The invention relates to a device for subfield coding as defined in the preamble of claim 1.
The invention also relates to a method of subfield coding as defined in the preamble of claim 8.
Such a device for subfield coding is used in large television displays and computer displays, which displays comprise a number of light sources arranged in a matrix. Such a display may comprise a plurality of LEDs or a plasma display panel.
In the known device, the subfield coding is applied to obtain a grey scale by means of pulse width modulation of the light-emitting diodes (LEDs) in the display. The known device comprises means for subdividing every field of an image signal to be displayed into 255 subfields and processing means arranged to program all picture elements of the display device to emit or not to emit light during that subfield. For LED displays, the brightness of the LEDs is dependent on the LED current and the on-period of the LEDs of the respective subfields. Accordingly, a picture element that should produce {fraction (1/256)} of the maximum light output will only emit light during one subfield, and a picture element that should produce {fraction (10/256)} of the maximum light output will emit light during ten subsequent subfields. A disadvantage of this subfield coding is that it provides only a small dynamic range which is not sufficient for typical applications of large television and monitor screens in, for example, open air or in relatively dark control rooms.
Another possibility is to increase the length of each subsequent subfield by a predetermined amount as is applied in, for example, plasma display panels. If, for example, every field of an image signal is subdivided into twelve subfields and the first subfield corresponds to {fraction (1/2048)} of the maximum light output, the second subfield corresponds to {fraction (1/1024)} of the light output and so on, so that a twelve-bit gray scale can be obtained. However, a disadvantage of this subfield coding reduces the maximally obtainable brightness of the display, because the light-emitting elements do not emit radiation for the maximally possible time in a subfield in order to display the maximum brightness.
It is an object of the invention to provide a device for subfield coding which improves the dynamic range of a picture and maintains the maximally obtainable brightness of the image to be displayed. This object is achieved by a device according to the invention as defined in claim 1. In this device, the predetermined total number of subfields having a fixed duration is divided into a first number of subfields having a different period in which the picture element emits radiation, and a second number of subfields having a fixed period in which the picture element emits radiation. The first number of subfields is used to obtain a fine scale for the lower values of brightness of the picture element. The second number of subfields is used to obtain a linear scale for the higher values of brightness of the picture element.
For example, when the total number of subfields is 256, a binary order or an order defined by successive negative powers of two can be applied to define the lower values of brightness for the first ten subfields. The relative length of the on-period of the first sub-field is 2 to the power −10, the relative length of the second subfield is 2 to the power −9, and so on. The relative length of the 10th period is then ½. The remaining 245 subfields have a fixed relative length of 1 and are used to obtain a linear scale for the higher values of brightness. The maximally obtainable brightness is thus hardly reduced. Applying this subfield coding in a display device improves the dynamic range of a large display so that it can operate under different ambient light conditions varying from low ambient brightness to high ambient brightness, while the maximally obtainable brightness of the device is maintained.
It is a further object of the invention to provide a method of subfield coding which improves the dynamic range of a picture and maintains the maximally obtainable brightness of the image to be displayed. This object is achieved by the method of subfield coding according to the invention as defined in claim 8.
Further advantageous embodiments of the subfield coding device according to the invention are defined in the dependent claims.
These and other aspects of the invention are apparent from and will be elucidated with reference to the embodiments described hereinafter. In the drawing:
In practice, the number of picture element is 512 (horizontal)×384 (vertical)×3. Consequently, several driver devices 4, data processing devices 3 and data distribution devices 2 are necessary to address the full display screen 5.
Furthermore, the subfield coding device 32 comprises means 62 for determining the second number of subfields having a fixed on-period from the remaining eight most significant bits of the eighteen-bit digital value. The second number of subfields is determined by the value formed by the eight most significant remaining bits of the digital value. The second number equals the number of remaining subfields wherein the LED emits radiation for the whole duration of the subfield. In this example, the second number is a maximum of 245 subfields. In this way, the means for determining the second number of subfields determines the second number of subfields having a fixed period wherein the LED emits radiation and generates a subfield-on signal 72 for these subfields. This method of subfield coding provides a large dynamic range while the maximum brightness of the display screen is substantially maintained.
