DE3838348A1 - Arrangement having a plurality of display device controllers - Google Patents

Abstract

In process control engineering a plurality of display device controllers (ST1, ST2) having visual display units (SG1, SG2) are used in operation and monitoring control rooms or process control systems, on the screens (BS1, BS2) of which visual display units pixels flash in a clock-controlled manner in various frequencies and colours. To avoid asynchronous flashing of the pixels represented on the various screens (BS1, BS2), which flash at the same frequency, the display device controllers (ST1, ST2) are in each case provided with a sequence control system (AS1, AS2) which generate in a first operating mode a first clock (Tae) for controlling the flashing of the pixels and a second clock (Tye) for synchronising the flashing and switch to a synchronisation bus (SYB) and are controlled in a second operating mode in such a manner that they receive the first and the second clock signal (Tae, Tye) from the synchronisation bus (SYB) and thus control the flashing of pixels on the screen (BS1, BS2) of the visual display unit (SG1, SG2) assigned to them in each case, in each case one display device controller (ST1, ST2) functioning in the first operating mode and the others being in the second operating mode. The invention is used in particular in colour graphics visual display units. <IMAGE>

Description

The invention relates to an arrangement with a plurality of viewing devices Controls according to the preamble of claim 1.

In graphic applications of viewing devices, especially in the process technology, is a clear representation of complex processes. This presentation is intended at the same time point out all the essentials and yet quickly and easily be overlooked. For example, instead of columns of numbers or a fold scale display level indicators desired, the if possible also colored markings for Mini painting and maximum states included. In addition, the current Level indicators in a specific color flash when the Maximum mark is exceeded. Flow processes or processes in the Processes should also be presented as such.

In order to enable such a type of representation, a Display control in a graphics system to be able to Delivering flashing signals in different frequencies differs to process the flashing colors and at every flashing frequency to provide phase-shifted flashing signals to a to represent moving color images. The assignment of Flashing color, flashing frequency and flashing phase can be changed be. Such a display device control is in the patent application P 38 05 998.3 proposed.

In process control technology, larger operating and monitoring caution waiting or process control centers several such graphics systems used. It shows that the representations of System parts or of process flows on several graphics systems must be distributed. Since every display device for supply with the necessary control signals a separate display device control display processes run independently of each other. This means that the operating and observation technology very often used flashing light  Representations and chaser effects are also asynchronous be controlled. This results in asynchronicity of the Blinking, even when the blinking frequencies change only very differ little from each other or even phase to each other are displaced, are very disturbing to the viewer when there are several viewing devices in his field of vision.

The present invention is therefore based on the object to eliminate this interference effect.

This object is achieved by the characterizing Part of claim 1 specified measures solved.

In process technology, the pixels usually flash on the various screens with a flashing frequency of 0.5 Hz, 2 Hz or 8 Hz. The pixels that are on a Blin screen with a frequency of 0.5 Hz, 2 Hz or 8 Hz ken, also on the remaining screens with a frequency of 0.5 Hz, 2 Hz or 8 Hz flash in phase. To do this the viewing devices with a common one, from a process control clock signal supplied to generate the various flashing signals at the same frequency. If the display device, whose sequence control be for generating the flashing signals supplies necessary clock signal, switched off, so takes over partly the flow control of another to the synchronizer sationsbus connected display device automatically the Er generation of a clock signal.

Based on the drawing in which an embodiment is clear, the invention, its configurations as well as described and explained advantages. It shows

Fig. 1 is a block control diagram of a known vision devices,

Fig. 2 is a schematic diagram of two coupled vision systems,

Fig. 3 is a block diagram of a sequence control for synchronization of a display system and

Fig. 4 timing diagrams of clock signals of a sequence control and flashing signals of time controls.

