EP0970869A2 - Method for securely displaying the status of a signalling installation - Google Patents

Abstract

The method involves an operating position calculator (BPR) in which two image construction modules (BAM1,BAM2) to which state data (i1) is submitted to create independent symbol images made of pixels, at least module transferring the symbol images to a display module (AZM) at which the color value of each pixel of the symbol image is explicitly identified for display on a screen (BS). The image construction modules refer to templates stored in memories (SPC1,SPC2). An Independent claim is included for an operating position calculator to carry out the state display method.

Description

The invention relates to a method for reliably displaying the status of a signal-technical System on a screen and a workstation computer for execution of the procedure.

introduction

In signal boxes and operations control centers, the current status becomes more signal-related Attachments displayed on screens. For example, busy states are visualized of track sections, the location of switches and signal terms. The operating staff, e.g. B. a dispatcher, based on the displayed condition Decisions and intervenes specifically in the operation of the plant. If the status is displayed, the operating personnel cannot see it Corruption of visual information, such interventions can endanger the operation.

Various methods have therefore been developed, such as adulteration of Screen displays can be reliably recognized. For example, from the DE-C2-43 06 470 a method is known in which supplied status data in two independent logical channels are prepared and compared with each other. The graphical user interface is preferably from an X-Windows system made available.

Fig. 1 shows the basic structure of an X-Windows system. Essential components are an X server XSERV and one or more client applications CLAPP1 and CLAPP2. The client applications usually rely on an X-library XLIB on which the client applications have an agreed command set available poses. Calls REQU from the client applications to the X server XSERV translated into the X protocol by the X library XLIB and via a network NETW transmitted. The X-Server XSERV creates a directly on the Screen BS displayable image. In addition to the screen are attached to the X server in the Usually input devices such as keyboard TAS and mouse MOUSE connected. The X server cares u. a. for the fact that different windows can be called up via the input devices and can be changed in size and position. Between the X server and the screen only a graphics card is switched, which u. a. a refresh memory contains.

Signals generated by the input devices are in the form of special messages EVTS from the X server XSERV to the client applications CLAPP1 and CLAPP2 transmitted over the NETW network. There is also news REPL, with which the X server acknowledges certain calls to the client applications or error messages transmitted.

DE-A1-43 32 143 discloses a method for displaying operating states, in which the status data are supplied in two channels, but in one Computers are only partially prepared in two channels. In a graphics system there are symbols that are colored depending on the state to be displayed be interpreted. However, the process described there encounters serious safety concerns, because the graphics system itself is just there. It is for example, not recognizable if a picture symbol in the graphics system falsifies loaded from memory and integrated into the overall picture.

task

It is therefore an object of the invention to provide a method for reliably displaying the status to indicate a signaling system on a screen. The procedure should have a high level of security with the least possible hardware and software expenditure Detect errors and falsifications.

Summary of the invention

This object is achieved by a method with the features according to claim 1. According to the invention create two image building modules using supplied State data composed of pixels independently of one another Symbols (SYMB 1, SYMB2). At least one image building module transmits the created symbols on a display module. The color values of the pixels for the Symbols are explicitly given. The display module then sets the transmitted image symbols to a displayable directly on the screen State picture together.

According to the method according to the invention, the symbols are also independent generated from each other in two different logical channels. The display module, which is only available from the image building modules the full pixel information (i.e., the color values) for the image symbols. The functionality of the display module is therefore limited to the assembly the transmitted picture symbols to a complete picture. Because of this reduced Functionality is also less likely to falsify errors in the ad remain undetected.

In an advantageous embodiment of the invention, each image building module engages when creating the image symbols on their own protected memory area to. In this memory area, templates for picture symbols are pixel by pixel saved. It is thus prevented that the image building modules together on access a faulty memory and falsified image symbols from it in parallel create.

In another advantageous exemplary embodiment, the image building modules are concerned around X clients and in the display module around an X server. Since the required security with only one X server instead of otherwise with two-channel Systems usual two X servers is required in the implementation only one X server license.

However, the invention is in no way based on the use of an X-Windows system limited. When using certain client-server operating systems such as Windows NT®, the image building modules can be implemented as client processes. The display module is then a protected subsystem of the operating system. The Picture symbols are then transmitted via interfaces for local or remote Procedure calls.

