maximum luminance value of 1.5 times the maximum luminance value of “255” is obtained, and an image can be expressed with a wide dynamic range.
[0063]
The dynamic range can be expanded in this way when the combinations of all luminance values (gradation values) that can be selected in the subfield control circuit are rearranged in order of luminance values (gradation value order). (Gradation value) can be caused to jump (the gradation value of the input image signal is “4”, “9”, “14”, etc.). This is because the ratio can be made larger than in the conventional case.
[0064]
Here, the luminance weight setting condition is important for jumping the luminance value. That is, the predetermined luminance weight (for example, the luminance weight “2” of the subfield SF2) and the luminance weight of the subfield having the next largest luminance weight (in the above example, the luminance weight “5” of the subfield SF3). Set to be less than 1/2.
In other words, the subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the i-th smallest luminance weight is expressed as W. _i When W ₁ + W ₁ + W ₂ + ... + W _n <W _{n + 1} It can also be said that the luminance weight is assigned so that n exists. In the above example, n = 2.
[0065]
In order to increase the dynamic range, it is necessary to increase the value at which the luminance value jumps. Therefore, in this case, the subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the jth smallest luminance weight is set to W. _j When W _i + W ₁ + W ₂ + ... + W _n <W _{n + 1} The luminance weight is assigned so that n and i of 2 or more exist. As a result, the dynamic range can be further expanded.
[0066]
Next, in the case of a moving image, as described above, only the image signal having a value limited to a part of the gradation value used for displaying the still image is used. For example, as shown in the column with shading 51 in FIG. 3, the input image signals having values of “40” and “50” use image signals converted to “30” and “60”, respectively. .
What if we don't do this conversion? That is, normally, an image signal having a value of “40” emits light in three subfields having luminance weights “2”, “5”, and “33”, and an image signal having a value of “30” is obtained. The subfield of the luminance weight “20” emitted when displaying is turned off.
[0067]
For this reason, the correlation between the gradation value of the input image signal and the light emission pattern is lost, and the occurrence of a moving image pseudo contour is observed in the moving image portion.
Here, in the moving image portion, as shown in the example in which the gradation value of the input image signal of “40” is displayed by replacing it with the image signal of “30”, in the image display device according to the present embodiment, When the gradation value of the input image signal increases, the control of the subfield from the on state to the off state is lost, or when the gradation value of the input image signal increases, the control is switched from the on state to the off state. Since the luminance weight of the subfield can be made relatively small, it is possible to display an image while suppressing the generation of the moving image pseudo contour.
[0068]
Further, as described above, the still image encoding circuit 4 and the moving image encoding circuit 5 perform encoding that converts a predetermined input image signal into a value different from the original gradation value. There is a large difference from the gradation value actually displayed on the PDP, and it cannot be said that the image can be displayed correctly.
Therefore, the gradation value to be originally displayed on the peripheral pixels is actually displayed by the error diffusion loop formed by the adder circuit 3, the difference circuit 11, the coefficient circuit group 12, and the delay circuit group 13 as described above. A process of allocating the difference from the gradation value is performed.
[0069]
As a result, the gradation jump is compensated for and a good gradation display is performed.
Note that, in the present embodiment, the above contents are only examples for the number of subfields and the luminance weight in each subfield, and the present invention is not limited to this. In particular, when the number of subfields can be increased, a subfield with a smaller luminance weight is added to improve gradation resolution at low luminance, or a subfield with a larger luminance weight is added. Needless to say, the maximum luminance value can be improved.
[0070]
<Embodiment 2>
FIG. 11 is a block diagram showing a configuration of the image display apparatus according to the present embodiment of the present invention.
As shown in FIG. 11, the image display apparatus is obtained by adding a display gradation magnification setting circuit 14 to the configuration of the image display apparatus according to the first embodiment, and according to the maximum gradation value of the input image signal. Thus, the second embodiment is different from the first embodiment in that the encoding in the still image encoding circuit 4, the moving image encoding circuit 5, and the subfield control circuit 8 is switched. Hereinafter, differences will be described. For the sake of simplicity, the description here assumes that the input image signal is a signal in the range of about 22 to 110 gradations.
[0071]
The display gradation magnification setting circuit 14 is the magnification of the maximum gradation value of an image of one frame (1 TV field) to be displayed (hereinafter referred to as this value) with respect to the reference gradation value (22 gradations). The K value is described as “K value”, which is the display TV field to be displayed at present with respect to the sum of the luminance weights of all the subfields used when displaying the reference TV field. The ratio of the sum of luminance weights of all subfields used when displaying “.” Is calculated, and the calculated K value is used as the still image encoding circuit 4, the moving image encoding circuit 5, and the subfield control circuit. 8 is supplied.