In Fig. 1, the screen of a display device SG is designated BS . Each pixel can be displayed differently, ie different attributes must be defined with attribute numbers. A flashing frequency, a flashing phase and flashing colors for the flashing states "On" and "Off" are assigned to each attribute number. An attribute memory AP , which is addressed with the attribute numbers stored in a frame buffer BWS , stores these assignments. Each memory cell of the attribute memory AP therefore contains the blink codes and the color codes for the blink states "blink on" or "blink off". The blink codes control a first selection circuit DMX via lines Lb , the color codes are supplied to a second selection circuit DMU via lines Le, La . Blinking signals with different blinking frequencies and at least one group of phase-shifted blinking phase signals are generated by a time control ZS , which is controlled by a clock Ta of a clock generator, not shown. The timing controller ZS feeds these signals via lines Ls to the first selection circuit DMX , which connects one of these signals to the second selection circuit DMU as a control signal. Which signal of the timing ZS is switched through via the selection circuit DMX to the selection circuit DMU is from is set dependent from the blink code stored in the attribute memory AP and circuit via the lines Lb to the control input of the selection DMX. With this blink code one of the lines Ls is addressed and the signal on the addressed line is switched through a line Lf to the second selection circuit DMU . Depending on the signal present via the line Lf, the latter selects one of the two color codes supplied from the attribute memory AP via the lines Le, La to a color table FT . For example, the signal value is log. "1" of the present across the line Le color code for the flash state "On" and log the signal value. "0" the color code for the blinking state "Off" which is present via line La is passed on. A color table FT is connected to the second selection circuit DMU , which produces the assignment between the color codes and binary color values R, G, B for the basic colors red, green and blue. These color values are converted into video signals in the display device SG . Which colors are stored in the color table and which attribute assignments are stored in the attribute memory AP is defined in a graphical user program to be processed by a central processor ZP and is stored in a working memory AB . The attribute assignments and selected colors arrive in the attribute memory AP and in the color table FT via a system and data bus SD . A graphics controller GC , which supplies horizontal and vertical synchronizing pulses H, V to a video output stage of the display device SG , not shown, addresses the memory cells of the image repetition memory BWS assigned to the pixels and stores the attribute numbers therein.

When using multiple display device systems in process control the time controls of the display device controls controlled with clocks from different clock generators. These bars therefore often behave asynchronously, which causes time controls produce phase-shifted flashing signals.

Fig. 2 illustrates the coupling of two display device systems SY 1 , SY 2 . The first display device system SY 1 consists of a display device SG 1 with a screen BS 1 and a display device control ST 1 . An essential component of the display device control ST 1 is a sequence control AS 1 for synchronizing the display device system SY 1 . The second display device system SY 2 is accordingly equipped with a display device SG 2 with a screen BS 2 and a display device control ST 2 with a sequence control AS 2 . The display device systems SY 1 , SY 2 are coupled via a synchronization bus SYB . Of course, several display device systems can be connected to the synchronization bus SYB . The respective sequence controls AS 1 , AS 2 can have both controlling behavior (master function) and controlled behavior (slave function). Controlling behavior means that e.g. B. a clock of the sequential control system AS 1 both the display system SY 1 and via the synchronization bus SYB the display system SY 2 produces a clock signal. Both display device systems SY 1 , SY 2 therefore behave synchronously with regard to their flashing signals of the same frequency. While the sequential control system AS 1 has a controlling behavior, the sequential control system AS 2 is supplied with a clock signal by the sequential control system AS 1, and a clock signal generated by the sequential control system AS 2 does not reach a time control of the display device system SY 2 nor on the synchronization bus SYB Supply of the sequence control AS 1 of the display system SY 1 with this clock signal. Controlled behavior means that e.g. B. the sequence controller AS 1 receives the required clock signal from the sequence controller AS 2 .

FIG. 3 shows a block diagram of a sequence controller AS of a display device controller which is connected to the synchronization bus SYB with a bus interface BA . It is initially assumed that this sequential control system AS works in master mode. A clock generator TG generates a first clock signal Tai and a second clock signal Tyi . As is known, the first clock signal controls a time control of this display device control and time controls of display device controls additionally connected to the synchronization bus SYB , the sequence controls of which operate in slave mode. These timers generate flash signals with different flash frequencies from the clock signal Tai . These flashing signals determine the flashing states "On" and "Off", which are shown in different colors. As described in FIG. 1, for example, a signal value is log. "1" of a flashing signal of the applied via line Le color code for the flash state "on" and log at a signal value. "0" the color code present via the line La for the flashing state "off" is switched to the color table FT , which produces the assignments between the color codes and the binary color values R, G, B. The second clock signal Tyi , a system clock signal, resets the flashing signals to a defined initial state. This ensures that all display unit controls connected to the SYB synchronization bus assume the same flashing state. The timers are therefore provided with a reset input to which the second clock signal Tyi is present.

FIG. 4 illustrates with time diagrams the first and second clock signals Tai, Tyi , which generates a sequence control, and flashing signals B 1 , B 2 generated by two time controls . The sequence controller works in master mode and switches the clock signals Tai, Tyi to the synchronization bus to supply the rest of the sequence controllers connected to the synchronization bus, which receive the two clock signals Tai, Tyi as external clock signals Tae, Tye . A control of a first display device system generates a flashing signal B 1 from the first clock signal Tai . At a time Tz , a second display system is connected to the synchronization bus, which forms a second flashing signal B 2 from the clock signal Tae . The flashing signals B 1 , B 2 have the same frequency, but are out of phase by half a period. This causes the pixels of the display system SY 1 , z. B. during a period of time T , in a flashing state "on" in the color red on the screen, while the pixels of the display system SY 2 are shown in a flashing state "off" with the color green. This phase shift is eliminated by a pulse Pu of the clock signal Tye at a time Tp . From this point on, the flashing signals B 1 , B 2 run in phase again, and the pixels to be imaged assume the same flashing states. The flashing signals B 1 and B 2 run synchronously and thus the different flashing signals of the same frequency generated by the time controls.

