DE102007036569B4 - Data transmission with DLP projectors - Google Patents

Abstract

Display device for displaying a pixel-based image information and simultaneous transmission of data, in which the brightness and / or color of their pixels is adjustable by a light circuit (4) of variable length alternating with a dark circuit, wherein during the light circuit (4) a constant light intensity is emitted , and in which the data are emitted by means of an additional temporal modulation of the pixels, the display device being designed such that: - the changeover between light and dark circuit (4) takes place within a constant image build-up period (1); - The image synthesis period (1) is subdivided into clock steps (2), wherein the length of a clock step from the length of the image synthesis period (1) and the brightness and / or color resolution of the display device results; - At least one clock step (2) of each image synthesis period (1) is used instead of displaying the image information to transmit the data; and - in which, within the image synthesis period (1), the light circuit (4) is made continuous for an on-time, wherein a start time of the light circuit (4) is used to send out the data.

Description

The invention relates to an arrangement and a method for displaying pixel-based image information while transmitting data.

One method for the projection of large-scale pixel-based images is the so-called DLP (Digital Light Processing). In a DLP projector, a projection light source, such as a halogen lamp, illuminates a field of micromirrors. The micromirrors are configured to be switchable between two positions, with a micromirror in the on position reflecting the light from the projection light source through an imaging optic, thereby forming a bright spot on the projection surface, i. H. a picture pixel, arises. Each micromirror is therefore for one pixel, i. H. a pixel of the pixel-based image, responsible. Since only one light source is used for projection, a brightness gradation of the pixels in a DLP projector is not achievable via a direct brightness variation. Rather, the brightness gradation is achieved by switching a respective micromirror to the on position for a time dependent on the desired brightness, while for an additional period of time it is in an off position in which it does not reflect light into the imaging optics. In order to render this bright and dark pasting of the pixels invisible to the eye and thus to project an apparently static image, it is carried out within a time span of for example 15 ms for black-and-white projectors or 5 ms for color projectors.

Schematically, an exemplary bright / dark keystroke according to the prior art is shown in FIG 1 outlined. This in 1 given example assumes a brightness resolution of 4 bits, ie 16 brightness levels. In the lowest brightness level, corresponding to the first line in 1 , the micromirror is left in the off position. It therefore does not reflect light into the imaging optics and the corresponding pixel remains black. If a nonzero brightness is desired for a pixel, the corresponding micromirror will be for a certain number of clock steps 2 switched to the on position. A clock step 2 this results from the length of the image buildup time span 1 for example, for a DLP color projector 5 ms, divided by the number of brightness levels-1. With a brightness depth of 4 bits, this means that the image buildup time 1 of 5 ms is divided into 15 clock steps, each about 330 μs duration. The lowest nonzero brightness, in the given example 1/15, is according to the top line of 1 achieved in that the micromirror for the first clock step 2 the image buildup time span 1 in the light circuit 4 while it is switched on for the rest of the image build-up period 1 is in the off position. Brightness values of 3/15, 6/15 and 12/15 are adjusted by 3, 6 and 12 steps, respectively 2 reached in the on position. The highest possible brightness for a pixel is achieved by corresponding to the bottom line in 1 the micromirror for the entire image buildup period 1 in light circuit 4 is.

The publication US 2009/0002265 A1 discloses a DMD display device using lasers, wherein additional information can be conveyed by modulation of the laser light.

In the document JP 2004-064465 A a display device is described in which the image data for the transmission of communication data is superimposed with a signal which is generated via pulse position modulation.

From the WO 00/74390 A1 It is known how DMD control is used in Digital Light Processing (DLP) based systems with Digital Micromirror Devices (DMDs). In this case, the information is first written into the entire image matrix (this is done continuously in rows and columns), and then all the micromirrors are folded over with the aid of a bias voltage pulse, thus the image information is changed. By subdividing the image time into subimage times (for example, for a color depth of 4 bits, 4 sub times occur) with image times divided at a ratio of 1: 2: 4: 8, gray values of the DMD pixels are reached in which the pixels correspond to their gray value partially switched on and off (temporally sequential partial modulation of the pixels).

