NO180097B - Method and switching device for gathering self-monitoring information in telecommunications devices - Google Patents

Abstract

Method and circuit arrangement for collecting self-monitoring information in information transmission systems containing plug-in components. To enable identification data of the individual components to be updated in simple fashion and to be polled by a signal collector, the identification data is read into EEPROMs by means of a setup computer and polled by means of the signal collector using address selection and clock control. The method can be employed to particularly advantageous effect in conjunction with devices for recording error messages in information transmission systems. <IMAGE>

Description

The invention relates to a method for the collection of self-monitoring information in transmission devices in electrical telecommunications technology and a connection device for carrying out such a method as stated in the introduction of patent claim 1.

Such a method and such a coupling device are already known from DE-OS 35 06 945.

The known method makes it possible to collect self-monitoring information from several teletechnical devices or telecommunications devices by means of a signal collection device and transfer them to a central and process them in a central processing device. Such self-monitoring information can e.g. be pilot alarms in the case of analogue and code error alarms in the case of digital telecommunications. In addition, the telegrams transmitted in this connection may contain identification data, namely device identifiers. If an error is detected, the data is read out again.

Furthermore, DE-OS 33 32 3 04 discloses a switching device with an EEPROM which is loaded by means of a setting computer. This EEPROM is used to store operational values such as the bitrate of a transmitter or receiver, the address of a remote-controlled station or the like.

The purpose of the invention is to provide a method as stated in the introduction of patent claim 1 or connecting device for carrying out such a method which respectively provides for storing and polling identification data for the individual components so that the identification data for small storage dimensions can easily be updated and polled at the signal collector.

According to the invention, the stated purpose is achieved in the manner stated in the characteristics of the independent claims. An EEPROM (Electrically Erasable Programmable Read Only Memory) is a read storage whose storage space is erased electrically and can be written again with new information. In the event of a power failure, the information is not lost. The polling of the identification data preferably takes place continuously or in cyclic order.

The identification data can in particular be a company case number, a short name for a device or case number, the document's issue stock, manufacturer's designation, a production number and/or a catalog number.

The signal collector can also belong to a signal collector device for collecting error messages or be part of a separate device for collecting identification data.

These measures have the advantage that in telecommunications devices with a number of pluggable components, identification data can be collected in a particularly economical way and which provides more detailed information about the identity of the monitored components.

In the further development according to claim 2, the identification data must only be transferred completely from the signal collector to the central monitoring device when the transmission device is started. Thereafter, the central monitoring device is only notified of changes to the identification data, so that there is a reduction in the data to be transferred.

An advantageous coupling device for carrying out the method according to claim 1 appears from claims 3 and 4.

In the embodiment according to claim 3, the storage components can each have a separate input for incoming data and a separate output for outgoing data or a common data input and output. In both cases, the connection device gets a bus line that is inexpensive and requires only a few connections. Advantageously, only a central clock is needed in this connection.

In the embodiment according to claim 5, the storage components are preferably provided with addresses, which can be set or when inserting the component via a plug connection reaches a storage component from an addressing device located outside the component, so that the addressing is related to the connection point.

In an embodiment of the device according to claim 6, a special call line leads to each storage component so that regardless of the number of components polled by the signal collector, the component only needs a single socket for addressing.

The measures in accordance with claim 7 have the advantage that no devices are needed in monitored components themselves for calculating parity bits or fuse fields for error detection or correction, respectively. The further development according to claim 8 advantageously ensures that the identification data are each transmitted together with the error messages from the same component.

The further development according to requirements 9 and 10 ensures that each component, which as such does not need a power supply, takes part in the registration of identification data without having to be connected to a power supply for this purpose.

In the embodiment according to claim 11, the components are called by the signal collector over an address bus, so that no address information needs to be transmitted over the data line.

The invention shall be explained in more detail in connection with the exemplary embodiments shown in the drawing.

Fig. 1 shows a device for collecting monitoring information,

fig. 2 shows an insert with plug units equipped with bearing components,

fig. 3 shows a device for collecting identification data with address-controlled calling in the case of serial address information,

fig. 4 shows a section of the device in fig. 3 with additional single features,

fig. 5 shows a pulse diagram for the device in fig. 4,

fig. 6 shows a section of a device for collecting identification data with addressing by calling lines,

fig. 7 shows a section of a device with common collection of identification data and error messages,

fig. 8 shows for the device in fig. 7 a timing diagram for reading error messages,

fig. 9 shows for the device in fig. 7 a timing diagram for reading error messages and identification data,

fig. 10 shows a storage component whose supply voltage is derived from the clock pulses,

fig. 11 shows a bearing component whose supply voltage input is connected to its call line.