Both means 61, 62 generate a subfield-on-signal 72 for the individual LEDs associated with the subfield coding device 32. The subfield-on signal 72 is sent via a logic OR circuit 63 to the driver device 4. Furthermore, the image processing unit 60 generates a subfield-count-signal 78 and a frame-reset-signal 77 which indicates the beginning of a new frame. The subfield counter 64 counts the number of subfields from the subfield-count signal 78 and is reset to zero when the frame-reset-signal 77 is received. An output of the subfield counter 64 is connected to an input of the look-up tables 65,66,67. Look-up tables 65,66,67 and period counters 68,69,70 are present for each colour. The outputs of the respective look-up tables 65,66,67 are connected to the respective period counters 68,69,70 for loading a digital number in the respective period counter. The period counters 68,69,70 generate the output-enable signals 73,74,75 for the respective red, green and blue LED drivers 41,42,43 in dependence upon the loaded digital number and a clock signal 79. After receiving the frame-reset signal 77, the subfield counter 64 counts the consecutive subfields. Preferably, the clock signal 79 has a clock frequency of 10 Mhz to obtain a sufficiently low output of the LEDs under low ambient light conditions for PAL TV images. The clock circuit 71 generates the clock signal 79. Furthermore, the subfield counter 64 and the period counters 68,69,70 should be reset with the frame-reset signal to avoid unwanted interference when the display screen 50 is being filmed. The output-enable signals 73,74,75 and the subfield-on signal 72 are sent to the screen driver 4 and stored in latches 41,42,43 having outputs connected to the LEDs 51,52,53,54,55,56.
The digital numbers for the look-up tables 65,66,67 can be determined as follows. For a PAL TV image, each field is 20 ms, when the field is divided into 256 subfields. Each subfield takes 78.125 microseconds and the number 782 corresponds to the maximum number of clock periods defining the maximum length of the period wherein the LED emits radiation in that subfield. For an NTSC TV image, each field is 17 ms, when the field is divided into 256 subfields. Each subfield takes 65 microseconds and the decimal number 651 corresponds to the maximum number of clock periods defining the maximum length of the period wherein the LED emits radiation in that subfield. In this example, the look-up table has a table of 256 entries corresponding to the number of applied subfields and a 10-bit output for coding 782 different lengths varying from 1 to 782 clock periods defining the on-period in which the LED emits radiation in an associated subfield.
An example of a look-up table comprising the decimal numbers for the period counters 68,69,70 is shown in Table 1.
In the Table, the minimal on-period for the LED is limited to at least 2 counts for practical reasons.
In operation, the image processing unit 60 converts the 8-bit digital video data Iin into a 18-bit number value Iout via a gamma correction. For example, the gamma correction is represented by the function Iout=(Iin)^gamma*(Max/MaxIin^gamma), wherein Gamma=2.2,
Max represents a maximum eighteen-bit value and
MaxIin represents the maximal value of the video data.
The first eight most significant bits of the value Max are determined by the decimal number 245 and the ten least significant bits of the value Max are determined by the decimal number 1023. This eighteen-bit binary value Max represents the decimal value 251903.
Furthermore, the values for the look-up table 65,66,67 may include this gamma correction. The values for the look-up table may also include other non-linear image processing functions to compensate for a non-linear brightness scale.
Furthermore, the look-up tables 65,66,67 may be equal to each other. In order to provide a white point correction to obtain a desired colour balance between the red, green and blue, the values in the different look-up tables can be altered.
Furthermore, the look-up tables 65,66,67 can be loaded with pre-stored data, but alternatively it is also possible to load new tables in the look-up table via an external computer and the control bus 15.
It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative solutions without departing from the scope of the claims. In the claims enumerating several means, several of these means can be embodied by one and the same item of hardware. The invention is preferably applied in large-screen LED displays for outdoor use and other matrix displays (digital micro-mirrored device, plasma display panel (PDP)) but may also be applied with other devices such as O-LED display devices in mobile telephones.
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