[0072]
The still image encoding circuit 4, the moving image encoding circuit 5, and the subfield control circuit 8 perform predetermined encoding based on the K value.
First, the still image encoding circuit 4 performs predetermined encoding for each of the K values of 1, 2, 3, 4, and 5. If K = 1, a gradation value (luminance value) is used. ) Is performed such that jumping occurs. Such encoding is performed by a plurality of lookup tables (similar to those shown in FIG. 2) in which input image signals and gradation values to be converted (encoded) are associated for each K value. ). In encoding at values of K = 2, 3, 4, 5 respectively, gradation values (luminance values) are continuously displayed as shown in the leftmost column of FIGS. ) Does not change and a specific gradation value (luminance value) jumps.
[0073]
The moving image encoding circuit 5 also performs predetermined encoding for each of the K values 1, 2, 3, 4 and 5, except for the case where K = 1, the gradation value (luminance value). ) To perform a jump. Further, encoding limited to an image signal having a specific gradation value is executed (the signal is limited to a signal having a specific gradation value so as not to use an image signal marked with a star on the left side of each figure in FIG. 14). Similarly, in FIG. 26 described later, the signal is limited to a signal having a specific gradation value so as not to use the image signal with a star. Such encoding is performed by a plurality of lookup tables (similar to those shown in FIG. 3) in which input image signals and gradation values to be converted (encoded) are associated for each K value. ).
[0074]
Next, in each of the cases where the K value is 1, 2, 3, 4 and 5, the subfield control circuit 8 uses the determined encoding table (lookup table) to preliminarily output the image signal corresponding to each pixel. Here, the information is converted into 5-bit field information having a predetermined weight.
Normally, when the encoding in the subfield control circuit is switched based on the value of the K value, as shown in FIGS. 12A to 12E, a reference encoding pattern (here shown in FIG. 12A) is used. Using a coding pattern in which the luminance weight in each subfield is set to the luminance weight obtained by multiplying the luminance weight by the luminance value in the pattern in which the luminance weight of each subfield is “1, 2, 3, 6, 10” in time order) Each pixel in a frame having a K value is displayed. However, even though the luminance value to be displayed can be increased, the dynamic range of the gradation value to be displayed cannot be expanded. That is, as shown in FIGS. 13A to 13E, in the correlation between the input image signal and the light emission luminance, the luminance increases with respect to the input in the low gradation portion (the circle frame 201 in the drawing). The resolution in the low gradation value portion is also reduced, and the dynamic range cannot be expanded. In FIG. 13, the right figure is an enlargement of the left figure and shows the same contents (the same applies to FIG. 15).
[0075]
On the other hand, in the image display apparatus according to the present embodiment, as shown in FIGS. 14A to 14E, a reference coding pattern (here, each subfield is arranged in the time order shown in FIG. 14A). In the luminance weight in the pattern in which the luminance weight is “1, 2, 3, 6, 10”), a value obtained by multiplying the luminance weight of the low luminance by a value equal to or less than the K value is set as the luminance weight, and the high luminance Each pixel in a frame having the corresponding K value is displayed using an encoding pattern in which the luminance weight is set to a value obtained by multiplying the luminance weight by a value exceeding the K value.
[0076]
The coefficient multiplied by the luminance weight can be a coefficient that increases monotonously according to the order of the luminance weight.
Further, the coefficient to be multiplied by the luminance weight can be a coefficient that changes in an equal manner depending on the order of the luminance weight.
In addition, the coefficient to be multiplied by the luminance weight can be a coefficient that changes in proportion according to the order of the luminance weight.
[0077]
In particular, in order to further expand the dynamic range, it is effective to use a coefficient that changes in an equivalent ratio.
Specifically, for each K value, the coefficient to be multiplied by the luminance weight “1, 2, 3, 6, 10” is K = 2; 1, 1.5, 2, 1.83, 2. 3, when K = 3; 1, 2, 2.67, 1.83, 2.83, 3.6, when K = 4; 1, 2.5, 4, 3.83, 4.7, In the case of K = 5: 2, 3.5, 4.67, 4.83, 5.8.
[0078]
Here, for example, in the case of K = 2 and K = 3, the subfield belonging to the subfield group calculated by multiplying by a coefficient equal to or less than the K value is among a plurality of possible values among the K value values. By including the subfield fixed to the luminance weight multiplied by the minimum value (coefficient: 1) that can be set in (1), an increase in luminance with respect to the input in the low gradation portion is suppressed. Further, as the K value increases, the value of the coefficient to be multiplied by the luminance weight of the reference coding pattern is generally increased in order to increase the maximum luminance value.