The object underlying the invention is to provide a display device for a pixel-based image information, in which the brightness and / or color of their pixels is adjustable by a light circuit of variable length alternating with a dark circuit, with the additional transmission of data is possible. A further object is to provide a method with which data can additionally be transmitted via a display device, light circuit of variable length alternating with a dark circuit.

This object is achieved with respect to that by a display device having the features of claim 1 or 2 and with respect to the method by a method having the features of claim 7 or 8. Advantageous embodiments emerge from the dependent claims.

According to claim 1, in the display device for displaying pixel-based image information and simultaneous emission, the brightness and / or color of its pixels can be adjusted by a light circuit of variable length alternating with a dark circuit. She is still like that configured to transmit the data by means of additional temporal modulation of the pixels. According to the invention, at least one clock step of each image buildup time period is used instead of displaying the pixel-based image information for transmitting the data, and depending on the information to be transmitted, the turn-on time for the on position within the image build-up time period, ie for the light switching, the light circuit is always uninterrupted within one image build-up period is made so that there is a unique connection time in each image synthesis period.

An alternative is to set the shutdown time for the switch to the off position, i. H. Dark switching, to use for sending the data.

In accordance with claim 2, in the display device for displaying pixel-based image information and simultaneous emission, the brightness and / or color of its pixels can be set by a light circuit of variable length alternating with a dark circuit. It is further configured such that the data are transmitted by means of an additional temporal modulation of the pixels. According to the invention, at least one clock step of each image synthesis period is used instead of displaying the pixel-based image information for the transmission of the data, and in at least two clock steps a change from the light circuit, ie. H. the on position to dark switching, d. H. the off position or vice versa, to be able to use a Manchester code to improve the synchronization.

An example of a corresponding display device is a DLP projector.

In the display device according to the invention, therefore, the display of the image is already based on a modulation of the light output. The data is sent out with an additional temporal modulation of the light output, which is expediently not visible to humans.

It is advantageous that the display device is already configured for a temporal modulation of the light output and thus the additional temporal modulation for transmitting the additional information is implemented with little effort. In a DLP projector, for example, in which the temporal variation of the light output is performed by means of micromirrors, the micromirrors are switchable at a very high speed and therefore easily allow a further temporal modulation for the transmission of information.

The number of clock steps of an image build-up period available to represent the corresponding pixel is reduced by the additional modulation. In this case, the constant light intensity for the light circuit can advantageously be adapted to the number of clock steps used for the transmission of the data, that an unchanged brightness range, ie. H. Contrast, for the display of the image information is achievable, as if the entire image composition period would be used for the display of the image. This adaptation avoids that the transmission of the data reduces a contrast achievable with the display device.

If the display device is designed to display colored image information by means of a plurality of color channels, the information can be transmitted by means of a relationship of the modulations of the individual color channels.

The described display device can be used advantageously in a transmission system for data. The transmission system additionally has a receiving device for receiving the data, which is configured such that the reception of the data is possible on the basis of the additional modulation that is performed by the display device.

According to claim 7, in the method for displaying a pixel-based image information and simultaneously transmitting data with a display device, the brightness and / or color of pixels of the display device is adjusted by a light circuit of variable length alternating with a dark circuit and the data by means of an additional temporal modulation the pixel is sent, wherein at least one clock step of each image synthesis period is used instead of displaying the pixel-based image information for transmitting the data and depending on the information to be transmitted, the turn-on time for the on position within the image synthesis period, d. H. for light switching, the light switching is always carried out continuously within an image synthesis period, so that there is a clear connection time in each image synthesis period.

According to claim 8, in the method for displaying a pixel-based image information and simultaneously transmitting data with a display device, the brightness and / or color of pixels of the display device is adjusted by a light circuit of variable length alternating with a dark circuit and the data by means of an additional temporal modulation the pixel is emitted, wherein at least one clock step of each image synthesis period is used instead of displaying the pixel-based image information for transmitting the data and in at least two clock steps, a change from the light circuit, ie the on position to dark switching, ie the off position or vice versa, is made in order to use a Manchester code to improve the synchronization can.

