FR2830362A1 - Method for controlling a display device such as a plasma monitor whereby an improved coding method is used for secondary fields that results in reduced pseudo contour intensity - Google Patents

Abstract

Method for controlling a display device in which, for example, in an input signal with 256 graduations, first secondary fields (SF1, SF2, SF7, SF8) operate with a gray scale of 15, while other secondary fields (SF3, SF9) operate with a gray scale of 16. The difference in weighting is 3 both lower and higher values. The invention also relates to a corresponding command circuit.

Description

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CONTROL CIRCUIT AND METHOD FOR CONTROLLING
IMAGE DISPLAY DEVICE
BACKGROUND OF THE INVENTION Field of the Invention
The present invention relates to a circuit and a method for controlling an image display device which can preferably be applied to a plasma display device and the like, and more particularly to a circuit and a method for image display device control to improve image quality.

Description of the Prior Art
A known plasma display panel control system is a secondary field system for the gradation representation. According to the secondary field system, 1 field is split into several secondary fields (SF) having differently weighted maintenance light emission values, and a representation in several gradations can be achieved by combinations of these secondary fields. .

 FIG. 4 represents a conventional secondary field coding for a display at 50 Hz in a plasma display panel. In the coding of conventional secondary fields, 1 field is for example divided into 12 secondary fields SF1 to SF12, and the weights of the respective secondary fields are fixed as shown in FIG. 4. That is to say that the weights of the fields secondary SF1 to SF12 are sequentially 1,2, 8, 16, 32,64, 4,8, 8,16, 32 and 64. Note that in 1 field, the secondary field of rank i from the beginning of field is designated by SFi.

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 In addition, the 12 secondary fields are grouped by 6 secondary fields as 2 groups of secondary fields G1 and G2, and a couple constituted by the secondary field SF3 and the secondary field SFg, a couple constituted by the secondary field SF4 and the secondary field SF, a pair constituted by the secondary field SF5 and the secondary field SF, and a couple constituted by the secondary field SF6 and the secondary field SF12, are respectively mutually locked under an ON / OFF command. That is to say that in each pair, when a secondary field is selected, as being a secondary field ON, the other secondary field is also selected, as being a secondary field ON, while if a secondary field is not selected, as being a STOP secondary field, the other secondary field is also not selected, as being a STOP secondary field.

 This control system for the ON / OFF control of 2 secondary fields to reduce flicker when displaying an image is revealed in for example Published Japanese Patent Application Not examined Published No. Hei 10-319 903.

 According to this secondary field system, it is possible to display in 256 gradations by selecting appropriate secondary fields as being ON secondary fields in correspondence with a gray scale level.

 In the coding described above, to represent for example a gray scale level of 15, it is necessary to select the secondary fields SF1, SF2, SF7 and Sofa, and to represent a gray scale level of 16, it it is necessary to select the secondary fields SF3 and SFg. The problem is that the light emission distribution

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 between these fields varies enormously in time and that large pseudo contours occur.

SUMMARY OF THE INVENTION
The present invention has been established in consideration of the foregoing problem, and its object is to provide a circuit and method for controlling an image display device which reduces pseudo-moving image contours.

 According to the present invention, the foregoing objective is achieved by providing an image display device control method for dividing an input video image signal field into N secondary fields to which predetermined luminance weights are assigned , and for controlling the image display device to perform displays in several gradations by the on / off control combination of the secondary fields, in which M pairs of secondary fields are defined between secondary fields of first rank in fields secondary of rank M (M is equal to L / 2 or less) from an end or the beginning of each field and the secondary fields respectively at the head of these secondary fields by L (L is equal to N / 2 or less ) secondary fields, and in which in each pair of secondary fields, the on / off command of a secondary field and that of the other secondary field constituting the pair of secondary fields ires are mutually locked, in which, furthermore, the difference between the difference in the weight of an arbitrary secondary field of the secondary fields of first rank at rank M and that of its immediately preceding secondary field and the difference between the weight of a another secondary field constituting, with the arbitrary secondary field, a pair of secondary fields and that of its field

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 immediately preceding secondary, is equal to or less than a minimum value among the weights of the N secondary fields.