[0079]
That is, image display is performed using a coding pattern composed of a subfield group having a luminance weight multiplied by a coefficient equal to or less than the K value and a subfield group having a luminance weight multiplied by a coefficient exceeding the K value.
By setting luminance weighting in this way, not only the luminance value to be displayed can be increased, but also the dynamic range of the gradation value to be displayed can be expanded. That is, as shown in FIGS. 15A to 15E, in the correlation between the input image signal and the light emission luminance, the luminance is kept small with respect to the input in the low gradation portion (circular frame 202 in the drawing). In addition, the resolution in the low gradation value portion can be maintained and the dynamic range can be expanded.
[0080]
Furthermore, in order to increase the dynamic range as the K value increases, it is necessary to increase the value at which the luminance value jumps. Therefore, the ratio of the value multiplied by the high luminance luminance weight and the value multiplied by the low luminance luminance weight is larger in the TV field with a larger K value. As a result, the subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the jth smallest luminance weight is set to W. _j When W _i + W ₁ + W ₂ + ... + W _n <W _{n + 1} In a TV field with a large K value such that n and i of 2 or more exist, a luminance weight can be assigned.
[0081]
In the above example, W ₁ = 1, W ₂ = 5, W _Three = 12, W _Four = 23, W _Five = 47, W ₂ + W ₁ + W ₂ + ... + W _Four (46) <W _{4 + 1} There are n = 4 and i = 2 which become (47).
Thus, in a TV field with a large K value, the dynamic range can be effectively expanded by further increasing the degree of jump of the luminance value.
[0082]
Note that the present invention is not limited to the combination of the luminance weights, and the approximate values of the luminance weight ratios are “1: 2: 3”, “1: 2: 4”, “1: 2: 5”, “1: 2: If a combination including any two or more of “6”, “1: 3: 7”, “1: 4: 9”, “2: 6: 12”, and “2: 6: 16” is used, Since the value jumps, the dynamic range can be expanded.
[0083]
Further, by using the error diffusion loop as in the first embodiment, a process of distributing the difference between the gradation value that should be originally displayed to the surrounding pixels and the gradation value that is actually displayed is performed. Therefore, it is possible to compensate for the jump of the gradation and to perform a good gradation display.
<Third embodiment>
FIG. 16 is a block diagram showing a configuration of the image display apparatus according to the present embodiment.
[0084]
As shown in FIG. 16, the image display device further includes a spatial modulation circuit 15 that performs spatial modulation on the motion detection signal from the motion detection circuit 6, and the spatial modulation circuit 15 in addition to the image display device according to the first embodiment. And a random number generation circuit 16 for supplying a random number value to the. Hereinafter, differences from the first embodiment will be described.
FIG. 17 shows an example of an input image and a motion detection result in the present embodiment.
[0085]
Assuming that the triangular object 203 shown in FIG. 17A has moved to the right as shown in FIG. 17B, the motion portion detected from the TV field before and after the input image signal is the black portion shown in FIG. 204.
On the other hand, the random number generation circuit 16 generates a random number from “−3” to “3”, for example, and the value is supplied to the spatial modulation circuit 15, and the spatial modulation circuit 15 only applies to the pixel corresponding to the generated random number. The pixel position of the motion detection signal of the signal c) is shifted in the horizontal direction or the vertical direction, and a motion signal represented by the black portion 205 in FIG. 17D is obtained as a selection circuit switching signal.
[0086]
Conventionally, encoding was performed by switching between a still image portion and a moving image portion using the motion detection signal shown in FIG. 17C. However, if the shape of the region of the switching signal is linear, the light emission pattern associated with the switching is also changed. There was a tendency to line up, resulting in switching shocks.
On the other hand, when the encoding switching signal shown in FIG. 17D is used, the boundary portion has a random shape. Therefore, when encoding switching is performed using such a signal, Since a region in which different still image encoding methods and moving image encoding methods are mixed is formed at the switching boundary portion, the temporal characteristics of light emission in the PDP 10 are also changed as the encoding is switched. Therefore, it becomes difficult to switch the encoding, and the switching between the still image encoding portion and the moving image encoding portion can be performed smoothly.
[0087]
The above effect is recognized if the shape of the boundary portion of the switching signal is not a straight line. In the above description, the pixel position is irregularly shifted. However, the pixel position may be regularly shifted. Further, the above-described effect can be obtained even if the switching signal has a shape that includes a polygonal line having a pixel interval as a minimum unit as a main element.
<Embodiment 4>
FIG. 18 is a block diagram showing a configuration of the image display apparatus according to the present embodiment.
