DE4345426C2 - Workstation display unit with input device - Google Patents

Abstract

The graphics display system has a computer module (1a) that consists of a CPU (11), internal memory (13), input interface (12), I/O connection port (14), display control circuit (15), external memory (17) and an addition circuit for control signals (16). An input is provided (10) that can be a keyboard, mouse or similar device. The video signal or synchronising signal may be modified by the addition of a control signal and the combined signal fed to the display unit (16), consisting of control signal separation circuit (18), video circuit (20), deflection control circuit (21) and display control circuit (19).

Description

The present invention relates to an image display device comprising a Input unit, such as a keyboard, a computer unit and includes a display unit, and in particular it relates on an image display device in which a display size, a display position tion and a brightness of an image in the display unit by the Input unit, such as the keyboard, through the computer unit can be adjusted to improve manageability. The image display device of the present invention can be used in a work station and an advanced personal computer can be used using a display unit.

There are currently in the display units for a computer terminal Display position and size of the image and a distraction frequency of a video signal to be displayed varies in different ways. the according to a display unit for the computer terminal is designed to to be able to handle different video signals.

The display unit of this type sets a microcomputer and one LSI memory to ensure optimal image display for any type of video to ensure signals. Such a display unit from the prior art Technology is, for example, in Japanese Unexamined Patent Publication chung No. 1-32175.  

This conventional display unit is from a CRT display unit Multi-scan type that includes a memory in which Information relative to display positions and sizes of the image for each Kind of video signals are stored, and that by a Microcom computer is controlled in this display unit. The information relative to the optimal display position and size of the image in accordance with an input video signal is read out from the memory, and a deflection circuit of the display unit is read out by the Information controlled. Furthermore, if one is turned on in the display unit If the video signal is not known, the memory does not store any information tion relative to the input video signal and accordingly Adjustment switches arranged on a front panel of the display unit are operated without the influence of the computer, so that information to adjust the display position and size of the image is entered. A control circuit such as the Microcom computer, prepares information for control including distraction and makes an attitude.

The display unit is in the above-described prior art designed to display optimal images in accordance with the To receive input video signal while in another state of Technique a display state is controlled to by the computer unit to be switched in accordance with the diversity of multimedia the. Such a display unit from the prior art is in the Japanese Unexamined Patent Publication No. 2-60193.

This conventional display unit is directed to a CRT display device tet that in a display of an electronic device such as a personal computer is used, and that the number of Ab  can switch key lines between 200 lines and 400 lines freely and by one TV receivers can be shared.

In particular, in the above prior art, the computer unit generates a Distinguishing signal which corresponds to a video signal during a blanking period is superimposed, and the display unit switches the deflection frequency on the Basis of the distinction signal.

In the former prior art (Publication No. 1-321475) of the above two well-known publications, since both the display position and the Display size of the image controlled by the display unit, it is for the Operator necessary to keep his fingers off the input device, such as the Disconnect keyboard that is connected to the computer unit, and his hands to reach the setting switches of the display unit, which are on a separate Position is arranged when the setting of the display position and size of the Image is required. Accordingly, it is troublesome to handle.

Furthermore, in the latter prior art (publication No. 2-60193) the display status by the input unit, such as the Tas keyboard, which is connected to the computer unit, while controlled, since only the Deflection frequency can only be switched by a binary value, there is one Problem that only two special signals can be traded and one enough gender display status required by the user of the computer, cannot be obtained.

DE 37 22 169 A1 discloses a method and a circuit arrangement for the Fit a multi-mode monitor on a personal computer, whereby the operating values required for the respective operating mode from a memory  can be fetched in which they were previously saved. For this, the Be drive values for an exact setting of the monitor for each operating mode next be determined, set and saved. This first time The operating values are set using an additional control unit, on which for example the brightness, the contrast, the horizontal and vertical amplitudes de and the horizontal and vertical position can be set and saved that can. However, this setting is relatively complex and not during the Operating the computer executable. The for the respective operating mode of the The required operating values can only be exceeded during operation be taken if they have been saved beforehand.

US 5,051,827 relates to the configuration control of a television signal Encoders / decoders, which are the modification of circuit parameters for a TV encoder / decoder enable, a microprocessor is provided, wel is provided with local and remote interfaces in order to obtain parameters hold. The parameters are set on the television itself or via a remote control.

It is the object of the present invention to provide an image display device which the user especially the adjustment of image size and position conveniently allowed.

This goal is achieved by an image display device according to claims 1 and 2, respectively. Further advantageous exemplary embodiments are defined in the subclaims.

The problems in the prior art are advantageously solved by Be Providing an image display device capable of setting a display image len through an input unit, such as a keyboard, close at hand through a computer unit, without hands on a display setting switch unit to reach, and to receive a display status by the user which is required exactly.  

is able to set a display image by an input unit such as for example a keyboard, close at hand by a computer unit, without putting your hands on the setting switch of a display unit, and to get a display status that is accurate by the user is required.

It is another object of the present invention to improve operability in a computer system and the manageability of the image display device to improve.

It is still another object of the present invention to provide an image display provide device that is capable of displaying a display image from a Computer unit by using a conventional one Circuit without providing a new circuit.