 In addition, according to the present invention, the foregoing objective is achieved by providing an image display device control method for dividing an input video image signal field into N secondary fields at which luminance weights are assigned, and to control the image display device to perform multi-gradation displays by the combination of on / off control of the secondary fields, in which M pairs of secondary fields are defined between first secondary fields to secondary fields of rank M (M is equal to L / 2 or less) from an end or the beginning of each field and secondary fields respectively behind these secondary fields by L (L is equal to N / 2 or less) secondary fields, and in which in each pair of secondary fields, the on / off control of a secondary field and that of the other secondary field constituting the pair of ch secondary amps are mutually locked, in which, furthermore, the difference between the difference of the weight of an arbitrary secondary field of the first secondary fields at rank M and that of its immediately following secondary field and the difference between the weight of another secondary field constituting, with the arbitrary secondary field, a pair of secondary fields and that of its immediately following secondary field, is equal to or less than a minimum value among the weights of the N secondary fields.

 In addition, according to the present invention, the above objective is achieved by proposing a circuit for

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 image display device controller for dividing an input video image signal field into N secondary fields to which predetermined luminance weights are assigned, and for controlling the image display device for performing displays in several gradations by the on / off command combination of secondary fields, in which M pairs of secondary fields are defined between secondary fields of first rank to secondary fields of rank M (M is equal to L / 2 or less) at from an end or the beginning of each field and the secondary fields respectively at the head of these secondary fields by L (L is equal to N / 2 or less) secondary fields, and in which in each pair of secondary fields, the command on / off of a secondary field and that of the other secondary field constituting the pair of secondary fields are mutually locked, in which, in addition, the difference between the difference of the weight of an arbitrary secondary field of the secondary fields of first rank at rank M and that of its immediately preceding secondary field and the difference between the weight of another secondary field constituting, with the arbitrary secondary field, a pair of secondary fields and that of its immediately preceding secondary field, is equal to or less than a minimum value among the weights of the N secondary fields.

 In addition, according to the present invention, the foregoing objective is achieved by providing an image display device control circuit for dividing an input video image signal field into N secondary fields at which luminance weights are assigned, and to control the image display device to perform

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 displays in several gradations by the combination of on / off control of the secondary fields, in which M pairs of secondary fields are defined between secondary fields of first rank to secondary fields of rank M (M is equal to L / 2 or less) from an end or the beginning of each field and the secondary fields respectively behind these secondary fields by L (L is equal to N / 2 or less) secondary fields, and in which in each pair of secondary fields, the on / off control of a secondary field and that of the other secondary field constituting the pair of secondary fields are mutually locked, in which, in addition, the difference between the difference in the weight of an arbitrary secondary field of the secondary fields of first rank at rank M and that of its immediately following secondary field and the difference between the weight of another constituting secondary field, with the arbitrary secondary field, a pair of secondary fields and that of its immediately following secondary field is equal to or less than a minimum value among the weights of the N secondary fields.

 It will be noted that it is preferable that the difference in the weight of the arbitrary secondary field and that of its immediately preceding secondary field coincides with the difference between the weight of the other secondary field constituting, with the arbitrary secondary field, a pair of secondary fields. and that of its immediately preceding secondary field.

 In addition, it is preferable that the difference in the weight of the arbitrary secondary field and that of its immediately following secondary field coincides with the difference between the weight of the other secondary field constituting, with the arbitrary secondary field, a

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 pair of secondary fields and that of its immediately following secondary field.

