DE19950798A1 - Module for life insertion into redundant bus in module frame - Google Patents

Abstract

The module (2) is inserted in the module frame (1) and comprises two terminals (3,6) for corresponding data buses (4,7) and two noise suppression devices (5,8). The second data bus (7) forms redundancy for the first bus (4).

Description

The present invention relates to an assembly for insertion gene in a module frame, the module frame for Includes multiple assemblies, as it is in the preamble of the appended claim 1.

The present invention further relates to an assembly pen frame for holding assemblies, as it is in the preamble of the appended claim 3.

Modern electronic systems are based on technology development ever smaller. So z. B. whole one units of modern switching centers as system on Chip realized, d. H. they are un on a single chip brought. This development enables Assemblies that due to a high required failure i security must be redundant, together in one Module frames are housed.

With redundant systems one differentiates u. a. between the so-called 1 + 1 redundancy and 1: n redundancy. With the 1 + 1 Redun danz are all modules, such as. B. processor assembly, zen central RAM and data bus are available twice. Sy systems that are built with 1 + 1 redundancy operate simultaneously and take on the same tasks; if one unit fails, the remaining one works Unit continues without downtime.

With 1: n redundancy, surplus modules are available Reserve available, but these modules do not have to be duplicated to be available. This is the case with 1: n redundancy in a multi processor system z. B. one processor more available than Operation of the system at full capacity is necessary.  

The 1: n redundancy has the advantage that the same modules, that exist more than once cannot be built up twice need to create a reserve. The disadvantage with this The method is that in the event of a component failure, such as. B. in a processor, the processing power of the system sinks.

Advantageously, for. B. in multiprocessor systems that Are built redundantly due to the reliability, both types of redundancy are used. So are the central ar main memory and the data bus with 1 + 1 redundancy and the processors are built with 1: n redundancy.

There are then two in such multiprocessor systems Bus connections on one module; a bus connection for the first data bus and a bus connection for the second data bus, which forms the redundancy. These data buses transmit the data from and to a central working memory, whose Content Same due to the redundant structure of the system is.

If a construction falls during the operation of the entire system group or a data bus, the system remains at Vor in the presence of appropriate redundancy. In the event of a defective assembly, it is simply removed from the Module frame pulled out and replaced. Moreover system expansions can be carried out simply by replaced an assembly or added a new assembly is added.

Is in one module during the operation of the system frame removed or inserted an assembly, e.g. B. due failure, malfunctions can occur. These disorders arise z. B. by different voltage levels on the Module opposite the data bus or by loaded or discharged capacitors. All modules that are used for data transfer use the same redundant data bus as the  Assembly that should be inserted or removed can be affected by the interference.

In the prior art, systems which use a 1 + 1 redun danz, the defective unit configured away. The sy stem then only runs on during the repair time nich, d. H. that there was no redundancy during the repair period is there.

For systems that each have two data bus connections the individual modules, data traffic takes place between the modules via so-called bus concentrators, which ent neither assigned to the data bus or the redundant data bus are. The bus concentrators transmit the data traffic from several modules via the data bus and vice versa. Defects Modules can be configured away from the bus concentrator ren, d. H. switch off from bus concentrator, and then replace . Bus concentrators are separate assemblies.

Since bus concentrators handle data traffic from several modules Transmitted over a data bus, this method has the after part that in the event of a failure of a concentrator multiple construction groups are affected. In this case, during the repa There is also no redundancy at the end of the

The object of the present invention is thus a construction group for insertion in a module frame according to the upper Concept of the appended claim 1 or an assembly frame according to the preamble of appended claim 3 be to sit back, ensuring that assemblies inside half of a module frame with a redundant data bus not removed by removing or inserting an assembly be disturbed.

This task is performed by an assembly with the characteristics of attached claim 1 or by an assembly frame solved with the features of appended claim 3.  

So that the data bus of the module frame and thus the other modules can remain in operation undisturbed Interference suppression device in the so-called life insertion technology used.