In order to solve the above problems according to the present invention, has a computer unit in a general computer system Adding device for adding a control signal for a display image to a video signal or a synchronization signal, and a Display unit has a separating device for separating the added Control signal on and a control device for setting the display state based on the separate control signal.

Alternatively, the computer unit has a preparation Direction to prepare the control signal to use it with a generate certain system, and the display unit has a Control device on for receiving the control signal to the display state based on the control signal.  

Alternatively, the computer unit has display processing processing device for generating the prepared image data and the Control signal for the display image in the form of a digitized signal to the display unit, and the display unit has a control device for preparing an analog video signal and one Synchronization signal from the image data and to generate a Setting signal for setting a predetermined position of the display based on the control signal.

Alternatively, the computer unit has modulation direction for adding the control signal for the display image to a AC power supply to operate the computer unit, and the display unit has a demodulation device for separating of the modulated control signal and a control device for setting an internal circuit of the display unit by the control signal from of the demodulation device in order to produce a predetermined display image receive.

Still alternatively, the control signal is on from the input unit, such as the keyboard, received by the display unit, as it is, and the display unit has an instruction identification direction for identifying the control signal relative to the setting of the Display image and a control device for setting the display image based on a signal from the instruction identification direction up.

The adder of the computer unit adds the control signal for the display unit for the video signal or the synchronization signal, that is generated by the computer unit when the instruction that through the input unit, such as the keyboard  will, on the setting of the display image on the display unit refers. In the display unit, the separation device takes the added Control signal out and the control device provides the internal circuit of the display unit in accordance with the control signal thereby displaying a predetermined image.

Alternatively, the preparation device prepares a control module signal in accordance with the control signal for the display image from the input unit, such as the keyboard, and brings it through an exclusive connecting line, and if the tax device of the display unit receives the control signal, the Control means a predetermined part of the internal circuit of the Display unit in accordance with the control signal and sets the display image.

Alternatively, the display processing device processes one Drawing instruction by a CPU in the computer unit is being used to prepare image data for displaying a video signal and to prepare a control signal for the display image so that the Image data and the control signal to the display unit with a front certain system for transmitting and receiving a digital Signals are created. Furthermore, the control device receives the Image data and the control signal from the display processing device and prepares the video signal, the synchronization signal and the on control signal for the internal circuitry of the display unit.

Alternatively, the modulation device prepares the control signal for the display image of the information or instruction relative to before setting the display image and adds the control signal the AC power supply for the computer unit to do that  Transfer control signal. The demodulation device extracts this Control signal that is added by the modulation device. The Controller provides a predetermined part of the internal circuit the display unit based on the control signal from the demo dulation device to adjust the display image.

In a further alternative manner, the instruction identification identifies one direction of a signal relative to the setting of the display image of signals, directly through the input unit, such as the keyboard, can be entered to prepare the control signal for adjustment. The control device provides the predetermined part of the inner scarf direction of the display unit in accordance with the control signal of the instruction identifier to display the image to deliver.

Further advantages, features and possible uses of the present the invention result from the following description of Embodiments in connection with the accompanying drawing. In the drawing shows:

Fig. 1 is a block diagram schematically a first example of execution of an image display apparatus according to the present invention is illustrated;

Fig. 2 is a block diagram schematically illustrating an actual example of a control signal adding circuit and a display control circuit as shown in Fig. 1;

Fig. 3 is a waveform diagram of signals of Fig. 2;

Fig. 4 is a block diagram schematically illustrating an actual example of a control signal separation circuit and the display control circuit as shown in Fig. 1;

Fig. 5 is a waveform diagram of signals of Fig. 4;

FIG. 6 is a block diagram schematically illustrating another actual example of the control signal adding circuit and the display control circuit shown in FIG. 1;

Fig. 7 is a block diagram schematically showing a second exporting approximately example of an image display apparatus according to the present invention;

Fig. 8 is a block diagram schematically showing a third embodiment of an image display device according to the present invention;

Fig. 9 is a block diagram schematically approximately a fourth example exporting an image display apparatus according to the present invention; and

Fig. 10 is a block diagram schematically approximately a fifth example exporting an image display apparatus according to the present invention.

Fig. 1 is a block diagram schematically showing a first game according Ausführungsbei illustrating an image display apparatus of the present invention veran. In Fig. 1, reference numeral 1 a denotes a computer unit, 11 a CPU, 12 an input unit interface connected to the computer unit 1 a for processing various instruction signals, which are transmitted from a first input unit 10 (which transmits an intention of a user to the computer ), such as B. a keyboard, a mouse, a pen for input, 13, a memory circuit constituting main memory, 14 an input / output terminal for connection to a peripheral device, not shown, 15 a display control circuit for generating a video signal and a synchronization signal for driving a display unit, 16 a control signal adding circuit for superimposing or adding a control signal to the video signal or the synchronization signal generated by the display control circuit 15 , and 17 designating an external memory represented by a floppy disk, a hard disk or a memory card is what is arranged separately from the memory circuit 13 . Furthermore, reference numeral 1 b denotes a display unit, in the reference numeral 18 a control signal separation circuit for extracting the control signal from the video signal or the synchronization signal on which the control signal generated by the control signal adding circuit 16 is superimposed, 19 a first display control circuit for generating a setting signal for a predetermined circuit based on the control signal extracted by the control signal separating circuit 18 , 20 denotes a video circuit, 21 a deflection circuit which is a display driving means, and 22 denotes a cathode ray tube for displaying a video signal.