 According to the present invention, as a light emission / non-light emission control is carried out in a pair of secondary fields distant from each other by L fields, the light emission frequency increases and it is possible to obtain a video image with reduced flicker. In addition, since a difference in weight between adjacent secondary fields is substantially the same in each pair of secondary fields, the variation over time in the distribution of light emission upon the occurrence of a change in gradation can be extremely scaled down. As a result, the occurrence of pseudo moving image contours due to a change in gradation can be suppressed.

 Other characteristics and advantages of the invention will emerge more clearly on reading the description which will follow when taken in conjunction with the appended drawings, in which similar references designate similar elements or of the same name throughout the figures of these latter.

BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is an explanatory view showing secondary field coding in a method of controlling an image display device according to a first embodiment of the present invention; Fig. 2 is an explanatory view showing a particular example of the secondary field coding in the print display device control method according to the first embodiment of the present invention; Figure 3 is an explanatory view showing

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 the secondary field coding in the image display device control method according to a second embodiment of the present invention and Fig. 4 is an explanatory view showing the conventional secondary field coding for display at 50 Hz in a plasma display panel.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
In the remainder of the document, a circuit and a method for controlling an image display device according to embodiments of the present invention will be described with reference to the accompanying drawings. Fig. 1 is an explanatory view showing secondary field coding in the image display device control method according to a first embodiment of the present invention.

 In the first embodiment, each input video signal field is divided into N secondary fields with assigned luminance weights, and multi-gradation displays are performed by ON (select) / OFF command combinations (no selection) of these secondary fields. In addition, we configure M pairs of secondary fields where 2 secondary fields have their ON / OFF commands mutually locked. More particularly, as shown in FIG. 1, M secondary fields starting from the last secondary field SFN of the field and M secondary fields at the head of the preceding M secondary fields respectively of L secondary fields are mutually locked under the ON / OFF command.

It will be noted that it is preferable that the value of L is approximately half the number of secondary fields N.

 For example, the ON / OFF command of the control

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 secondary SFN and the ON / OFF command of the secondary field SFN-L are mutually locked, the ON / OFF command of the secondary field SFN-1 and the ON / OFF command of the secondary field SFN-L-1 are mutually locked, the ON command / STOP of the secondary field SFN-M + 2 and the ON / OFF command of the secondary field SFN-M + 2-L are mutually locked, and the ON / OFF command of the secondary field SFN-M + 1 and the ON / OFF command of the secondary field SFN-M + 1-L are mutually locked.

Furthermore, in the present embodiment, as regards the weights of two secondary fields constituting a pair of mutually locked secondary fields, the difference between the weight of a secondary field and that of its immediately preceding secondary field coincides with the difference between the weight of the other secondary field and that of its immediately preceding secondary field. That is, assuming that the secondary field weight SFi is designated by W (SFi), in two secondary fields constituting a pair of mutually locked secondary fields, the relation in the following expression (1) is established.

 According to the present embodiment, as the total of the weights of mutually locked secondary fields increases, as for a flicker component, a frequency of twice the field frequency dominates. As a result, flicker cannot be easily detected by human garlic.

 In addition, we know that the maximum value of pseudo mobile image contour is frequently proportional

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 to the difference in weight with regard to its adjacent secondary field. In the present embodiment, as a light emission distribution movement occurs in secondary fields having the same weight difference in the front half and rear half of the complete image, the intensity of pseudo contour d the moving image during different gradation changes can be reduced.

 Next, we will describe an example where the value of N is 12, the value of M is 4, and the value of L is 6 as half the value N in the first embodiment. Fig. 2 is an explanatory view showing a particular example of the secondary field coding in the image display device control method according to the first embodiment of the present invention.

In this example, the weights of the secondary fields SF1 to SF12 are sequentially 1, 2.5, 13, 29.61, 4.8, 11.19, 35 and 67. Consequently, the relation in the following expression (2) is established.

 In addition, in comparison with the conventional coding in FIG. 4, the number of pairs of mutually locked secondary fields is the same as that of conventional coding, and the weights of non-mutually locked secondary fields are the same as those of conventional coding.