Fig. 1: Prinzipskizze zur Erläuterung eines X-Windows-Systems;

Fig. 2: Schematische Darstellung eines erfindungsgemäßen Bedienplatzrechners;

Fig. 3: Flußdiagramm zur Erläuterung des erfindungsgemäßen Verfahrens;

Fig. 4: Visuelle Darstellung von besetzten und unbesetzten Gleisabschnitten.

The invention is explained in detail below using the exemplary embodiments and the drawings. Show it:

Fig. 1: schematic diagram to explain an X-Windows system;

2: Schematic representation of an operator station computer according to the invention;

3: Flow chart to explain the method according to the invention;

Fig. 4: Visual representation of occupied and unoccupied track sections.

Fig. 2 shows schematically an operator station computer, which has two independent input channels Status data i1 and i2 are supplied. The status data come from for example from a signal box computer that is secure in terms of signal technology. The status data are identical in content and are only duplicated for security reasons transmitted in different formats (e.g. normal and inverted). Conceivable is, however, also that the status data is simply fed to the operator station computer and be distributed internally to both input channels.

Each input channel is connected to an image building module BAM1 or BAM2. The image construction modules BAM1 and BAM2 create from the supplied status data i1 and i2 icons for the parts affected by the status data the signaling system. You access project data that may a. Information contains which icon for which type of track or field element is to be used. More complex field elements, e.g. B. main signals may need to be off several picture symbols can be put together. The rules, what icons to use and how to arrange them are usually determined by the system operator fixed. They are preferably in both image building modules BAM1 and BAM2 filed independently of each other.

Gleisabschnitt G3 besetzt" zugeführt bekommen. Mit diesem Zustandsdatum meldet der Stellwerksrechner die Besetzung des Gleisabschnitts G3 durch einen Zug.The creation of the image symbols is to be explained in more detail using the example shown in FIGS. 3 and 4. It is assumed that in a step 31 the image building modules BAM1 and BAM2 send the message as the status data from a safe signal box computer

Track section G3 occupied "is fed in. With this status data, the signal box computer reports the occupation of track section G3 by a train.

The image building module BAM1 now determines which image symbol in a step 32 is to be used for the representation of a track section. It accesses project data to which it can be seen in this example that the track section in question is represented by a horizontal bar. From a file in which The image construction module calls all possible image symbols as templates BAM1 the template for the corresponding icon. Subsequently arranges the image building module BAM1 in a step 33 of the template a front and a background color too. Which colors are to be selected depends on according to the rules already mentioned above. By assigning the color values the finished image symbol is created for the individual pixels of the template.

In the following step 34, the image construction module BAM1 transmits according to the invention the full icon of an AZM display module. Complete means in this Context that the color values are explicitly specified for all pixels. For example, if the symbol is 13 by 17 pixels and the color depth is 8 Is bit, then at least (13x17x8) / 8 = 221 bytes are transmitted. In addition to the color values of the pixels, at least are transmitted at which point of the image to be displayed the symbol should appear. The coordinates for this are taken by the image building module BAM1 Project data.

The display module receives the picture symbol and overwrites the displayed picture with the picture symbol. Fig. 4 shows an example of four track sections G1 ... G4. The track section G3 is initially represented by an icon in the state image displayed on the screen, the color of which represents the state Free "symbolizes. After the busy message, the display module AZM overwrites this picture symbol with the picture symbol newly transmitted by the picture building module BAM1. In this case, the new picture symbol has the same geometry, but a different coloring than the originally existing picture symbol. The changed color makes it easier for the operating personnel the state busy "is displayed.

As already mentioned above, the display module only has the task of to overwrite the existing status picture with a picture symbol which of an image building module has been generated. If e.g. B. after a change of a section of the state to be displayed should be completely rebuilt, so it will be completely from the transmitted image symbols from the display module composed.

Operator-specific symbols ( Pushbuttons ") are also treated as picture symbols. They are therefore also created by the picture building modules in the manner described using templates and transmitted to the display module.

The other image building module BAM2 just carries out for the image building module BAM1 explained steps in the same way, but independently. With perfect The function of the image construction modules BAM1 and BAM2 must be independent created image symbols match pixel by pixel in their color values. To check this, you can create the independently Icons are compared. It can also be provided that image symbols are read back from the screen and with those from the image construction module BAM2 created image symbols can be compared. Such checks are but not the subject of the invention, which is why at this point on the beginning cited publications. Which of the two image building modules BAM1 or BAM2 the AZM display module in specific individual cases transmitted is not important here. 2 are therefore the connections of the the two image construction modules BAM1 and BAM2 are shown identically to the display module AZM.