Operation of Fig. 1 will now be described. In the computer unit 1 a, other parts other than the control signal adding circuit 18 are the same as the general configuration of a conventional personal computer or a work station.

If the user of the computer enters a control instruction for setting the display image in the display unit 1 b by means of a first input unit 10 , such as. B. a keyboard, a mouse, a pen for input, which is connected to the computer unit 1 a, the input unit interface 12 converts the control instruction into a digital signal that is recognized by the CPU 11 , which controls the control signal adding circuit 16 ,

The control signal adding circuit 16 prepares a control signal Sc in accordance with the control instruction. The control signal Se for the display unit 1 b is also superimposed on the video signal R, G or B or the synchronization signal for display, which are generated by the display control circuit 15 , during the vertical return period. The signal on which the control signal Sc is superimposed is represented by the dash (') sign. The control signal Sc is prepared in accordance with the control instruction that is input into the input unit 10 .

The control signal separating circuit 18 of the display unit 1 b separates the added control signal Sc from the video signal R, G or B or of the synchronization signal Hs and Vs, generated by the control signal adding circuit 16 to allow the first display control circuit ren zuzufüh 19, and supplies the video signals R, G and B to the video circuit 20 and the synchronization signals Hs and Vs to the deflection circuit 21 .

The first display control circuit 19 generates adjustment signals Sa and Sb for the video circuit 20 and the deflection circuit 21 based on the findings of the inputted control signal Sc and the signals Sa and Sb to the video circuit 20 to respectively the deflection circuit 21 to to set it.

In this way, the display image is adjusted so that the image desired by the user is displayed in the CRT 22 .

FIG. 2 is a block diagram schematically illustrating an actual example of the control signal adding circuit 16 of FIG. 1, and FIG. 3 is a waveform diagram illustrating waveforms of signals in FIG. 2.

In Fig. 2, reference numeral 161 denotes an address decoder, 162 a data latch circuit, 163 an edge detection circuit for detecting an edge of a pulse, 164 a shift register circuit, 165 and 170 AND circuits, 166 a level conversion circuit for converting a level of a signal, 167 an analog switch, 168 a counter circuit for counting 17 clock pulses and 169 a flip-flop circuit of the set and reset type (hereinafter referred to as an RSFF circuit).

Operation of Fig. 2 will now be described.

As described above, when the user of the computer enters the control instruction for setting the display image on the display unit 1 b by means of the input unit 10 , which is connected to the computer 1 a, the input unit interface 12 delivers the control instruction to the CPU 11 a computer bus BUS. Then the CPU 11 recognizes the control instruction and supplies control data C _D to the control signal adding circuit 16 through the computer bus BUS.

The address decoder 161 supplies the control data C _D to the intermediate data storage circuit 162 when the control data supplied to the decoder are control data for setting the display image of the display unit 1 b. Then, the edge detection circuit 163 detects a leading edge of the vertical synchronizing signal Vs by means of the horizontal synchronizing signal Hs and supplies the Flankenerfas sungsimpuls Pe to the shift register circuit 164, the counter circuit 168 and the RSFF circuit 169th

The counter circuit 168 is supplied with the edge detection pulse Pe as a reset signal and the horizontal synchronization signal Hs as a clock signal and starts its counting operation in response to the rising edge of the clock signal. When the counter circuit 168 counts 17 clocks after the reset signal is input, the counter circuit generates a carry output signal Sca, which is supplied to a reset input terminal of the RSFF circuit 169 . The RSFF circuit 169 thus generates a V gate pulse Pv, as shown in FIG. 3. The control signal Sc for the display unit 1 b is superimposed on the V gate pulse Pv during a high level period C _H.

On the other hand, the shift register circuit 164 reads the held in the data latch circuit 162 control data _D in C Ant word from the edge detection pulse Pe, the sungsschaltung of the Flankenerfas is supplied 163rd The shift register circuit 164 performs the shift operation in response to the clock signal represented by the horizontal synchronization signal Hs generated by the AND circuit 170 during the high period T _{H of} the V gate pulse to generate the control data C _D '. as shown in Fig. 3.

Furthermore, the control data C _D 'are supplied to the AND circuit 165, which generates a logical product of the control data C _D ' and the horizontal synchronization signal H _S. The output signal from the AND circuit is converted into a video signal level by the level conversion circuit 166 to be supplied to the switch circuit 167 . Another input to switch circuit 167 is provided with a B (blue) video signal directly without being processed, and switch circuit 167 selects the output of level conversion circuit 166 during high level period T _H and the B video signal during another low level period TL out by using the V gate pulse Pv as an alternate control signal for the switch to be able to obtain a P 'video signal to which the control signal is added, as shown in Fig. 3. In the embodiment the control signal Sc is added to the B video signal having a low image color sensitivity, while the control signal can be added to another R (red) or G (green) image signal or the synchronization signal Hs or Vs.