 In addition, as in the case of the conventional method, the 12 secondary fields are grouped into 6 secondary fields as 2 groups of secondary fields G1 and G2, and the secondary field SF3 and the field

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 secondary SF9 as a mutually locked couple, the secondary field SF4 and the secondary field SF1o as a mutually locked couple, the secondary field SF5 and the secondary field SF as a mutually locked couple, and the secondary field SF6 and the secondary field SF12 as a mutually locked pair, are respectively controlled ON / OFF, thus a representation in 256 gradations can be achieved.

 In this secondary field coding example, light emission occurs twice in certain secondary fields of 1 field. In addition, since the frequency when emitting light in the secondary field is twice the field frequency, the flicker is not easily perceived by the human eye.

 In addition, in an input signal with 256 gradations, when a gray scale level of 15 is represented, the secondary fields SF, SF, SF-y and SFg are selected as secondary fields ON, and when a gray scale level of 16 is shown, the secondary fields SF3 and SF9 are selected as secondary fields ON. The control itself is the same as the conventional control.

 However, in the present embodiment, as the difference in weight during a transition from the secondary field SF2 to the secondary field SF3 is equal to 3, and that the difference in weight during a transition from the secondary field SFg to the secondary field SF9 is equal to 3, that is to say that they are equal to each other, whereas, in the conventional control method of FIG. 4, as the difference in weight during a transition from the secondary field SF2 to the secondary field SF3 is equal to 6, and that the difference of

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 weight during a transition from the secondary field SF8 to the secondary field SF9 is equal to 0, the variation over time of the distribution of light emission between these secondary fields is extremely large. As the maximum value of the pseudo moving image contour intensity is proportional to a weight difference with regard to its adjacent secondary field, in this particular example, the intensity of pseudo moving image contour can be greatly reduced .

 Next, a second embodiment of the present invention will be described. Fig. 3 is an explanatory view showing the secondary field coding in the image display device control method according to the second embodiment of the present invention.

 In the second embodiment, as in the first embodiment, multi-gradation displays are performed by dividing each input video image signal field into N secondary fields having luminance weights and an ON command (selection) / STOP (non-selection) combined of these secondary fields. In addition, M pairs of mutually locked secondary fields for the ON / OFF command are configured.

 It will be noted that, as shown in FIG. 3, M secondary fields starting from the secondary field of header of fields SF are mutually locked with M secondary fields respectively behind these secondary fields of L secondary fields, and the respective mutually locked couples are ordered ON / OFF.

secondaire SF et la commande MARCHE/ARRÊT du champ secondaire SF1+L sont mutuellement verrouillées, la commande MARCHE/ARRÊT du champ secondaire SF2 et la For example, the ON / OFF command of the control

secondary SF and the ON / OFF command of the secondary field SF1 + L are mutually locked, the ON / OFF command of the secondary field SF2 and the

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champ secondaire SF-i et la commande MARCHE/ARRÊT du champ secondaire SF-j sont mutuellement verrouillées, et la commande MARCHE/ARRÊT du champ secondaire SFM et la commande MARCHE/ARRÊT du champ secondaire SFM+L sont mutuellement verrouillées. ON / OFF command of the secondary field SF2 + L are mutually locked, the ON / OFF command of the

secondary field SF-i and the ON / OFF command of the secondary field SF-j are mutually locked, and the ON / OFF command of the secondary field SFM and the ON / OFF command of the secondary field SFM + L are mutually locked.

In addition, in the present embodiment, with regard to the weights of 2 secondary fields constituting a pair of mutually locked secondary fields, the difference between the weight of a secondary field and that of its immediately following secondary field coincides with the difference between the weight of the other secondary field and that of its immediately following secondary field. That is, the relationship in the following expression (3) is established.

 In this embodiment, the same advantages can be obtained as those of the first embodiment.