In an advantageous embodiment according to claim 2, the project data and also the templates for the picture symbols in two independent protected storage areas filed, to which only one of the two image building modules Has access. 2, these memory areas are identified by the reference symbols SPC1 and Labeled SPC2. The protected memory areas can be, for example are areas of main memory that are operated by an operating system is managed, which ensures a strict separation of computer resources (e.g. Windows NT®). In this main memory, as shown in FIG. 2, too a protected memory area SPAZM can be assigned to the display module AZM.

If there is corruption in one of the memory areas SPC1 or SPC2 of stored information, it is ensured in this way that distinguish between image symbols created in the image construction modules BAM1 and BAM2. At A comparison of the image symbols reliably recognizes the falsification.

The method according to the invention has been successfully implemented on an X-Windows system. In this case, the image construction modules BAM1 and BAM2 are X client applications, while the display module is an X server. The transmission of the image symbols from the image construction modules to the X server takes place in accordance with the X protocol. According to the invention, the X server has one - in comparison to the usual one Use - very limited functionality. Usually the X server only the most necessary information to create graphical representations transmitted in order to minimize the data volume in the connecting network. The X server determines from this information (e.g. coordinates of a polyline) independently the color values of the pixels to be displayed.

In contrast, according to the invention, the image to be displayed is complete, even if in individual parts (= picture symbols), the X servers of the X client applications transmitted. As a result, the scope of data transmission between the X client applications on the one hand and the X server on the other hand are not insignificant is. If the X client applications are located spatially away from the X server is consequently for a sufficient transmission capacity on the connecting Network. However, the X client applications are preferably located together with the X server on one computer, making its powerful internal bus system can be used for the transmission.

The X server is connected to one or more graphics cards GK that are connected to one corresponding number of screens BS are connected. The overall system can thus be built with standard hardware and does not require any special developing operating system.

The invention is of course not restricted to the use of an X-Windows system. Because of the low functionality that the display module requires certain client-server operating systems such as Windows NT® in question. The image building modules are then as normal Realize client applications. The role of the display module takes over protected subsystem of the operating system. The transmission of picture symbols in this case takes place via interfaces for local procedure calls. If the image building modules and the display module is spatially distributed over a network, so the transmission takes place accordingly via interfaces for remote procedure calls.

Claims (7)

Process for the safe display of the status of a signaling system on a screen (BS) with the help of a workstation computer (BPR), comprising the following steps: a) at least two image construction modules (BAM1, BAM2) create image symbols composed of pixels independently of one another using supplied status data (i1, i2), b) at least one image construction module transmits the image symbols created by it to exactly one display module (AZM), the color value for each individual pixel of the image symbols being explicitly stated, c) the display module assembles the transmitted image symbols into a state image that can be displayed directly on the screen. Method according to Claim 1, in which each image construction module (BAM1, BAM2) when creating the image symbols on their own protected memory area (SPC1, SPC2) accesses in which symbols for image symbols are stored. Method according to one of the preceding claims, in which the image construction modules X client applications are, the display module is an X server and the Image symbols are transmitted in accordance with the X protocol. Method according to one of claims 1 or 2, wherein the image building modules Protected client processes of a client-server operating system are the display module is a protected subsystem of the client-server operating system and the transmission of picture symbols either via a message interface for local procedure calls or via a message interface for remote Procedure calls are made. Operator station computer (BPR) for safe display of the status of a signaling system on a screen (BS) with: a) at least two image construction modules (BAM1, BAM2), which independently create image symbols composed of pixels using supplied status data (i1, i2) and explicitly specify the color values of the individual pixels, and one b) display module which receives image symbols from at least one image construction module and assembles the transmitted image symbols into a state image which can be displayed directly on the screen. Operator console according to claim 5, wherein the image building modules X client applications are, the display module is an X server and the transmission of picture symbols according to the X protocol. Operator station computer according to claim 5, in which the image building modules are protected Client processes of a client-server operating system are the display module is protected subsystem of the client-server operating system and the transmission icons either through a local message interface Procedure calls or through a message interface for remote procedure calls he follows.

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