[0088]
As shown in FIG. 18, the image display device further includes a signal modulation circuit 17 that performs amplitude modulation on the motion detection signal from the motion detection circuit 6, and the signal modulation circuit 17 in addition to the image display device according to the first embodiment. In addition, a boundary detection circuit 18 for supplying a signal indicating a boundary portion between the moving image and the still image is added. Hereinafter, differences from the first embodiment will be described.
[0089]
FIG. 19 shows an example of an input image and a motion detection result in this embodiment.
If the triangular object 206 shown in FIG. 19 (a) has moved to the right as shown in FIG. 19 (b), the motion part detected from the TV field before and after the input image signal is the black part shown in FIG. 19 (c). It becomes like 207.
On the other hand, the boundary detection circuit 18 detects a boundary portion where the value of the detected motion detection signal changes, and based on this signal, the signal modulation circuit 17 modulates only the boundary portion of the motion detection signal in the amplitude direction of the signal. As a switching signal of the selection circuit, a signal represented by the peripheral portion 208A of the black portion 208 in FIG. 19D is obtained. In FIG. 19 (d), the modulation signal is drawn in a checkered pattern.
[0090]
If a switching signal modulated at the boundary between a moving image and a still image is used as described above, the boundary portion has a random shape as described above. Therefore, a still image encoding method and a moving image encoding are performed at the switching boundary portion. Since a region in which different encoding methods are mixed is formed, when the encoding is switched using such a signal, the temporal characteristics of the light emission in the PDP 10 are associated with the switching of the encoding. The change is not made uniform, it becomes difficult to notice that the encoding is switched, and the switching between the still image encoded portion and the moving image encoded portion can be performed smoothly.
[0091]
In addition, since the encoding method is modulated at the boundary between the moving image and the still image, the encoding switching shock is suppressed from being conspicuous, and the coding is performed in an area where it is certain that the still image portion and the moving image portion are present. The encoding method can be fixed, and an unnecessary image switching can be suppressed to display an image without deterioration in the signal-to-noise ratio.
[0092]
In FIG. 19, the signal for modulating the boundary of the motion detection signal shows a regular pattern. However, the same effect can be obtained when the modulation method at the detected boundary portion is a method using random numbers.
<Embodiment 5>
FIG. 20 is a block diagram illustrating a configuration of the image display apparatus according to the present embodiment.
[0093]
As shown in FIG. 20, the image display apparatus differs from that in the fourth embodiment in that an adder circuit 19 and a random number generator circuit 20 (here, “1”, “0”) are used as signal modulation circuits. , A random number value of “−1” is generated), and three image encoding circuits 21, 22, and 23 are selected instead of the still image encoding circuit 4 and the moving image encoding circuit 5. A selection circuit 24 having three signal inputs is provided in place of the circuit 7, and the motion detection circuit 6 is a point that detects the amount of motion of the image in three stages.
[0094]
Each of the image encoding circuits 21, 22, and 23 performs encoding in stages as shown in FIGS. That is, the still image portion is encoded with emphasis on gradation characteristics as shown in FIG. 21 (a), and the moving image portion has gradations that are unlikely to generate moving image pseudo contours as shown in FIGS. 21 (b) and 21 (c). Limited encoding. FIG. 21A shows coding performed in an intermediate motion part, and FIG. 21C shows code performed in a relatively large motion part.
[0095]
On the other hand, the motion detection detection circuit 6 similarly detects the motion of the image in three stages in a stepwise manner, further obtains a boundary portion where the motion detection signal changes by the boundary detection circuit 18, and generates a random number in this portion by the random number generation circuit 20. In the adding circuit 19, a signal having a value obtained by adding a random value to the value of the motion detection signal is generated and used as a switching signal for the selection circuit 23.
[0096]
With the above operation, the encoding method can be fixed in the parts that are sure to be the still image portion and the moving image portion, and image display without deterioration of the signal-to-noise ratio by suppressing unnecessary encoding method switching. In addition, it is possible to smoothly perform the switching by performing the intermediate encoding and performing the encoding switching step by step in the portion located between the still image region and the moving image region. In addition, since the switching control signal is modulated at the boundary of encoding switching, the conspicuous encoding switching shock is further suppressed.
[0097]
<Embodiment 6>
FIG. 22 is a block diagram showing a configuration of the image display apparatus according to the present embodiment.
As shown in FIG. 22, the image display apparatus includes the boundary detection circuit 18 and a random number generation circuit 20 (here, it is assumed that a random number of “0” or “1” is generated), and further. Instead of the signal modulation circuit 17 of the image display apparatus according to the fourth embodiment, signal modulation circuits 25 and 26 for performing amplitude modulation on the output signals from the still image coding circuit 4 and the moving image coding circuit 5 are provided. Yes.