 It will be noted that the control method according to the first and second embodiments can be carried out by a control circuit which controls a data control circuit, a sweep control circuit and a maintenance control circuit and so on. a plasma display screen or the like.

 It will be noted that in these embodiments, in a pair of secondary fields, the difference between the weight of an arbitrary secondary field and that of its immediately preceding or following secondary field coincides with the difference between the weight of the other

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 secondary field and that of its immediately preceding or following secondary field, however, the present invention is not limited to this arrangement, but is applicable in any case as long as the difference between these differences is equal to or less than the value of least difference among the N secondary fields constituting a field, which is 1 in the first and second embodiments.

 As previously described, according to the present invention, since the difference in weight between adjacent secondary fields is substantially the same in each pair of secondary fields, the variation in the light emission distribution time during the occurrence a change in gradation can be reduced. As a result, the occurrence of pseudo moving image contours due to a change in gradation can be suppressed. In addition, a light emission / non-light emission is carried out in 2 secondary fields constituting a pair of secondary fields, the frequency of light emission can be increased and the flicker can be reduced.

 The present invention is not limited to the preceding embodiments and various changes and modifications may be made to the scope of the present invention. Therefore, to assess the public of the scope of the present invention, the following claims are made.

Claims (4)

1. Image display device control method for dividing an input video image signal field into N secondary fields (SF to SFN) to which predetermined luminance weights are assigned, and for controlling the display device image display for performing displays in several gradations by the on / off control combination of secondary fields (SF to SFN) characterized in that M pairs of secondary fields are defined between secondary fields of first rank to secondary fields of rank M (M is equal to L / 2 or less) from an end or the beginning of each field and secondary fields respectively in head or behind of / in relation to these secondary fields of L (L is equal to N / 2 or less) secondary fields, in which in each pair of secondary fields, the on / off command of a secondary field and that of the other secondary field constituting the pair of secondary fields are mutually locked, and in which, in addition, the difference between the difference in the weight of an arbitrary secondary field of said first secondary fields at rank M and that of its secondary field immediately preceding and the difference between the weight of another secondary field constituting, with said arbitrary secondary field, a pair of secondary fields and that of its secondary field immediately t preceding, is equal to or less than a minimum value among the weights of said N secondary fields (SF to SFN).  2. Method for controlling an image display device according to claim 1, characterized in that <Desc / Clms Page number 16>  the difference in the weight of said arbitrary secondary field and that of its immediately preceding or following secondary field coincides with the difference between the weight of the other secondary field constituting, with said arbitrary secondary field, a pair of secondary fields and that of its secondary field immediately preceding or following.  3. Image display device control circuit for dividing an input video image signal field into N secondary fields (SF to SFN) to which predetermined luminance weights are assigned, and for controlling the image device image display for displaying in several gradations by the on / off control combination of secondary fields (SF to SFN), characterized in that M pairs of secondary fields are defined between secondary fields of first rank to secondary fields of rank M (M is equal to L / 2 or less) from an end or the beginning of each field and secondary fields respectively in head or behind of / in relation to these secondary fields of L (L is equal to N / 2 or less) secondary fields, in which in each pair of secondary fields, the on / off command of a secondary field and that of the other secondary field constituting the pair of secondary fields are mutually locked, and in which, in addition, the difference between the difference in the weight of an arbitrary secondary field of said first secondary fields at rank M and that of its secondary field immediately preceding and the difference between the weight of another secondary field constituting, with said arbitrary secondary field, a pair of secondary fields and that of <Desc / Clms Page number 17>  its immediately preceding secondary field is equal to or less than a minimum value among the weights of said N secondary fields (SF1 to SFN).  4. Image display device control circuit according to claim 3, characterized in that the difference in the weight of said arbitrary secondary field and that of its immediately preceding or following secondary field coincides with the difference between the weight of l another secondary field constituting, with said arbitrary secondary field, a pair of secondary fields and that of its immediately preceding or following secondary field.