DE20001953U1 - Device for displaying analog graphics signals generated in a graphics processor on a display - Google Patents

Abstract

The analogue output of the graphics processor (1) is fed to a display (3) via an analog to digital converter (2) to convert the pixel data into digital format . A clock signal generator (4) provides a clock signal input for the converter and an input circuit (9) provides a means of controlling the image position. A protection circuit (19) generates a warning signal for a prohibited image move.

Description

Device for displaying analog graphics signals generated in a graphics processor on a display

Description

The invention relates to a device for displaying graphic signals generated in a graphics processor on a digital display.

The technical fields of personal computers and television receivers are growing ever closer together. Personal computers have already been proposed that are equipped with a tuner card to allow a PC user to receive and play back received television programs. Furthermore, so-called Internet boxes are already known, which are provided with a television receiver or integrated into such a television receiver to enable the television viewer to access the Internet.

Furthermore, television receivers are already known in which the reproduced images are shown on a plasma display. Such television receivers are offered on the market by the applicant under the name Pianatron.

When displaying graphic signals generated in a graphics processor on a plasma display, it is necessary to adapt the image position and image size of the graphic signals to the plasma display, since the signals generated by a graphics processor are not standard television signals, but rather image signals whose image position may differ relative to the existing synchronous signals and whose image size may deviate from the size of standardized television images.

Based on this prior art, the invention is based on the object of showing a way in which analogue graphic signals generated in a graphics processor can be displayed on a digital display without causing synchronisation disturbances.

This object is achieved by a device having the features specified in claim 1. Advantageous embodiments and further developments of the invention emerge from the dependent claims.

&iacgr;&ogr; The advantages of the invention are in particular that when displaying graphic signals generated in a graphic processor on a digital display, the user can use the input unit to enter operating commands for positioning the image on the display, while ensuring that no impermissibly large image shift occurs. Such impermissible image shifts would disrupt the image synchronization and thus the image reproduction.

The claimed output of a warning signal is particularly advantageous when the microcomputer evaluating the operating commands only outputs two-bit wide control signals to change the setpoint of a counter and does not have exact knowledge of the setpoint in the event of transmission faults to the counter. When only two-bit wide control signals are sent in this way to change the setpoint, the number of output pins of the microcomputer is advantageously reduced.

Further advantageous properties of the invention emerge from the explanation of an embodiment with reference to the figure. This shows a block diagram of a device according to the invention.

The graphic signals generated in a graphics processor 1 of a personal computer, which are in analog form, are to be displayed on a display 3, in particular a digital display, which is

preferably a plasma display or an LCD or a CRT unit. For this purpose, the graphics signals derived from the graphics processor 1 are converted in an analog-digital converter 2 into digital signals, which are forwarded to the digital display 3.

To generate the clock signal CK of the analog-digital converter 2, a clock signal generator 4 is provided, which is formed by a PLL. This PLL has a phase comparator 5, the output signal of which is the aforementioned clock signal CK for the analog-digital converter 2. The output signal of the phase comparator 5 is also fed to an actual value counter 6.

Its output signal is compared in a first comparator 7 with a setpoint value provided by a first setpoint counter 12. The output signal of the comparator 7 is fed to an input of the phase comparator 5 of the PLL, at whose other input 8 the horizontal synchronization signals of the graphics signal generated in the graphics processor 1 are present.

Consequently, the clock signal CK for the analog-to-digital converter 2 is determined by a phase comparison between the horizontal synchronizing signal generated in the graphics processor and the horizontal synchronizing signal provided by the first comparator 7, the latter corresponding to the total number of sampling pulses for each horizontal interval.

The output signal of the actual value counter 6 is also fed to a second comparator 15 and a third comparator 16, whose output signals are forwarded to a superposition circuit 17, which provides a blanking pulse at its output 18. The start of the blanking pulse is determined by the output signal of the second comparator 15 and the end of the blanking pulse is determined by the output signal of the third comparator 16.