FIG. 4 is a block diagram schematically illustrating a first embodiment of the control signal separation circuit 18 and the first display control circuit 19 of FIG. 1, and FIG. 5 is a waveform diagram showing waveforms of signals in FIG. 4.

In Fig. 4, reference numeral 401 denotes a distributor, 402 a low pass filter (hereinafter referred to as an LPF), 403 a level conversion circuit, 404 and 405 buffers, 406 a "divide by 17" counter or 17-step counter, 407 an RSFF circuit, 408 and 409 AND circuits, 410 an inverter, 411 a 16-stage shift register, 412 a decoder circuit, 413 a D / A converter circuit (hereinafter referred to as a D / AC), and 414 an edge detection circuit ,

Operation of FIG. 4 will now be described with reference to FIG. 5.

The B 'video signal from the control signal adding circuit 16 is supplied to the distributor 401 which divides the video signal into two signals, one of which is supplied to the video circuit 20 shown in Fig. 1 together with other video signals R and G and the other to the LPF 402 is delivered. With the B'-video signal supplied to the LPF 402 , an unnecessary frequency component, such as e.g. B. noise contained in the B 'video signal is removed in the LPF 402 , and the B' video signal is then converted to a digital signal level in the level conversion circuit 403 .

Furthermore, the vertical synchronization signal Vs is supplied through the buffer 404 to the edge detection circuit 414 , in which the leading edge thereof is detected, and the RSFF circuit 407 and the 16-stage shift register 411 are input to the 17-step counter 406 as one Fig. 5 pointed edge detection pulse 418 delivery.

When the 17-step counter circuit 406 is reset by the edge detection pulse 418 , the 17-step counter circuit 406 starts its counter operation for the horizontal synchronizing signal Hs, which is supplied by the buffer 405 as a clock signal. So that when rising edges of 17 clocks are counted, the counter circuit generates a 17 clock detection pulse. The RSFF circuit 407 is set by the edge detection pulse 418 and reset by the 17 clock detection pulse to generate the V gate pulse 419 shown in FIG. 5.

The AND circuit 408 takes the logical product of an output signal from the level conversion circuit 403 and the V-gate pulse from the RSFF circuit 407 to extract the control signal 420 added to the B 'video signal. Furthermore, another AND circuit 409 takes a logical product of the V-gate pulse and the horizontal synchronization signal Hs, which is generated by the buffer 405 and inverted by the inverter 410 , to provide a clock signal for the 16-stage shift register 411 and the D / AC (D / A converter) 413 to generate.

The 16-stage shift register 411 is reset by the edge detection pulse 418 to clear the content held therein, and successively receives the control signal 420 in response to the clock signal from the AND circuit 409 . Decoder circuit 412 decodes four held values at the first, second, fifteenth and sixteenth stages of 16-stage shift register 411 , and when the decoder circuit detects the start bit and stop bit in control signal 420 , the decoder circuit generates a load pulse 422 for the D / AC 413 . Furthermore, the output signal from the second stage of the shift register 411 is used as serial data 421 of the D / AC 413 shown in FIG. 5.

The D / AC 413 , which is a multi-channel serial input D / A converter, selects any one of a plurality of D / A converters included therein in accordance with a D / AC control address in the serial data shown in FIG. 5 421 and updates the D / A converted output value in accordance with a value of the control data portion. At this time, the serial data 421 are sequentially taken into the D / AC 413 in synchronism with the clock signal from the AND circuit 409 and are taken over by the decoder 412 by the rising edge (UP) of the load pulse.

Thus, the video circuit 20 shown in FIG. 1 and the deflection circuit 21 can be set by a set voltage or a set current generated by the D / AC 413 as a set signal.

Fig. 6 is a block diagram schematically illustrating a second actual example of the control signal separating circuit 18 and the display control circuit 19 of FIG. 1,. In Fig. 6, reference numeral 601 denotes a selector, 602 a one-chip microcomputer, and 603 a write-only read-only memory (hereinafter referred to as an EEPROM (electrically erasable programmable read-only memory). Other elements with the same reference numerals as in Fig. 4 have the same function.

Operation of Fig. 6 will now be described.

The operation that the control signal Sc added to the B 'video signal is separated by the AND circuit 408 and that the clock signal is prepared for writing the shift register 411 by the AND circuit 409 is quite the same operation as that of Fig. 4. in the second example, the microcomputer 602 is used to the control signal to the display unit 1 to process b, which is sent from the position shown in Fig. 1 computer unit 1 a.

First, the microcomputer 602 normally controls the selector 601 to select the clock signal for writing from the AND circuit 409 and to write the control signal to the shift register circuit 411 . At this time, the edge detection pulse is supplied from the edge detection circuit 414 to the microcomputer 602 as an interrupt signal 418 , and after a predetermined time, the microcomputer 602 controls the selector 601 by a selection control signal Ss to generate the clock signal S _CL for reading from the microcomputer 602 to select.