[0098]
FIG. 23 shows an example of an input image and a motion detection result in the present embodiment.
If the triangular object 209 shown in FIG. 23 (a) moves to the right as shown in FIG. 23 (b), the motion part detected from the TV field before and after the input image signal is the black part shown in FIG. 23 (c). 210.
On the other hand, the boundary detection circuit 18 obtains a boundary portion where the motion detection signal changes, and a random number is generated by the random number generation circuit 20 in this portion and used as an operation switching signal for the signal modulation circuit 25 and the signal modulation circuit 26.
[0099]
Then, the signal modulation circuits 25 and 26 modulate the image signal in the amplitude direction, and the image signals from the signal modulation circuit 25 and the signal modulation circuit 26 are selected by the selection circuit using the motion detection signal as a switching signal. As a result, the image signal that has passed through the selection circuit is represented by the black portion 211 in FIG. In FIG. 23 (d), the image signal is depicted as being modulated in a checkered pattern.
[0100]
If an image signal modulated at the boundary between a moving image and a still image is used as described above, the image at the boundary has a random shape as described above. Since a region in which encoding methods with different encoding methods are mixed is formed, the temporal characteristics of light emission in the PDP 10 do not change with the switching of the encoding, and the encoding is switched. It becomes inconspicuous, and the switching between the still image encoded portion and the moving image encoded portion can be performed smoothly.
[0101]
In addition, since the encoding method is modulated at the boundary between the moving image and the still image, the encoding switching shock is suppressed from being conspicuous, and the coding is performed in an area where it is certain that the still image portion and the moving image portion are present. The encoding method can be fixed, and an unnecessary image switching can be suppressed to display an image without deterioration in the signal-to-noise ratio.
[0102]
<Embodiment 7>
FIG. 24 is a block diagram showing a configuration of the image display apparatus according to the present embodiment.
As shown in FIG. 24, the image display device uses a space for the image signals from the still image coding circuit 4 and the moving image coding circuit 5 instead of the spatial modulation circuit 15 of the image display device according to the third embodiment. Spatial modulation circuits 27 and 28 for performing modulation are provided. Hereinafter, differences from the third embodiment will be described.
[0103]
FIG. 25 shows an example of an input image and a motion detection result in this embodiment.
If the triangular object 212 shown in FIG. 25 (a) has moved to the right as shown in FIG. 25 (b), the motion part detected from the TV field before and after the input image signal is the black part shown in FIG. 25 (c). It becomes like 213.
On the other hand, the random number generation circuit 16 generates random numbers from “−3” to “3”, for example, and supplies the values to the spatial modulation circuits 26 and 28. The spatial modulation circuits 27 and 28 correspond to the generated random numbers. Only the pixel position of the image signal of the moving image portion of FIG. 25C is shifted in the horizontal direction or the vertical direction, and the spatially modulated signal is selected by the selection circuit using the signal from the motion detection circuit as a switching signal, and the moving image In the portion, an image signal represented by a black portion 214 in FIG.
[0104]
If an image signal modulated at the boundary between a moving image and a still image is used as described above, the image at the boundary has a random shape as described above. Since a region in which encoding methods with different encoding methods are mixed is formed, the temporal characteristics of light emission in the PDP 10 do not change with the switching of the encoding, and the encoding is switched. It becomes inconspicuous, and the switching between the still image encoded portion and the moving image encoded portion can be performed smoothly.
[0105]
In addition, since the encoding method is modulated at the boundary between the moving image and the still image, the encoding switching shock is suppressed from being conspicuous, and the coding is performed in an area where it is certain that the still image portion and the moving image portion are present. The encoding method can be fixed, and an unnecessary image switching can be suppressed to display an image without deterioration in the signal-to-noise ratio.
[0106]
In the third to seventh embodiments, this portion is limited to a non-edge portion in which the gradation value of the input image signal does not change at all or is small, particularly as an image portion in which the coding switching shock is conspicuous. If the coding switching method is not linear, it is possible to quickly switch the coding method at the edge portion of the image while suppressing the noticeable coding switching shock at the non-edge portion of the image. Therefore, it is more desirable because encoding suitable for each region can be performed without degrading the average signal-to-noise ratio of the entire image.
[0107]
Also, the second embodiment and the third to seventh embodiments can be combined.