Fig. 1 shows a signal recording device with a data network of tree structure. The signal collector is arranged in several grid planes. The signal collector 13 of the third network plane which includes an operating location is connected to the data processing device 14. The signal collector 12 of the second network plane which includes a rack series of the type 7R is connected to the signal collector 13.

To the signal collector 12 in the second grid plane, several signal collectors 11 are respectively connected to a rack.

Several signal collectors 10 are connected to each signal collector 11 in the first network plan which respectively comprises several inserts 2 of the type 7R. The signal collectors 10 are each arranged in one of the plug units 3 and together with further plug units 3 are included in a pluggable insert 2 of the type Bw7R.

By means of the one in fig. 1 shown signal collection device, the data processing facility 14 is supplied with identification data for further processing. With the help of a service terminal 15 connected to one of the signal collectors 11 in the first network plan, identification data can be read from the location.

All pluggable units, i.e. plug units 3 and inserts 2 are each provided with a bearing component. The storage components are each formed by an EEPROM and each have stored identification data for the relevant component.

Fig. 2 shows such an insert equipped with stock components. An insert 2 contains several plug units 3 each with a storage component 30 belonging to different telecommunication systems A and B, one in a further plug component including signal collector 10 with a storage component 100 and a storage component 20 for the insert 2 itself.

As stock components 20, 100 resp. 3 0 serves in particular an EEPROM HCMOS technology with a serial data input and a serial data output, so that a low space requirement, a small loss effect, few interface wires and the possibility of reprogramming are obtained. The EEPROM has e.g. a storage capacity of 256 bytes and is housed in an 8-pin capsule. Data input and output can be combined for two-wire operation.

Such a stock component is e.g. EEPROM MCM 2814 from the company Motorola. The storage component has a first and a second input for a component light ing, a mode input for setting to two-wire or four-wire bus operation, a connection for earth, a connection for a supply voltage, a connection for a programming voltage, a clock input and a serial data input and output .

At the production site, in the test area or at the point of use, the stock component is provided with the identification data by means of a programming device or the service terminal. The loading of the EEPROMs by means of setting computers is known per se and is therefore not described in more detail.

The inputs for component deletion serve appropriately to provide the storage component with an address. In this connection, the two inputs arranged for component deletion are each led to a supply voltage across a pull-up resistor and, depending on the address, connected to earth or not. In this connection, four addresses are available as ground-supply voltage combinations. In this case, the individual stock components or plug-in devices called by having their address supplied serially over the data line.

For setting the address, the inputs to the component delete are preferably correspondingly connected to ground on the rear wall of the relevant component. On the other hand, one can connect one of the inputs for component deletion to ground and the other to a call line, on which ground is applied in the event of a call of the relevant component.

Fig. 3 shows a connection device with serial addressing of the storage component over data lines 51...5n. Each plug component 3 can be set to one of four addresses. With each data line, a maximum of four storage components or plug devices are addressed. All plug units 3 are fed with a clock via the common clock line 6 from the signal collector 10. In addition, the plug unit 3 is connected in groups to the signal collectors 10 via data lines 51...5n. The data line 51 leads to the first group Gl of plug units 3, to the nth group Gn the data line 5n.

In this way, with the help of a signal collector, 10 n times 4 pluggable components can be polled.

Fig. 4 further shows details of the coupling device in fig.

3. This coupling device is suitable for inserts with a maximum of sixteen plug units or plug units 3. The clock is supplied to all plug units over the common clock line 6. Four and four plug units together have one of the four data lines 51,52,53 or 54.

The selection of the desired storage components takes place by the signal collector 11 giving the address of the storage component that is called on the data line leading to the group of storage components to which the relevant storage component belongs.

At the one in fig. 4, of several inserts connected to the signal collectors 11, only one insert 2 is shown, and of the plug components included in this insert 2, apart from the monitoring plug unit which contains the signal collectors 10, only one of the plug components 3. The signal collector 10 contains a microprocessor 100 which via the bus 7 receives error messages from the plug units 3 in the insert 2. Each plug unit 3 comprises a bearing component 30.

The storage component 30 is set to a predetermined own address by means of the device 4. This own address is determined using the device 4 for address setting on the rear wall of the plug unit, i.e. individually for each plugging or by a corresponding user connection, i.e. individually for plug position. The device 4 is connected to the inputs A0 and Al on the comparator 35. These connections A0 and Al are each led to a supply voltage across a pull-up resistor 41 or 42 and can optionally be connected to earth by means of the device 4.