The control signal held in the shift register circuit 411 is successively read out in response to the clock signal S _CL for reading from the microcomputer 602 and is supplied to the microcomputer 602 . If the signal supplied to the microcomputer is the correc th control signal, the microcomputer 602 generates the control data to supply it to the D / AC 413 to thereby processing a predetermined scarf in the display unit 1 b set. The control data are also written to the EEPROM 603 . Thus, when the display unit 1 to b is next turned on, the control data from the EEPROM 603 is read out to the predetermined position A to perform.

Furthermore, in the second example, by previously storing the control data in the EEPROM 603, necessary control data can be read out from the computer unit 1 a in accordance with the control signal S _C. Accordingly, the control information can be used for the on display unit 1b in advance in the software for operating the computer unit can be programmed in addition to the control information from the input unit 10 so that a predetermined setting for each software can be made.

As described above, in the first embodiment of the present invention, the control signal is added to the video signal or the synchronization signal during the vertical return period, while a DC level itself of the video signal can be used as the control signal. In this case, the control signal may separator circuit 18 to the DC level of the video signal reproduzie ren and the predetermined circuit of the display unit 1 b in Convention humor with a voltage value of the DC voltage level set. Further, in the first embodiment, the video circuit 20 and the deflection circuit 21 of the display unit 1 can be set b, whereas a high-voltage circuit section can be of course controlled to adjust the focus or the like.

Fig. 7 is a block diagram schematically illustrating a second embodiment of the present invention. In Fig. 7, reference numeral 1 c denotes a computer unit that is different from the computer unit shown in Fig. 1, and in the computer unit 1 c, reference numeral 70 denotes a control signal preparation circuit. Furthermore, reference numeral 1 d a display unit which is under differently from that shown in Fig. 1 display unit 1 and d in the display unit 1, reference numeral 71 erschaltung a second Anzeigesteu which are different from that shown in FIG. 1, the first control circuit 19 is. Other elements denoted by the same reference numerals as those of FIG. 1 have the same function as those of the elements of FIG. 1.

Operation of Fig. 7 will now be briefly described.

In Fig. 7, the video signal and the synchronization signal are generated by the display control circuit 15 in the same manner as in a general personal computer or a work station.

When the user of the computer inputs the control instruction for setting the display image of the display unit 1 d by means of the input unit 10 connected to the computer unit 1 c, the control instruction is sent to the control signal preparation circuit 70 through the input unit interface 12 , the CPU 11 and sent the computer bus BUS.

The control signal preparation circuit 70 holds the control instruction and prepares the control signal in accordance with the control instruction in order to present it to the display unit 1 d at a correct time determination. An output system of the control signal can at this time an existing interface such. B. Use RS-232C, GP-IB and SCSI. Accordingly, the control signal preparation circuit 70 includes the interface circuit.

The second display control circuit 71 of the display unit 1 d receives the control signal generated by the control signal preparing circuit 70, enclosed by the same interface circuit such as those ersignalvorbereitungsschaltung in the CONT 70, and generates the tuning voltage or current setting for the video circuit 20 and the deflection circuit 21 as the setting signal based on the received control signal to set the video circuit 20 and the deflection circuit 21 .

In the second embodiment of the present invention, a two-way communication between the display unit 1, since the control signal transmitted by the general-purpose interface, and is gen are received,, d and the computer unit 1 are made c. Accordingly, the computer unit can recognize whether the display unit 1 d has received the control signal exactly or not, what the control state of the display unit 1 d is at the current time or whether the display unit 1 d is operated exactly or not.

Fig. 8 is a block diagram schematically illustrating a third embodiment of the present invention. In Fig. 8, reference numeral 1 e represents a computer unit different from that of Figs. 1 and 7, and in the computer unit 1 e, reference numeral 81 represents a display processing circuit for preparing image data for a display image, and 82 an interface circuit. Reference numeral 1 f represents a display unit which is different from that of FIG. 1 and 7, 83 an interface circuit and 84 a display controller f to prepare various signals for driving the display unit 1. The interface circuit (hereinafter referred to as I / F circuit) 82 and 83 serves to transmit and receive signals between the display processing circuit 81 in the computer unit 1 e and the display controller 84 in the display unit 1 f. Other elements with the same reference numerals as those of Figs. 1 and 7 have the same function.

Operation of Fig. 8 will now be described.

An image processing instruction issued by the CPU 11 is supplied to the display processing circuit 81 through the computer bus BUS. The display processing circuit 81 receives the image processing instruction and prepares the image data for the display image.

At this time, when the user of the computer inputs the control instruction for setting the display image on the display unit 1 f by means of the input unit 10 connected to the computer unit 1 e, the control instruction is sent to the display processing circuit 81 through the input unit interface 12 , the CPU 11 and the computer bus. When receiving the display processing circuit 81, the control instruction, prepares the display processing circuit 81, the control signal in a predetermined location in front, which is other than that of the image data area.

The image data and the control signal are thus sent to the display unit 1 f through the I / F circuit 82 as the image information in accordance with a predetermined interface specification, e.g. B. the SCSI standards with a high transmission rate.