Such interference suppression devices are used as building blocks by eini gene manufacturers, such as B. Texas Instruments, and have the task of interference that occurs when inserting or removing avoid an assembly.

The suppressor can either be on the module be housed, or in the assembly frame on the data bus.

Preferred embodiments of the invention are in the Unteran sayings 2, 4 and 5 reproduced.

According to the present invention, the interference suppressor used in life insertion technology in systems in those on a module have two connections for two data buses are present, with a data bus providing redundancy for the whose data bus represents.

The interference suppression device on the data bus in the modules frame realized, so is advantageous for each plug space where an assembly can be inserted, one Interference suppressor on the first data bus and an interference suppressor device available on the redundant second data bus.

The present invention is hereinafter based on before preferred embodiments with reference to the accompanying Drawings explained in more detail, in which:

Fig. 1 is an illustration of the assembly according to the invention in a module frame, and

Fig. 2 is an illustration of the assembly frame according to the invention with an assembly

Fig. 1 shows the assembly 2 according to the invention in a construction group frame 1 ; the assembly 2 is not inserted in the figure. The connection between module 2 and the first and the redundant second data bus 4 , 7 is made via connections 3 and 6 . These connections 3 and 6 are designed as multi-pole plugs and establish the connection to the data buses 4 and 7 via the connections or plugs 9 and 10 , which are located in the module frame 1 on the data buses 4 and 7 .

The first and second interference suppression device 5 and 8 are preferably located on the module 2 between the plugs 3 and 6 and the electronic circuits that perform the functions of the module 2 radio.

Fig. 2 shows the assembly frame 1 according to the invention in connection with an assembly 2 and essentially includes the same functional blocks as Fig. 1; the assembly is also not inserted in this figure.

The difference to the embodiment in Fig. 1 is that the first and the second interference suppression device 11 and 12 between the terminals 9 and 10 and the data buses 4 and 7 are.

Basically, the embodiment that was presented in FIG. 1 is to be preferred because a defective interference suppression device can be repaired in the case by simply replacing the relevant assembly.

Claims (5)

1. Module ( 2 ) for insertion into a module frame ( 1 ), the module frame ( 1 ) for receiving several building groups ( 2 ), with
a first connection ( 3 ) for a first data bus ( 4 ), where in the first data bus ( 4 ) for data transmission between groups ( 2 ) in the module frame ( 1 ) and
a first interference suppression device ( 5 ) for avoiding interference on the first data bus ( 4 ) when removing and inserting the module ( 2 ) into the module frame ( 1 ),
marked by
a second connection ( 6 ) for a second data bus ( 7 ), the second data bus ( 7 ) being used for data transmission between modules ( 2 ) in the module frame ( 1 ) and
a second interference suppression device ( 8 ) for avoiding interference on the second data bus ( 7 ) when removing and inserting the module ( 2 ) into the module frame ( 1 ). 2. Module ( 2 ) according to claim 1, characterized in that the second data bus ( 7 ) forms a redundancy for the first tenbus ( 4 ). 3. Module frame ( 1 ) for receiving modules ( 2 ) with
a first data bus ( 4 ) for data transmission between the individual modules ( 2 ) and
a first interference suppression device ( 11 ) for avoiding interference on the first data bus ( 4 ) when removing and inserting an assembly ( 2 ) into the assembly frame ( 1 ),
marked by
a second data bus ( 7 ) for data transmission between the individual modules ( 2 ) and
a second interference suppression device ( 12 ) for avoiding interference on the second data bus ( 7 ) when removing and inserting an assembly ( 2 ) into the assembly frame ( 1 ). 4. Module frame ( 1 ) according to claim 3, characterized in that the second data bus ( 7 ) forms redundancy for the first Da tenbus ( 4 ). 5. assembly frame ( 1 ) according to claim 3 or 4, characterized in that for each assembly ( 2 ) which the assembly frame ( 1 ) takes on, a first and a second interference suppression device ( 11 , 12 ) is present.