The variations described for the arrangement can also be applied to the method.

The method can be used advantageously in a method for the transmission of data, in which additionally a reception of the data is carried out on the basis of the additional modulation with a correspondingly configured receiving device, for example a PC, mobile telephone or PDA.

Further advantages and details are explained below with reference to exemplary embodiments given in the drawing:

1 the adjustment of different brightnesses for a pixel according to the prior art,

2 the transmission of a bit of the data at different brightnesses of the pixel,

3 the transmission of data at high brightness resolution,

4 the transmission of data using Manchester code,

5 a differential transmission of the data.

In 1 is schematically illustrated, as in the prior art, a different brightness of a pixel by differently long light circuit 4 within a frame period 1 , that is realized by a pulse width modulation. This procedure has already been described in the introduction.

The image buildup time span 1 of 5 ms for a DLP color projector is in accordance with the brightness resolution in steps 2 divided. With a brightness resolution of n bits, this results in 2 ⁿ -1 clock steps 2 , Today's DLP projectors achieve brightness resolutions of 10 bits and more, which is at least 1023 steps 2 equivalent. In the 1 . 2 . 4 and 5 However, for a better overview only 15 clock steps 2 shown, which corresponds to a brightness resolution of 4 bits.

2 shows a first embodiment for an additional modulation for the transmission of data, namely a pulse position modulation. The two upper lines of the 2 show how a "0" and a "1" are transmitted at a pixel brightness of 3 of 15. For this purpose, the starting time at which the micromirror is set in the on position is varied. While in the prior art, the turn-on time is always at the beginning of the image build-up period 1 is, is now to transfer the "0" the turn-on by one clock step 2 postponed. To transfer a "1", the startup time is the start of the image buildup period 1 taken. Like the bottom two lines of the 2 show the maximum duration of light switching when using this procedure 4 on 14 of 15 steps 2 limited, since when transmitting a "0" of the micromirror in the first clock step 2 must be in the off position. If a "1" is transmitted, then the micromirror is in the first cycle step 2 in the on position. In this case, it would be possible to use the micromirror to achieve full pixel brightness for the entire image build-up period 1 to remain in the on position. But that would lead to a fluctuating depending on the nature of the data brightness of the pixel and is therefore avoided. If at the same time a "1" is transmitted at maximum pixel brightness, the micromirror remains in the last clock step 2 in the off position.

To avoid the disadvantage that the maximum achievable pixel brightness is lowered in this embodiment and comparable embodiments, the constant light intensity, which is reflected by the micromirrors, increased by a corresponding factor. At 4-bit brightness resolution, this increase would be significant, but for a real DLP projector with, for example, 10-bit brightness resolution, the required brightness increase is only 1/1023. This increase in brightness of the constant light intensity is easily achievable. Conversely, a loss of 1/1023 of the possible contrast is also tolerable if an increase in the constant light intensity is not possible.

The described modulation method allows a data rate of 1: 5 ms = 200 bit / s. This limitation can be circumvented by higher-level modulation methods. For example, in pulse position modulation, one can delay the pulse not by one clock, but by 2 ^(n-1) clocks by n bits within the frame time period 1 to convey. The maximum bit rate is limited by the number of gray scales and the switching speed of the micromirrors. Currently, the mirrors can be turned on and off within about 4 μs, ie 5 ms can be subdivided into about 1250 clocks, but for 10 bits only 1023 clocks are needed. Approximately 200 clocks can therefore be used for the pulse position modulation, which is approximately 7 bits. Thus, the bit rate of the transmitted signal could be increased to 7x200 bits / s = 1.4 kbps. In order to leave the contrast ratio unchanged, the power of the illumination source would have to be increased by (2 ^7-1 ) :( 2 ^10-1 ) = 12%. Alternatively, a corresponding Contrast loss of 12% can be accepted. If, in the future, the switching time of the micromirrors can be shortened, the achievable data rate would grow accordingly. For example, halving the switching time would increase the bit rate from 1.4 kbps to 2.2 kbps. To clarify this more real situation is in 3 the basis of 2 shown execution option under more realistic conditions. This is based on a DLP projector with 10-bit brightness resolution, in which the micromirrors can be controlled within approx. 4 μs. In 3 is the transmission of three different values of the invisible information at a constant duration of the light circuit 4 shown. Because of the more real brightness resolution, these are more than 1000 clock steps 2 in 3 no longer shown.