In the display unit 1 f, the I / F circuit 83 receives the image information from the I / F circuit 82 and successively supplies the image information to the display controller 84 . The display controller 84 successively writes the received image information into an internal memory and prepares the video signals for R, G and B and the synchronization signal from the image data portion of the written image information. Furthermore, the tuning voltage or the current setting as the setting signals Sa 'and Sb' when the control signal is present in the image information for the video circuit 20 and generates the deflection circuit 21, to adjust the video circuit 20 and the deflection circuit 21st

In addition, if the image information written in the internal memory of the display controller 84 is not updated within a predetermined time, the display controller 84 controls the video circuit 20 to minimize an amplitude level of the video signal so that the brightness of the CRT 22 is reduced to prevent burn-in to prevent the cathode ray tube 22 . Even in the third embodiment of the present invention, since the interfaces between the computer unit 1 e and the display unit 1 f have the ability for two-way communication, not only the image data and the control signal can be transmitted from the computer unit 1 e, but also a signal for confirmation of receipt and a report signal for the operating situation can be transmitted by the display unit 1 f. Furthermore, since the computer unit 1 e is connected to the display unit 1 f by a single interface cable, the complexity of the connection can be solved.

Fig. 9 is a block diagram schematically showing a fourth Ausführungsbei play illustrates the present invention. In Fig. 9, reference numeral 1 g a computer unit is, which is different from that of Fig. 1, 7 and 8, and g in the computer unit 1 represents the reference numeral 91 a modulation circuit. The reference numeral 1 h represents a display unit, which is different from that of Figs. 1, 7 and 8, and in the display unit 1 h, reference numeral 92 represents a display control circuit, 93 a demodulation circuit and 94 and 95 power supply plugs. Other elements with the same reference numerals as those of Fig. 1 have the same function.

Operation of Fig. 9 will now be described.

When the user of the computer inputs the control instruction for setting the display image of the display unit 1 h by means of the input unit 10 connected to the computer unit 1 g, the control instruction is supplied to the CPU 11 through the input unit interface 12 . The CPU 11 processes the control instruction and supplies the control signal corresponding to the control instruction to the modulation circuit 21 through the computer bus BUS. The modulation circuit 91 modulates the received control signal and superimposes it on the AC power supply in order to transmit the signal from the power supply plug 94 through a power supply line PL to the display unit 1 h.

In the display unit 1 h, when the AC power supply is supplied from the power supply connector 95 through the power supply line PL, the demodulation circuit 93 demodulates the modulated control signal that is superimposed on the AC power supply to reproduce the original control signal. The reproduced control signal is supplied to the display control circuit 92 . The display control circuit 92 generates the set voltage or current as the set signals Sa and Sb for the video circuit 20 and the deflection circuit 21 in accordance with the contents of the control signal to set the video circuit 20 and the deflection circuit 21 .

In this way, in the exemplary embodiment, since the control signal is transmitted to the display unit 1 h through the power supply line PL, the display unit 1 h can be controlled without an increased or additional signal line for the control signal.

Fig. 10 illustrates schematically a fifth embodiment of the present invention. The fifth embodiment will now be briefly explained. In Fig. 10, reference numeral 1 represents a computer unit represented by a general personal computer or a work station, 1j a display unit different from that of the previous embodiments, 101 a second input unit such as a keyboard. B. a keyboard, a mouse or a stylus, which is connected to the computer unit 1 and the display unit 1 j, 102 a command identification circuit in the display unit and 103 a third display control circuit. Other elements with the same reference signs as those of Fig. 1 have the same function.

In Fig. 10, when the user of the computer operates the second input unit 101 , an input signal such as. B. the control instruction to the computer unit 1 and to the display unit 1 j. The input signal input to the display unit 1 j is processed by the command identification circuit 102 and taken out as the display control signal when the input signal is an instruction regarding the display control. The third display control circuit 103 controls the display operation by the control voltage or the control current against the associated part of the video circuit 20 and the deflection circuit 21 based on the display control signal. In the embodiment of Fig. 10, since the computer unit does not prepare the control signal for display, there is no load imposed on the CPU of the computer. In this way, the user of the computer can control the display unit by means of the second input unit without direct contact with the display unit. The signal line, which is connected from the second input unit 101 to the display unit 1 j, can use the signal line connected to the computer unit 1 , since they are or can be an exclusive signal line for the transmission of only the display control signal. In the former case, the input unit, such as. B. the general keyboard can be used as it is. In the latter case, it may be necessary to add a special input unit for display control to the second input unit. Furthermore, a remote control circuit using infrared rays or the like can be used to reduce the number of connection lines between the second input unit 101 and the display unit 1 j, so that the complexity due to the wiring can be reduced. In the fifth embodiment, an input unit such as. B. a mouse, a touch plate, a stylus or the like, are of course used as the input device for the control instruction, in addition to the keyboard.

According to the present invention, the following effects are obtained:

• 1. The user of the computer can view the display image through the Input unit, such as B. the keyboard, near the hand through the Control the computer unit without turning your hands to the setting switches Extend the display unit.
• 2. The user can get the necessary display status exactly. ( 3 ) The operability in the computer system and the handling ability of the display unit are improved.
• 3. The individual user can view the display state of the image set the counters according to the circumstances.
• 4. The setting of the display image can be done with the minimum control Hardware can be obtained.
• 5. Standard lines can be made without the provision of new lines be used.
• 6. The complexity due to the wiring can be determined by the Ver using a remote control circuit can be avoided.
• 7. It is possible to optimally display the image on the display unit by stopping the operation of software using the Control program of a display that is in the application program  is integrated on the computer side, and accordingly it is not necessary for the user to take care of the setting of the display.