The storage component 30 comprises a comparator 35 which, together with the start-stop logic 34 and the control logic 33 via the clock line connected to the clock input 302, is controlled by the microprocessor 100. The comparator 35 compares the address received over the data line 54 with the address set in the device 4. If the two addresses match, then the comparator 3 5 emits an agreement signal to the control logic 33. The actual EEPROM 31 is equipped with the X-decoder 32 and the Y-decoder 36. The X-decoder 3 2 is connected in front of the control logic

33. The Y-decoder 36 is connected to the data register 37 which, by means of the control logic 3 3, can be clocked over the internal clock line 6a and is connected to an input to the data input and output 3 01 and whose output is routed via the driver 38 to the data input and the output 301.

The data line 54 which is led to the data input and output 3 01 on the plug unit 3 also leads to three further plug units not shown in the figure. The further data lines 51-53 lead to four further plug units, also not shown in the figure, so that the insert 2 can also comprise a maximum of sixteen further plug units with storage components in addition to the monitoring plug unit which contains the signal collectors 10.

The reading of the identification data is arranged by the signal collector 10 which for this purpose sends a polling telegram to the data line 54. The first data byte sent by the signal collector 10 contains the two address bits. These bits are compared with the eigenaddress by the comparator 35 integrated in the storage component 30. If the two addresses match, the storage component 30 sends the named plug unit 3 an acknowledgment signal and then transfers all its identification data to the signal collector 10. The signal collector 10 acknowledges each data byte received. If the signal collector 10 does not receive the acknowledgment signal, the connection is terminated.

After connecting the insert 2 in the coupling device in fig. 3,4 and 5, the signal collector 10 polls all plug units 3 with regard to their identification data and stores this data in its storage. In the signal collector 10, the data is sorted and, if necessary, assigned to the individual systems of the insert 2. In this form, the identification data can be read out via a signal collector system such as the one in fig. 1 shown known device, from the data processing facility DVA or polled at a service terminal 15. The identification data of the plug units 3 is polled by a so-called cyclic polling method, resp. read out. Only in the event of a change, especially in the case of a replacement of plug units, is the new data passed on to the data processing facility DVA.

A preferred response telegram with which the identification data is transferred from the plug unit 3 to the signal collector 10 is shown in fig. 5. The black telegram begins with a response character STI to which a part with fixed bit order BF, the address bits A0 and Al and a logical "1" join. The black telegram begins with an acknowledgment signal AS for the storage component formed by a logical "0".

Then follow the characters Z1,Z2,...Z (n-l),Zn which each contain identification data, the security field SF which consists of one or two bytes and the stop character ST2. The acknowledgment signals AM that the signal collector emits after each of the characters Zl...Z(n-l) have logic level 0 when correctly received. The acknowledgment signal AM that joins the fuse field SF has logic level 1.

Fig. 6 shows a connection device which calls the plug units 3 included in the insert 2 by means of calling lines 81...8n. The signal collector 10 included in a monitoring unit activates the individual inputs via call lines 81...8n. In this connection, only one of the call lines 81...8n is always set to logic level "0". This calling line thus releases the named EEPROM 30 in such a way that the identification data stored therein is read out. The identification data is read out in the same way as with the connection device in fig. 4, i.e. by means of a pulse telegram according to fig. 5.

In the case of devices with several systems or plug units per effort, the error messages and identification data are appropriately read out together over a serial bus. A connecting device which enables such a joint reading is shown in fig. 7.

Fig. 7 shows a connection device in which a number of plug units and the signal collector of an insert are interconnected via bus lines. Of these plug units, only one plug unit 3 is shown.

The plug unit 3 comprises the address comparator 41 which is connected. via the address bus 9 as well as with the signal collector 10 and also to the device 4 for the address setting of the plug unit 3. The setting of the own address is as with the switching devices in fig. 4 and 5 made according to which four instead of two address bits are determined. The address comparator 41 compares the eigenaddresses of the plug unit with the addresses transmitted cyclically to the address bus 9 by the signal collector 10. If address equality is determined, the address comparator 41 emits a delete signal to the connection 3 03 to delete the storage component 3 0 and to the shift input S and the load input L of the shift register 39.

The storage component 30 is connected with its data output D1 to the input 3D of the shift register 39 and with its data input D2 to the data bus 5a coming from the signal collector 10. The clock input T on the storage component 30 is connected to the common clock line 6 for all plug units of the insert.

The shift register 3 9 as e.g. is of type 74 HC 165 is connected to the input 3D to the data output Dl on the storage component. The additional inputs 2D receive error messages as parallel information from the error message generator.

When calling the signal collector 10, the error messages are held in the register and the shift register gives a telegram via the driver 38a to the data line 5b going to the signal collector 10, the error messages from the error message generator F being followed by the identification data from the storage component 30, each of which has a serial form.

The one in fig. The connection device shown in 7 is suitably designed as an integrated circuit.