4 schematically shows a second embodiment possibility for the additional modulation, which works similar to the Manchester code. Here are the first two steps 2 each frame time period 1 used for information transmission. In this case, a "0" by switching from the off position in the first clock step 2 to the on position in the second clock step 2 while a 1 is switched by switching from the on position in the first clock step 2 to the off position in the second clock step 2 is used. 4 again shows the transmission of a "0" and "1" at a pixel brightness of 4 of 15 and the maximum pixel brightness of 14 of 15.

In the embodiments described so far, it is not possible to produce a brightness of 0/15, since the data emission always causes the micromirrors to be at least one clock step 2 is in the on position. Conversely, it is of course not possible to send data at complete dark switching of a pixel with this pixel. Therefore, it must be hurt that full blanking is not possible in this embodiment, or data transmission does not always occur.

A third embodiment is schematically shown in FIG 5 shown. This is a differential encoding of the data. Similar to the first possible embodiment, ie pulse position modulation, in the third embodiment, the data are based on the turn-on time of the light circuit 4 transfer. Here, however, the relationship of the turn-on timings of two consecutive image buildup times becomes 1 used to encode the information. For example, the position changes from an image buildup period 1 to the next screen setup time period 1 not, so a "0" is transmitted. However, if the connection time changes, a 1 is transmitted. In 5 is in the first line of the turn-on before the second clock step 2 , A "0" is transmitted by the on-line time in the next line also before the second clock step 2 is. As in the next screen setup time 1 a 1 according to the third line of the 5 the connection time to the first clock step 2 has changed, a "1" has been transferred hereby. For the fourth line, ie the next image synthesis period, the connection time changes again to the second clock step 2 , which means that again a "1" was transmitted. The differential modulation according to 5 has the advantage of simplifying the synchronization of the receiver.

In a 1-chip color DLP projector, the third embodiment described leads to a modulation in which a relationship between the color channels is used because the color channels are projected one behind the other.

For a multi-chip color DLP projector, on the other hand, the colors are projected simultaneously. Thus, with the colors, usually red, green and blue, there are three independent channels available for additional information. These can be used individually, for example in the manner described above, in order to send out data. However, it is also possible to correlate the additional modulation in the colors to send out the information. For example, the difference of the turn-on times in the individual colors can encode the information.

In the given examples it was assumed that all pixels, i. H. all micromirrors of a DLP projector experiencing the same additional modulation. This has the advantage that the signal containing the additional information is as easy to detect and secure as possible. However, it is also conceivable to use only a part of the pixels for the transmission of the additional information.

Furthermore, the given modulation examples were just concrete statements, and it is clear that details of these remarks vary widely. So instead of just one or two clock steps 2 , which are used for the transmission of the data, also more or substantially more clock steps 2 be used for transmission. Also the position of these clock steps 2 , which in the given examples are always at the beginning of a frame period 1 was, can be varied as desired, for example, to the middle or to the end of a Bildaufbau period 1 , The coding with regard to a digital "1" or "0" can also be interchanged with respect to the given examples. The given examples continue to assume that each image build time span 1 used for the transmission of data. This procedure can also be modified, for example to the effect that only every second image build-up period is used for the transmission of data.