The invention further relates to an image display device having an input unit 10 , a computer unit 1 a, 1 c, 1 e, 1 g, 1 and a display unit 1 b, 1 d, 1 f, 1 h, 1 , the computer unit having an adding device 16 has for preparing a control signal Sc based on a control instruction input through the input unit, for setting a display image of the display unit and for adding the control signal to a video signal R, G or B or a synchronization signal Hs or Vs which are separate for driving of the display unit to be applied to the display unit, and wherein the display unit has a separator for separating the added control signal from the video signal or the synchronization signal generated by the adding device, and a display control device 19 for generating a setting signal on the Basis of the control signal generated by the separator, u m to set a display drive device 20 , 21 in the display unit.

A special embodiment relates to such an image display device, the computer unit 1 a, 1 c, 1 e, 1 g, 1 additionally comprising a CPU 11 and a signal generating device 15 for generating the video signal and for generating a horizontal synchronization signal Hs and a vertical synchronization signal Vs as that Synchronization signals, and wherein the adder 16, a hold circuit 162 for holding the control instruction, which is input by the input unit 10 and which is provided by the CPU 11 , a shift register circuit 164 for receiving contents of the hold circuit with the vertical synchronization signal Vs as a reference , a counter circuit 168 for counting the horizontal synchronization signal Hs by a predetermined value with the vertical synchronization signal Vs as a reference, a gate circuit 170 for supplying the horizontal synchronization signal as a read clock of the shift register circuit, b When the counter circuit counts to the predetermined value with the vertical synchronizing signal Vs as the reference, a level conversion circuit 166 for converting a level of a signal read out from the shift register circuit into a level of the video signal generated by the signal generator 15 , and a selection circuit 167 , for selecting an output of the level conversion circuit during one output period of the gate circuit and for selecting the video signal during another period.

An alternative special embodiment relates to such an image display device, the display unit 1 b, 1 d, 1 f, 1 h, 1 additionally having a video circuit 20 and a deflection circuit 21 , and the control device having a multiplicity of digital / analog converter circuits 413 , which means that a predetermined digital-to-analog converter circuit 413 is selected from the plurality of digital-to-analog converter circuits based on address information included in the control signal Sc generated by the separator and control data 420 included in the control signal Sc are converted into a set voltage or a set current as the set signals by the digital-to-analog converter circuit to set the video circuit 20 and the deflection circuit 21 .

An alternative special embodiment relates to such an image display device, the display unit additionally comprising a video circuit 20 and a deflection circuit 21 , and the control device having a microcomputer 602 , a non-volatile memory 603 and a multiplicity of digital / analog converter circuits 413 , wherein when a Energiever supply of the display unit is turned on, control information is read out in the nonvolatile memory 603 by the microcomputer 602 to a predetermined circuit 413 of the plurality of digital / analog converter circuits to be delivered 413, so that the video circuit 20 and the deflection circuit 21 is set by an output of the digital / analog circuit 413 , and when the control signal Sc is generated by the separator 18 , the control signal is processed by the microcomputer 602 to be applied to a predetermined circuit 413 of the plurality of digital / analog Converter circuit to be supplied so that the video circuit 20 and the deflection circuit 21 are set by an output of the digital-to-analog converter circuit and the control signal is written into the non-volatile memory 603 as the information.

An alternative special embodiment relates to such an image display device, wherein in addition the adding device the prepared control signal Sc to the separately generated video signal R, G or B during a vertical blanking period added.

An alternative special embodiment relates to such an image display device, the input unit 10 additionally having a keyboard, a mouse and an input pen.

The invention further relates to an image display device which has an input unit 10 , a computer unit 1 c and a display unit 1 d, the computer unit 1 c having a preparation device 70 for preparing a control signal Sc on the basis of a control instruction which is input by the input unit 10 , for setting a display image of the display unit 1 d to apply the control signal to the display unit 1 d, and wherein the display unit 1 d has a control device 71 for generating a setting signal based on the control signal generated by the preparation device 70 to the Display drive device 20 , 21 set in the display unit 1 d.

A special embodiment relates to such an image display device, wherein in addition a delivery of the control signal Sc from the computer unit 1 c and the preparation device 70 to the control device 71 in the display unit 1 d is produced by means of a general-purpose interface, the preparation device 70 having a signal input device, wherein said control means includes a signal output means and said information of an operating situation of the display unit 1 with respect to d is able to be transmitted through the interface of the display unit 1 d to the computer unit.

The invention further relates to an image display device which has an input unit 10 , a computer unit 1 e and a display unit 1 f, the computer unit 1 e having a display processing device 81 for processing a control signal Sc on the basis of a control instruction which is input by the input unit 10 for setting a display image of the display unit 1 f to the control signal to the display unit 1 f to create, together with the image data separately for displaying an image in the display unit 1 f are produced, and wherein the display unit 1 f a control device 84 has to Preparing video signals R, G and B and synchronization signals Hs and Vs based on the image data generated by the display processing device 81 and generating an adjustment signal based on the control signal generated by the display processing device 81 around the display drive device 20 , 21 to be set in the display unit 1 f.