In the second embodiment, the magnification “K value” of the maximum gradation value of an image of one frame (1 TV field) to be displayed from the reference gradation value obtained by the display gradation magnification setting circuit 14. "Is a positive number, but is not limited to a positive number, and may be a decimal number. FIG. 26 is a characteristic diagram showing the correlation between the coding pattern and the input image signal and the light emission luminance when K = 2.5.
[0108]
As shown in FIG. 26A, a reference coding pattern (here, a pattern in which the luminance weight of each subfield is “1, 2, 3, 6, 10” in time order shown in FIG. 14A). In the luminance weight, a value obtained by multiplying the luminance weight of the low luminance by a value equal to or lower than the K value is set as the luminance weight, and a value obtained by multiplying the luminance weight of the high luminance by a value exceeding the K value is used as the luminance weight. Using the set coding pattern, each pixel in the frame having the corresponding K value is displayed.
[0109]
Specifically, the coefficients to be multiplied by the luminance weight “1, 2, 3, 6, 10” are 1, 1.5, 2.33, 2.5, and 2.9.
By setting luminance weighting in this way, not only the luminance value to be displayed can be increased, but also the dynamic range of the gradation value to be displayed can be expanded. That is, as shown in FIGS. 26B and 26C, in the correlation between the input image signal and the light emission luminance, the luminance is kept small with respect to the input in the low gradation portion. While maintaining the resolution in the gradation part, the dynamic range can be expanded.
[0110]
【The invention's effect】
As described above, according to the present invention, one TV field is composed of a plurality of subfields each having luminance weight arranged in time order, and a desired subfield is turned on to display an image of one TV field on multiple floors. An image display device that performs tone display, and includes a subfield having a luminance weight less than ½ of a luminance weight of a subfield having the next largest luminance weight.
[0111]
Further, the present invention is an image display device in which one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of the 1TV field in multiple gradations. The subfields are arranged in ascending order of the luminance weight, and the luminance weight of the subfield having the i-th smallest luminance weight is W _i When W ₁ + W ₁ + W ₂ + ... + W _n <W _{n + 1} A luminance weight is assigned so that n is present.
[0112]
As a result, when all combinations of selectable luminance values (gradation values) are rearranged in the order of luminance values (gradation values), a portion where the luminance (gradation) jumps can be generated. Since the ratio of the maximum luminance value that can be expressed as follows can be increased as compared with the prior art, image display with a wide dynamic range can be realized.
[0113]
Furthermore, the present invention comprises an image display in which one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of the 1TV field in multiple gradations. The apparatus arranges the subfields in ascending order of luminance weight, and sets the luminance weight of the subfield having the jth smallest luminance weight to W _j When W _i + W ₁ + W ₂ + ... + W _n <W _{n + 1} The luminance weight is assigned such that n and i of 2 or more exist.
[0114]
As a result, when all combinations of selectable luminance values (gradation values) are rearranged in the order of luminance values (gradation values), a portion where the luminance (gradation) jumps can be generated, and thereby the minimum luminance value Since the ratio of the maximum luminance value that can be expressed as follows can be increased as compared with the prior art, image display with a wide dynamic range can be realized. Further, this allows the jump width of the luminance value to be controlled in accordance with the gradation value of the input image signal. For example, the higher brightness value allows the jump width of the brightness value, and further sets the maximum displayable brightness value. Can be set large.
[0115]
In the present invention, a 1TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and a desired subfield is turned on to display an image of the 1TV field in multiple gradations. An image display device configured to control a maximum display luminance according to characteristics of an input image signal, wherein a TV field including a plurality of subfields configured by a combination of predetermined luminance weights is set as a reference TV field, The sum of the luminance weights of all the subfields in the coding pattern used to display the display TV field to be displayed at present is compared with the sum of the luminance weights of all the subfields in the coding pattern used when displaying the reference TV field. When the ratio is K, the symbol used to display the display TV field The sub-pattern has a luminance weight calculated by multiplying the luminance weight of the predetermined subfield in the reference TV field by a coefficient of K or less, and the luminance weight of the predetermined subfield in the reference TV field exceeds K And a subfield having a luminance weight calculated by multiplying by a coefficient.
[0116]
As a result, when trying to control the maximum luminance value that can be displayed according to the maximum gradation value of the image and the distribution level of the high gradation region, the minimum luminance value that can be displayed is always kept small, and the maximum luminance value that can be displayed Can be controlled as needed. In general, in an image including a relatively bright part, if the maximum luminance value that can be displayed more than necessary is increased, a display device such as a plasma display panel having a high correlation with light emission luminance and power consumption consumes power as a whole. Since it may increase, it is desirable to control the maximum displayable luminance value according to the content of the image. When performing such control, for example, even if the maximum luminance value that can be displayed is increased, for example, a subfield having a small luminance weight always maintains a relatively small value, while a subfield having a relatively large luminance weight is used. Since the luminance weight is changed according to the desired maximum displayable luminance value, the ratio between the minimum luminance value and the maximum luminance value can be increased, and the image can be displayed even if the maximum luminance value is displayed large. The portion close to the black level of the image does not rise, and the contrast is not impaired.