The clock signal Tai and the system clock signal Tyi are applied to an evaluation unit AE and a gate circuit TR ( FIG. 3). The evaluation unit AE of the sequential control system AS , which, as presupposed, works in the master mode, applies an enable signal Fs to the gate circuit TR , which means that the two internal clock signals Tai, Tyi on the synchronization bus SYB as external signals Tae, Tye to supply the rest of the display device controls.

A Totzeitüberwachungsschaltung TS receives as the dead time of the sequential control of the remaining connected to the synchronization bus SYB vision monitoring circuits systems, the system clock signal Tye and examined whether the are received, generate clock signal Tye with the internal, erzeug from the clock generator TG th clock signal Tyi, which also monitoring circuit of the Totzeitüber TS switches, is identical. The dead time monitoring circuit TS takes into account the signal delay between the time of generation of the clock signal Tyi and its connection to the synchronization bus SYB . If the dead time monitoring circuit TS detects that the received signal Tye is its own signal Tyi , it supplies a blocking signal Ss to a received signal evaluation circuit EA . Due to this blocking signal Ss switches the reception signal evaluation circuit EV an enable signal Ma to the evaluation unit AE, which causes the analysis unit AE continues to place the clock signals Tai, Tyi on the synchronization bus SYB as external clock signals Tae, Tye and the interene clock signal Tai the timing the own display control. The clock signals Tye, Tae do not reach the evaluation unit AE from the received signal evaluation circuit EA .

It is now assumed that the clock signal Tye , which is present at the dead time monitoring circuit TS at a certain point in time, is not identical to the clock signal Tyi generated by the clock generator TG . This means that the clock signal Tye is present at the dead time monitoring circuit TS at an earlier point in time than the internal clock signal Tyi could be present at the dead time monitoring circuit TS if the sequential control system AS were still operating in the master mode, which indicates that another is on the synchronization bus SYB connected display device system has taken over the master function. The dead time monitoring circuit TS therefore does not switch a blocking signal Ss to the reception signal evaluation circuit EA and now instead of the release signal Ma only applies the clock signals Tye, Tae to the evaluation unit AE . The evaluation unit AE then does not switch an enable signal Fs to the gate circuit TR . The clock signals Tai, Tyi generated by the clock generator TG are not switched through to the synchronization bus SYB or to the time control of the own display device control. The sequence control AS now works in slave mode and switches the signals Tye and Tae received by the received signal evaluation circuit EA to the time control of the own display device control.

It is now possible that the sequential control system AS has to take over the master function again at a later time, e.g. B. a display device that is currently working as a master is switched off. Therefore, the evaluation unit AE is designed so that it switches the clock generator TG in the slave mode to synchronize the internal clock signals Tyi and Tai, the external clock signals and Tye Tae to the clock generator TG. A clock failure circuit AF detects a failure of one of the two clock signals Tye, Tae . The clock failure circuit AF applies a failure signal Aa to the evaluation unit AE , and the sequence controller AS operates again in master mode, the clock generator TG supplying signals Tyi, Tai which correspond to the original clock signals Tye, Tae .

Claims (2)

1. Arrangement with a plurality of display device controls (ST 1 , ST 2 ) to which the display devices (SG 1 , SG 2 ) are connected, on their screens (BS 1 , BS 2 ) pixels flash clock-controlled, characterized in that the view device controls (ST 1 , ST 2 ) are each provided with a sequence control (AS 1 , AS 2 ) which, in a first operating mode, generate and open a first clock (Tae) for controlling the blinking of pixels and a second clock (Tye) for synchronizing the blinking switch a synchronization bus (SYB) and are controlled in a second operating mode such that they receive the first and the second clock signal (Tae, Tye) from the synchronization bus (SYB) and thus the flashing of pixels on the screen (BS 1 , BS 2 ) control the visual display device (SG 1 , SG 2 ) assigned to them, one visual display control (ST 1 , ST 2 ) each operating in the first operating mode and the others in the second operating mode. 2. Arrangement according to claim 1, characterized in that the sequential controls (AS 1 , AS 2 ) in the event of failure of the controller in the first mode of operation automatically from the first mode to the second mode or from the second mode in the first mode switch.