The invention relates to a method of displaying a sequence of color images using an imaging device equipped with a two-dimensional matrix of activatable pixels. Each of the images can be decomposed into at least one series of at least three primary images of different primary colors. In order to display any color image from this sequence, the pixels of the three primary images from this series are successively displayed by modulating the activation duration of said corresponding pixels of the imaging device. Documents U.S. Pat. No. 6,392,656, U.S. Pat. No. 6,972,736 and U.S. Pat. No. 6,756,956 describe such a method.
In this method the beginning of the activation of the pixels of each primary image generally occurs at the beginning of the display of this image. The time interval that is then generated between displaying these primary images generates color break-up faults.
One aim of the invention is to limit this kind of fault.
To this end, the subject of the invention is a method of displaying a sequence of color images using an imaging device equipped with a two-dimensional matrix of activatable pixels in which, in order to display at least one color image from said sequence, said image being decomposed into at least one series of at least three successive primary images of different primary colors, the pixels of said three primary images from at least one series are successively displayed by modulating the activation duration of said corresponding pixels of the imaging device, in which method, for each series having a duration TR, if the following definitions are made for each pixel Pij of said color image:
then, for any said pixel Pij of the imaging device and for each series, the following relation holds:
(dOff-12-Pij+dOff-23-Pij)<[TR−(d1-Pij+d2-Pij+d3-Pij)]/2.
Advantageously, said relation is applicable for each of the images to be displayed from said sequence. In the case in which the images of the video sequence are decomposed into a plurality of series of at least three successive primary images, the invention applies to each of these series. The series may have identical or different durations.
The display of an image from this sequence is obtained by successively displaying three subframes of different primary colors, generally red, green and blue. In the prior art, the pixel activation phases are generally positioned in the same way whatever the primary image to be displayed, for example either at the beginning of the subframe or in the middle of the subframe. The identical positioning of the activation phases implies the following relation: (dOff-12-Pij+dOff-23-Pij)≦[TR−(d1-Pij+d2-Pij+d3-Pij)]/2. According to the invention, so as to reduce color break-up faults, the distribution of the pixel activation phases in three successive subframes from the same series is contracted in relation to the prior art: the pixel activation periods of the first primary image are shifted toward the end of the subframe of this first image, and, during the subframe of the third primary image, the pixel activation periods of this third primary image are shifted toward the beginning of the subframe of this third image. Color break-up faults in displaying the video sequence are thus advantageously reduced.
It is to be noted that in document U.S. Pat. No. 6,570,554:
It is also to be noted that the term “pixel activation” here leads to the emission of this pixel (upstream of a liquid crystal cell, for example) and cannot, as in U.S. Pat. No. 6,570,554, designate the activation of the backlighting of a liquid crystal cell.
Preferably, if TS2 is the maximum admissible duration of pixel activation of said imaging device during the display of the second primary image, then, for any said pixel Pij, the following relation holds: (dOff-12-Pij+dOff-23-Pij+d2-Pij)≦TS2. Advantageously, said relation is applicable for each of the images to be displayed from said sequence.
According to this advantageous variant, during the subframe of the first primary image, all the pixel activation pulses preferably end at the end of this subframe, and, during the subframe of the third primary image, all the pixel activation pulses preferably start at the beginning of this subframe. Color break-up faults in displaying the video sequence are thus reduced even more.
According to a first preferred variant, it furthermore holds that: dOff-12-Pij=dOff-23-Pij. This relation then applies to each pixel Pij of color images from said sequence, for each series of at least three primary images intended to display each of these images. This relation implies that, for each series, the pixel activation phases for displaying the second primary image are centered relative to the pixel activation phases for displaying the first and the third primary image of this series.
According to another preferred variant, it furthermore holds that: dOff-12-Pij=0 and/or dOff-23-Pij=0. This relation then applies to each pixel Pij of color images from said sequence, for each series of at least three primary images intended to display each of these images. This relation implies that, for each series, the pixel activation phases for displaying the second primary image are placed alongside the pixel activation phase for displaying the first or the third primary image of this series.
The hue of the primary color associated with said second primary image is preferably green. The other primary colors, that of the first image and that of the second image, are preferably red and blue. Thus, according to the invention, it is the red and blue subframes that get closer to the green subframe, in order to reduce, in particular, color break-up faults.
The subject of the invention is also an image display system comprising a matrix imaging device equipped with a two-dimensional matrix of activatable pixels and means for activating said pixels which are suitable for applying the method according to the invention.
The activatable pixels of said imaging device are preferably formed by electro-optical valves, and the system furthermore comprises means for successively illuminating said imaging device with each primary color. For the display of each primary image, the imaging device is hence illuminated by the corresponding primary color coming from the illumination means. The duration of illumination of each primary color is hence the maximum admissible duration of pixel activation of the imaging device during the display of the primary image corresponding to this primary color.