[0117]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of different luminance weights depending on the amount, and displays an image of a desired 1 TV field in multiple gradations. The portion where the image signal at the switching boundary portion of the encoding method has a predetermined characteristic is encoded so as to include a region where a plurality of encoding methods are mixed.
[0118]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount and displays an image of a desired 1 TV field in multiple gradations. In the portion where the image signal at the switching boundary of the encoding method has a predetermined characteristic, the signal for switching the encoding method is irregularly shifted in the pixel direction.
[0119]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount and displays an image of a desired 1 TV field in multiple gradations. In the portion where the image signal at the switching boundary portion of the encoding method has a predetermined characteristic, the signal for switching the encoding method is regularly shifted in the pixel direction.
[0120]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount and displays an image of a desired 1 TV field in multiple gradations. In the portion where the image signal at the switching boundary portion of the encoding method has a predetermined characteristic, the shape at the switching boundary portion of the signal for switching the encoding method is a main component of a polygonal line having a pixel interval as a minimum unit. It is made into the shape which contains.
[0121]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount and displays an image of a desired 1 TV field in multiple gradations. A modulation signal having at least a pixel interval as a period is applied to an image signal at a switching boundary portion of the encoding method.
[0122]
In the present invention, one TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the motion of an input image signal from among gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using different combinations of luminance weights depending on the amount and displays an image of a desired 1 TV field in multiple gradations. The image signal at the switching boundary of the encoding method is subjected to modulation for shifting the display position.
[0123]
Even if a switching shock occurs in the image portion where the encoding method is switched by these, the generation position can be dispersed, so that the switching shock can be reduced while suppressing the moving image pseudo contour. This means that, for example, when the image encoding process is performed differently for the still image portion and the moving image portion, the transition to the encoding method switching can be performed smoothly.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an image display device according to a first embodiment.
FIG. 2 is a diagram illustrating a correspondence between an input image signal and an image signal to be converted in a still image encoding circuit.
FIG. 3 is a diagram illustrating a correspondence between an input image signal and an image signal to be converted in a moving image encoding circuit.
FIG. 4 is a block diagram illustrating a configuration of a motion detection circuit.
FIG. 5 is a block diagram showing a configuration of a subfield control circuit.
FIG. 6 is a diagram illustrating a correspondence between an input image signal and subfield information.
FIG. 7 is a diagram showing a configuration of a frame memory in a subfield control circuit.
FIG. 8 is a block diagram illustrating a configuration of a display control circuit.
FIG. 9 is a diagram illustrating an operation method of a PDP.
FIGS. 10A, 10B, and 10C are characteristic diagrams and charts showing the correlation between the value of an input image signal and light emission luminance. FIGS.
FIG. 11 is a block diagram illustrating a configuration of an image display device according to a second embodiment.
FIGS. 12A to 12E are diagrams showing modes when switching is performed in the subfield control circuit based on the value of each K value (conventional one).
FIG. 13 is a characteristic diagram showing the correlation between an input image signal and light emission luminance as shown in (a) to (e) (conventional one).
FIGS. 14A to 14E are diagrams showing modes when switching is performed in the subfield control circuit based on the value of each K value (in the present invention).
FIG. 15 is a characteristic diagram showing the correlation between an input image signal and light emission luminance as shown in (a) to (e) (in accordance with the present invention).
FIG. 16 is a block diagram illustrating a configuration of an image display apparatus according to Embodiment 3;
FIG. 17 shows an example of an input image and a motion detection result.
FIG. 18 is a block diagram illustrating a configuration of an image display apparatus according to Embodiment 4;
FIG. 19 shows an example of an input image and a motion detection result.
20 is a block diagram showing a configuration of an image display apparatus according to Embodiment 5. FIG.
FIG. 21 is a diagram illustrating a coding mode in each image coding circuit.
22 is a block diagram showing a configuration of an image display apparatus according to Embodiment 6. FIG.
FIG. 23 shows an example of an input image and a motion detection result.
24 is a block diagram showing a configuration of an image display apparatus according to Embodiment 7. FIG.
FIG. 25 shows an example of an input image and a motion detection result.
FIG. 26 is a characteristic diagram showing a correlation between an encoding pattern and an input image signal and light emission luminance when K = 2.5.