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In the second comparator 15, the actual value signal provided by the actual value counter 6 is compared with a setpoint value provided by a second setpoint counter 13. By changing this second setpoint value, the start time of the blanking pulse can be changed and thus the start of the image within the line.

In the third comparator 16, the actual value signal provided by the actual value counter 6 is compared with a setpoint value provided by a third setpoint counter 14. By changing this third setpoint value, the end time of the blanking pulse can be changed and thus the end of the image within the line.

By changing the setpoints for the setpoint counters 12, 13 and 14, the image positioning of the graphic signal derived from the graphic processor 1 on the digital display 3 can be changed. A change in the setpoint provided by the setpoint counter 12 changes the clock signal CK for the analog-digital converter 2 and thus the horizontal image width of the graphic signal to be displayed on the display 3. A change in the setpoint provided by the setpoint counter 13 changes the start of the blanking pulse and thus the start of the image display within a line. A change in the setpoint provided by the setpoint counter 14 changes the end of the blanking pulse and thus the end of the image display within a line.

A change to each of these setpoints can be made by the user who is viewing the image shown on the display 3 by means of the control unit 9 of the television set having the display 3. This control unit has either plus/minus keys or cursor control keys which can be used in a setting mode of the television set for image positioning, i.e. for setting the image size and the image position of the image shown.

The operating commands entered using the control unit 9 are fed to a microcomputer 10, which converts them into two-bit wide control signals that only contain the instruction for the respective setpoint counter to change the respective setpoint by one counting step up or down. These control signals are fed from the microcomputer 10 to the respective setpoint counter via a data bus 11. For a larger change to a setpoint, which can be initiated by repeatedly or for a longer period of time pressing a button on the control unit 9, the microcomputer 10 transmits several two-bit wide control signals one after the other to the respective setpoint counter via the data bus 11.

For example, the setpoint counter 12 and the setpoint counter 14 are 11-bit counters, and the setpoint counter 13 is an 8-bit counter. Since, according to the invention, only two-bit wide control signals are transmitted from the microcomputer 10 to the respective counter, only two output pins are required on the microcomputer to transmit the control signals.

In order to ensure that no impermissibly large image shifts can occur even in the event of transmission disturbances on the data bus 11, the device shown in the figure has a protective circuit 19 for outputting a warning signal at the output 22. This warning signal is fed to the microcomputer 10, which provides a remedy by ignoring operating commands or by suitably influencing the setpoint values of the setpoint counters.

The protective circuit 19 has a first flip-flop 20 and a second flip-flop 21 arranged in series with it, at the output of which the warning signal is present when an impermissibly large image shift is detected. For this purpose, the protective circuit (19) has a one-bit wide output. The output signal of the third comparator 16, which defines the end of the blanking pulse, is fed to the input of the first flip-flop 20. This occurs at the Q output of the first flip-flop 20 and thus also at the

Input of the second flip-flop 21 is delayed by one clock period. The enable input of the second flip-flop 21 is fed with the output signal of the first comparator 7 derived from the PLL. As long as the
Output signal of the comparator 16 occurs at least one clock period before the output signal of the first comparator 7, the warning signal is not generated at the output 22. If the output signal of the comparator 16 occurs within one clock period with the output signal of the first comparator 7, the aforementioned warning signal is generated so that the microcomputer can, by appropriately influencing the setpoint value of the setpoint counter 14,

&iacgr;&ogr; ensures that the blanking pulse generated at the output 18 is terminated in time before the appearance of the output signal of the first comparator 7, which defines the beginning of the next line interval.

After all, the advantages of the invention are in particular that by issuing a warning signal on the limits of a permissible
This warning signal can be used to automatically counteract further image shifting. This prevents an image shift from occurring into the area of a subsequent sync pulse, which could cause synchronization disturbances or image disturbances. The output of a
Warning signal in the event of impermissibly large image shifts allows setpoints for the existing setpoint counters to be changed using control signals that are only two bits wide. This means that a control signal

generating microcomputer only has two output pins for the mentioned control signals.