Said illumination means preferably comprise a light source emitting said three primary colors, optical means for directing the light emitted by this source onto the matrix of electro-optical valves of said imaging device and a color wheel that is placed in the path of this light between said source and said imaging device and which comprises colored filter segments, each filter being suited to transmit one of the various primary colors emitted by the source. The rotation of the color wheel thus enables successive illumination of the imaging device by each primary color.
The system preferably comprises a projection lens that is suitable and positioned for producing the image of said imaging device on a projection area. This projection area is generally formed by a projection screen which may, optionally, be integrated in the system (case of backprojectors).
The invention will be better understood on reading the following description, given by way of nonlimiting example and with reference to the appended figures in which:
The figures representing the time charts do not take into account the scale of the values so as to show better some details that would not be clearly apparent if the proportions had been respected.
An embodiment of the image display system according to the invention will now be described with reference to
The angular widths of the colored filter segments S1, S2, S3 of the color wheel 3 are preferably designed, in a way known per se, such that during each rotation of this wheel the illumination durations TS1, TS2, TS3 of the imaging device in each primary color are suited for the fusion of the resultant illuminations to form a white hue. This white hue generally corresponds to a temperature of the target color. This arrangement advantageously makes the most of the light flux emitted by the source 2. For convenience, it has been chosen here that TS1=TS2=TS3.
With reference to
Each control circuit Cij therefore comprises the following inputs:
A first implementation will now be described of the method according to the invention for displaying a sequence of images using the image display system that has just been described.
The duration TF of each image of this sequence, or the image frame duration, is here divided into two series of three primary images; each series of three primary images corresponds to a period TR of rotation of the color wheel. As previously indicated, the time allocated for illumination of the imaging device by each primary color during one turn of the color wheel is here TS1=TS2=TS3; hence TR=TS1+TS2+TS3 and TF=2×TR; for example, TF=20 ms.
The input interface 6 delivers to the control means 5 series of three primary images. Each primary image is delivered in the form of a video signal for each pixel of this image to be displayed. With reference to
For each series of primary images to be displayed, the display of the first and third primary image is obtained according to the same method, extrapolated from the method of displaying the second primary image. The upper graph of
Thus, if the following definitions are made for each pixel Pij of the color image to be displayed:
it is observed that:
The control method that has just been described enables a substantial reduction in color break-up faults for the display of video sequences.
It should be noted that the use of ramp-shaped reference signals for controlling the modulation of the emission duration of pixels of an imaging device is described in the prior art, for example in document US2001-026261.
A second implementation will now be described of the method according to the invention, again for displaying a sequence of images using the image display system that has just been described.
The only difference to the first method that has just been described lies in the form of the reference signal VRAMP. Here, in each series of three primary images, instead of the previous succession R1, R2, R3, there is now, with reference to
A third implementation will now be described of the method according to the invention, again for displaying a sequence of images using the same image display system. The only difference to the first method again lies in the form of the reference signal VRAMP. Here, in each series of three primary images, instead of the succession R1, R2, R3 of the first embodiment, there is now, with reference to
Although it holds that dOff-12-Pij+d2-Pij+dOff-23-Pij=TS2 in all the embodiments presented, the invention also includes the cases in which dOff-12-Pij+d2-Pij+dOff-23-Pij<TS2.
Although in all the embodiments presented the pixel activation phases of the first primary image from each series always end at the same time as the phase of illuminating the imaging device with this primary color, and the pixel activation phases of the third primary image always start at the same time as the phase of illuminating the imaging device with this primary color, the invention includes cases in which the end or the start of these phases do not coincide, provided the following relation is satisfied: (dOff-12-Pij+dOff-23-Pij)<[TR−(di-Pij+d2-Pij+d3-Pij)]/2. It should be noted that this relation is obviously satisfied in all the embodiments that have just been presented.
The invention has been described with reference to a decomposition of each image of a video sequence into two series of three successive primary images of different primary colors. The invention also applies to cases of decomposition of each image into a single series of three primary images, or into more than two series of three primary images. The various series may have different durations.
The invention also applies to cases in which each series has a number of primary images greater than three, provided that there are three of them successively in each series in order to apply the method according to the invention. By extension, among the primary colors, a color of white hue may even be counted.
The invention has been described with reference to an image display system in which the sequencing of primary images is ensured by a color wheel. Other modes of sequencing primary images may be used without departing from the invention.
The invention has been described with reference to a system for image display by projection in which the active pixels of the imaging device are liquid crystal valves. Other active pixels may be used without departing from the invention, such as micromirror pixels (DMD) or pixels with light-emitting diodes, especially when they are controllable by pulse-width modulation in an analogous manner, as described for example in document U.S. Pat. No. 6,590,549. It should be noted that in document WO2006/003091 the micromirrors are not controllable in an analogous manner.
The invention has been described with reference to a system for image display by projection. Other image display systems may be used for implementing the invention.
Number | Date | Country | Kind |
---|---|---|---|
0604798 | May 2006 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2007/055065 | 5/24/2007 | WO | 00 | 9/22/2009 |