A special embodiment of this relates to an image display device, in addition to which the control device 84 controls the display drive device 20 , 21 in the display unit 1 f in order to set the display unit 1 f in order to be in a non-display state or in a state close to the non-display -State when the image data generated by the image processing device 81 is not renewed for a predetermined time.

The invention also relates to an image display device which has an input unit 10 , a computer unit 1 g and a display unit 1 h, the computer unit 1 g having a modulation device 91 for preparing a control signal Sc on the basis of a control instruction which is input by the input unit 10 for setting a display image of the display unit 1 h and modulating the control signal to add the control signal to an AC power supply PL, and wherein the display unit 1 h has a demodulation device 93 for separating the added control signal Sc from the AC power supply PL to demodulate the control signal, and a control device 92 for generating a setting signal based on the control signal Sc generated by the demodulation device 93 to set the display drive device 20 , 21 in the display unit 1 h.

The invention also relates to an image display device which has a second input unit 101 , a computer unit 1 and a display unit 1 j, the computer unit 1 and the display unit 1 j being supplied with part or old of the instructions which are input by the second input unit 101 , and wherein the display unit 1 j is a preparation device 102 for preparing a control signal Sc based on the control instruction to generate it when an instruction input by the input unit 101 is a control instruction for setting a display image of the display device 1 j, and a control device 103 has for generating a setting signal based on the control signal Sc generated by the preparation device 102 to set the display drive device 20 , 21 in the display unit 1 j.

A special embodiment of this relates to an image display device, the second input unit 101 additionally having an exclusive input part for exclusively entering the control signal, and an instruction input to the exclusive input part being delivered to at least the display unit 1 j.

An alternative special embodiment relates to such an image display device, wherein in addition a transmission of the instruction from the second input unit 101 to the display unit 1 j is established by means of infrared rays or radio waves, thereby increasing the number of connecting lines between the input unit 101 and the display unit 1 j to reduce.

An alternative special embodiment relates to an image display device, the input unit 101 additionally having a keyboard, a mouse and a pen for input.

Claims (5)

1. Display unit for connection to an external computer ( 1 c) which outputs a video signal (R, G, B) and a synchronization signal (Hs, Vs), the display unit comprising:
a video circuit ( 20 ) receiving and demodulating the video signal (R, G, B);
a deflection circuit ( 21 ) which receives the synchronization signal (Hs, Vs) and generates vertical and horizontal deflection signals therefrom;
a display device ( 22 ) connected to the video circuit ( 20 ) for outputting an image on a screen based on the video signal (R, G, B) and the vertical and horizontal deflection signals;
a communication and control circuit ( 71 ) having an input which is connected to an interface which is suitable for bidirectional communication, irrespective of lines which carry the video and synchronization signals, the communication and control circuit being a command signal, the commands for controlling the display position and size adjustment results, (c 1) receives from the external computer through the interface, and having an output which is coupled to the deflection circuit (21) for controlling the deflection circuit (21) to position and / or adjust the size of the image on the screen in accordance with the position and size setting information contained in the command signal, the communication and control circuit ( 71 ) further generating feedback signals which are interfaced to the external computer ( 1 c) be transferred. 2. Display unit with video and synchronization signal connections for receiving video and synchronization signals (R, G, B; Hs, Vs), comprising:
a display device ( 22 ) for displaying an image based on a video signal (R, G, B) and a synchronization signal from an external computer ( 1 c);
a command signal connection, connected to the external computer ( 1 c), for receiving a command signal which is indicative of settings for the display position and / or size, and for outputting feedback signals;
a communication and control circuit ( 71 ) which controls the size and / or position of the image on the screen based on the command signal and which generates the feedback signals, the communication and control circuit ( 71 ) being connected to the command signal terminal for Receiving the command signal from the external NEN computer ( 1 c) via the command signal connection independently of the video signal (R, G, B) and the synchronization signal (Hs, Vs) and for outputting the feedback signals to the external computer ( 1 c) via the command signal connection , and wherein the communication and control circuit ( 71 ) is also connected to the deflection circuit ( 21 ) for controlling the setting of the position and size of the display according to the command signal, the feedback signals having information indicating confirmation of receipt of the control signal , 3. Display unit according to claim 1 or 2, wherein the communication and control circuit ( 71 ) comprises a microprocessor ( 602 ). 4. Display unit according to claim 1, wherein the communication and control circuit ( 71 ) has a microprocessor ( 602 ) having an input which is connected to the command signal line for receiving the command signal and having an output which is connected to the command signal line is connected to emit a display status feedback signal which is characteristic of a status of the display unit. 5. Display unit according to claim 2, wherein the communication and control circuit ( 71 ) has a microprocessor ( 602 ) having an input which is connected to the command signal connection for receiving the command signal and having an output which is connected to the command signal connection is for sending a display status feedback signal, which is indicative of a status of the display unit.