Claims (11)

1. Device for displaying analogue graphic signals generated in a graphic processor ( 1 ) on a display ( 3 ), with an analogue-digital converter ( 2 ) for converting analogue pixel data of the graphic signals into digital pixel data, a clock signal generator ( 4 ) for providing a clock signal (CK) for the analogue-digital converter ( 2 ), an input unit ( 9 ) for inputting operating commands which influence the image positioning on the display ( 3 ), and a protective circuit ( 19 ) for outputting a warning signal which signals the presence of an impermissible image shift. 2. Device according to claim 1, characterized in that the display ( 3 ) is a digital or analog display unit. 3. Device according to claim 2, characterized in that the display 3 is a plasma display or an LCD or a CRT unit. 4. Device according to one of the preceding claims, characterized in that the input unit ( 9 ) has a remote control transmitter and/or the device has a microcomputer ( 10 ) connected to the input unit ( 9 ), which decodes the operating commands entered by means of the input unit and outputs control signals influencing the image positioning on the display and/or the control signals are two bits wide and/or the control signals correspond to an increment or a decrement command and/or the protection circuit ( 19 ) has a one-bit wide output. 5. Device according to one of the preceding claims, characterized in that it has a first setpoint counter ( 12 ), the control signals are fed to the first setpoint counter and the first setpoint counter provides a first setpoint signal on the output side. 6. Device according to one of the preceding claims, characterized in that the clock signal generator ( 4 ) is a PLL which has a phase comparator ( 5 ), an actual value counter ( 6 ) and a first comparator ( 7 ) which is connected on the input side to the output of the actual value counter ( 6 ) and the output of the first setpoint counter ( 12 ) and which is connected on the output side to an input of the phase comparator ( 5 ) and/or the first setpoint signal specifies the image width of the image to be shown on the display. 7. Device according to one of the preceding claims, characterized in that it has a second setpoint counter ( 13 ) which is connected on the input side to the microcomputer ( 10 ) and on the output side outputs a second setpoint signal influencing the start of the blanking pulse. 8. Device according to claim 6, characterized in that the second setpoint signal is fed to a second comparator ( 15 ), to which the output signal of the actual value counter ( 6 ) is also fed, the second comparator ( 15 ) being connected on the output side to an input of a superposition circuit ( 17 ), at the output of which the blanking pulse can be tapped and/or the device has a third setpoint counter ( 14 ) which is connected on the input side to the microcomputer ( 10 ) and on the output side outputs a third setpoint signal influencing the end of the blanking pulse. 9. Device according to claim 7, characterized in that the third setpoint signal is fed to a third comparator ( 16 ), to which the output signal of the actual value counter ( 6 ) is also fed, the third comparator ( 16 ) being connected on the output side to a further input of the superposition circuit ( 17 ), at the output of which the blanking pulse can be tapped. 10. Device according to one of the preceding claims, characterized in that the protective circuit ( 19 ) is supplied with a signal indicating the end of the blanking pulse and the output signal of the first comparator ( 7 ) derived from the PLL and/or the protective circuit has a first flip-flop ( 20 ), to which the input side is supplied with the signal indicating the end of the blanking pulse, and a second flip-flop ( 21 ) provided in series with the first flip-flop ( 20 ), the output signal of the first comparator ( 7 ) derived from the PLL ( 4 ) also being supplied to the second flip-flop ( 21 ). 11. Device according to one of the preceding claims, characterized in that the protective circuit ( 19 ) is connected on the output side to the microcomputer ( 10 ) and the microcomputer, in response to the output of the warning signal, ignores operating commands causing a further image shift and/or the input unit ( 9 ) has cursor control keys or plus/minus keys for entering the operating commands influencing the image position.