[Explanation of symbols]
1 Input image signal
2 Inverse gamma correction circuit
3 Adder circuit
4 Still picture coding circuit
5 Video coding circuit
6 Motion detection circuit
7 Selection circuit
8 Subfield control circuit
9 Display control circuit
10 AC type plasma display panel
11 Difference circuit
12 Coefficient circuit group
13 Delay circuit group
14 Display gradation magnification setting circuit
15 Spatial modulation circuit
16 Random number generator
17 Signal modulation circuit
18 Boundary detection circuit
19 Adder circuit
20 Random number generator
21, 22, 23 Image coding circuit
24 selection circuit
25, 26 Signal modulation circuit
27, 28 Spatial modulation circuit
81 Subfield conversion circuit
82 Write address control circuit
83A, 83B frame memory

Claims (14)

One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
At the time of the encoding, the image signal in the switching boundary portion of the encoding method is encoded so as to include a region in which a plurality of encoding methods are mixed in a portion having a predetermined characteristic ,
An image display device , wherein a predetermined image portion of the portion in which the image signal has a predetermined characteristic is a non-edge portion of the image signal . One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
At the time of the encoding, in the portion where the image signal in the switching boundary portion of the encoding method has a predetermined feature, the signal for switching the encoding method is irregularly shifted in the pixel direction ,
An image display device , wherein a predetermined image portion of the portion in which the image signal has a predetermined characteristic is a non-edge portion of the image signal . One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
At the time of encoding, in the portion where the image signal in the switching boundary portion of the encoding method has a predetermined characteristic, the signal for switching the encoding method is regularly shifted in the pixel direction ,
An image display device , wherein a predetermined image portion of the portion in which the image signal has a predetermined characteristic is a non-edge portion of the image signal . One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
At the time of encoding, in the portion where the image signal at the switching boundary portion of the encoding method has a predetermined characteristic, the shape at the switching boundary portion of the signal that switches the encoding method is set to the minimum unit of the pixel interval. It is a shape that includes a polygonal line as the main element ,
An image display device , wherein a predetermined image portion of the portion in which the image signal has a predetermined characteristic is a non-edge portion of the image signal .   One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
  In the encoding, the image display apparatus is characterized in that encoding is performed so as to include a region where a plurality of encoding methods are mixed at a switching boundary portion of the encoding method.   One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
  An image display device characterized in that, at the time of encoding, a signal for switching the encoding method is irregularly shifted in a pixel direction at a switching boundary portion of the encoding method.   One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
  An image display apparatus characterized in that, at the time of encoding, a signal for switching the encoding method is regularly shifted in a pixel direction at a switching boundary portion of the encoding method.   One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
  At the time of encoding, at the switching boundary portion of the encoding method, the shape at the switching boundary portion of the signal for switching the encoding method is a shape including a broken line having a pixel interval as a minimum unit as a main element. An image display device.   At the time of the encoding, encoding is performed without mixing the plurality of encoding methods by encoding the switching boundary portion of the encoding method so as to include a region where the plurality of encoding methods are mixed. The image display apparatus according to claim 5, wherein a shape of a switching boundary portion of the encoding method is a random shape rather than a case.   The plurality of encoding methods include a first encoding method and a second encoding method,
  In the switching boundary portion of the encoding method, a first region in which the encoding according to the motion amount is encoded by the first encoding method, and the encoding according to the motion amount is the second encoding method Is adjacent to the second region to be encoded by
  In the encoding, by mixing the first encoding method and the second encoding method in each of the first region and the second region in the switching boundary portion of the encoding method, The image display device according to claim 5, wherein a plurality of encoding methods are mixed in a switching boundary portion of the encoding methods. The image display device according to claim 4 or 8 , wherein a shape including a polygonal line having a pixel interval as a minimum unit as a main element is a checkered pattern shape. Shape including a line for the pixel interval as the minimum unit as the main element, the image display apparatus according to claim 4 or 8, characterized in that a shape combining a line of a minimum unit pixel interval randomly. One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
An image display device, wherein a modulation signal having a period of at least a pixel interval is applied to an image signal at a switching boundary portion of the encoding method during the encoding. One TV field is composed of a plurality of subfields each having a luminance weight arranged in time order, and the luminance varies according to the amount of motion of the input image signal from among the gradation values that can be expressed by combining the subfields. An image display device that performs different encoding according to the amount of motion by using a combination of weights, and displays an image of a desired 1 TV field in multiple gradations,
An image display device characterized in that, at the time of encoding, a modulation for shifting a display position is performed on an image signal at a switching boundary portion of the encoding method.

Images