Claims (10)

Display device for displaying a pixel-based image information and simultaneous transmission of data, in which the brightness and / or color of their pixels is controlled by a light switching ( 4 variable length alternating with a dark circuit is adjustable, wherein during the light circuit ( 4 ) is emitted, and in which the data are emitted by means of an additional temporal modulation of the pixels, wherein the display device is designed such that: - the change between light and dark switching ( 4 ) within a constant image build-up period ( 1 ) he follows; The image buildup time span ( 1 ) in steps ( 2 ) is subdividable, wherein the length of a clock step from the length of the image synthesis period ( 1 ) and the brightness and / or color resolution of the display device; At least one clock step ( 2 ) each image build time span ( 1 ) is used instead of displaying the image information to broadcast the data; and in the case of 1 ) the light circuit ( 4 ) is made continuously for a turn-on time, wherein a start time of the light circuit ( 4 ) is used to send out the data. Display device for displaying a pixel-based image information and simultaneous transmission of data, in which the brightness and / or color of their pixels is controlled by a light switching ( 4 variable length alternating with a dark circuit is adjustable, wherein during the light circuit ( 4 ) is emitted, and in which the data are emitted by means of an additional temporal modulation of the pixels, wherein the display device is designed such that: - the change between light and dark switching ( 4 ) within a constant image build-up period ( 1 ) he follows; The image buildup time span ( 1 ) in steps ( 2 ) is subdividable, wherein the length of a clock step from the length of the image synthesis period ( 1 ) and the brightness and / or color resolution of the display device; At least one clock step ( 2 ) each image build time span ( 1 ) is used instead of displaying the image information to broadcast the data; and - in at least two steps ( 2 ) a transmission of data is feasible by in the steps ( 2 ) a change from the light circuit ( 4 ) is made to the dark circuit or vice versa to realize a Manchester code. Display device according to claim 1 or 2, designed as a DLP projector. Display device according to one of the preceding claims, configured in such a way that the constant light intensity in such a way to the number of clock steps ( 2 ) is adaptable that a medium brightness loss occurring by the transmission of the data is compensated. Display device according to one of the preceding claims, which is designed to display a colored image information by means of a plurality of color channels and in which the information is emitted by means of a relationship of the modulations of the individual color channels. Transmission system for data, comprising: - At least one display device according to one of the preceding claims for transmitting the data; and - At least one receiving device for receiving the data based on the additional modulation according to one of the preceding claims. Method for displaying pixel-based image information and simultaneous transmission of data with a display device, in which: - the brightness and / or color of pixels of the display device are controlled by a light circuit ( 4 variable length is set in alternation with a dark circuit, and - the data is transmitted by means of an additional temporal modulation of the pixels, in which: - the change between light and dark switching ( 4 ) within a constant image build-up period ( 1 ) he follows; The image buildup time span ( 1 ) in steps ( 2 ) is subdividable, wherein the length of a clock step from the length of the image synthesis period ( 1 ) and the brightness and / or color resolution of the display device; At least one clock step ( 2 ) each image build time span ( 1 ) is used instead of displaying the image information to broadcast the data; and - within the image synthesis period ( 1 ) the light circuit ( 4 ) is made continuously for a turn-on time, wherein a start time of the light circuit ( 4 ) is used to send out the data. Method for displaying pixel-based image information and simultaneous transmission of data with a display device, in which: - the brightness and / or color of pixels of the display device are controlled by a light circuit ( 4 ) variable length alternating with a dark circuit is set and - the data by means of an additional temporal modulation of the pixels are emitted, in which: - the change between light and dark switching ( 4 ) within a constant image build-up period ( 1 ) he follows; The image buildup time span ( 1 ) in steps ( 2 ) is subdividable, wherein the length of a clock step from the length of the image synthesis period ( 1 ) and the brightness and / or color resolution of the display device; At least one clock step ( 2 ) each image build time span ( 1 ) is used instead of displaying the image information to broadcast the data; and - in at least two steps ( 2 ) a transmission of data is feasible by in the steps ( 2 ) a change from the light circuit ( 4 ) is made to the dark circuit or vice versa to realize a Manchester code. Method according to claim 7 or 8 using a device according to one of claims 3 to 5. Method for displaying pixel-based image information and a simultaneous transmission of data, in which: The display of the pixel-based image information and the transmission of the data are carried out by a method according to claim 7, 8 or 9; and - Receiving the data based on the additional modulation according to claim 7, 8 or 9 with a receiving device, in particular a PC, mobile telephone or PDA, is performed.

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