If only error messages are to be read out alone, the signal collector adds according to fig. 8 as many clock pulses on the data line 6 as there are inputs on the shift register. The data line 5a going to the data input D2 on the EPROM has no signal. The driver 3 8a emits error messages to the data line 5b. The reading of error messages and identification data is shown in fig. 9. The signal collector emits a longer sequence of clock pulses on clock line 6b. In addition, the data input D2 on the EEPROM 30 receives from the signal collector a poll telegram consisting of the read code LC and the address AD. This causes the EEPROM to emit a sequence of characters consisting of two filler bits FB, an address AD specified in the protocol but not used, characters Zl...Zn containing the identification data and the security field SF. The parity bits placed at the end of the character Zl...Zn are denoted by

P.

The driver 3 8a in fig. 7 then emits the error messages FM and then finally the character sequence mentioned from the EEPROM.

Fig. 10 shows a storage component 30 whose supply voltage VDD is derived from the clock pulses arriving on clock line 6.

The common clock line 6 running from the signal collector to the storage components is led across the diode 61 polarized for the clock pulse in the conduction direction to the supply voltage input VDD on the storage component 30. Between the supply voltage input VDD and ground is the capacitor 62.

This switching device takes advantage of the fact that in the synchronous transmission methods according to which the switching devices 3,4,6 and 7 work, the beat is constantly on the common clock line 6. The clock signal consisting of a sequence of square pulses of a maximum of 100 kHz is smoothed by means of a capacitor whose capacitance lies in the range from 1-10 jiY. The A..leading of the clock pulses amounts to approx. 5 V. The smoothed voltage, which lies in the range 3-5 V, feeds the storage component during its active state, i.e. during reading or reading. The power consumption of the CMOS storage component 30 is approx. 2 mA.

The coupling device in fig. 10 is particularly advantageous in those cases where the connection device contains pluggable components for the collection of self-monitoring information and to which no supply voltage is supplied and in which a connection to a supply voltage is not immediately possible or associated with a relatively large cost.

Fig. 11 shows a storage component 30 whose supply voltage input VDD is immediately connected to the call line 8. If the storage component 30 is called via its call line 8, then there is voltage on this call line. This voltage is dimensioned so that it can feed the CMOS storage component 8.

In order to secure the identification data, the per se known methods with cyclic block security or generation of a test sum are used. In both methods, the programming device, which can be a service terminal or a PC, calculates the data protection in the test field while writing the identification data into the EEPROM.

Data security is served by a parity bit and a block security field which, together with the identification data, is stored in the EEPROM. Then the identification data starting with the address 0 is entered. This is followed by a security field which can comprise one or two bytes. For the identification data, the 7-bit code or The ASCII code according to DIN 66003 and a parity bit is added to each character.

The last two bytes in the EEPROM after the identification data belong to the security field. The content of this field is calculated from the identification data using a generator polynomial. This calculation is made by the programming device.

If the identification data consisting of the parity bit of a 7-bit code with the block test field is read out by the signal collector 10, then the same calculation that was also carried out when writing 1 test field is carried out again and the result compared with the content of the received block test field. If the result does not agree with the block test field, there is either a transmission error or a data error in the EEPROM. Transmission errors can be compensated by repeated reading of the data. Data errors in the EEPROM are reported to the data processing facility DVA.

Another advantageous type of data security consists in the identification data being added to the parity bits. The resulting 8-bit wide test sums are stored at the end of the data blocks in the EEPROM. The bits of the test sum that have a higher value and that no longer fit the word width are ignored. When the signal collector later reads out the identification data, the parity bit is checked, the data bits are added and the test sums calculated in the signal collector are compared with those received. If an error is detected, the data is read out again.

Claims (11)

1. Method for collecting self-monitoring information in transmission devices in electrical telecommunications technology, where the transmission devices contain pluggable modules, at least some of which comprise monitoring devices with transmitters for self-monitoring information, where the information transmitters are connected to signal collectors (10), where the the signal collectors (10) registered self-monitoring information contains identification data and at least part of the modules are provided with stores for the identification data, characterized in that the identification data can be entered with the help of a setting computer into EEPROMs (30) formed storage components in the component groups and which are provided with a serial data input and a serial data output, and with the help of the signal collector (10) can be polled address-selectively and clock-controlled . 2. Method according to claim 1, characterized in that the identification data is cyclically polled from the signal collector (10) and transferred to a central monitoring device (data processing device 14) after the first message at start-up only in case of changes to the identification data. 3. Connecting device for collecting self-monitoring information in transmission devices in electrical telecommunications technology, where the transmission devices contain pluggable modules, of which at least a part comprises monitoring devices with transmitters for self-monitoring information, where the information transmitters are connected to signal collectors (10), where those of the signal collectors (10) registered self-monitoring information contains identification data and at least part of the modules are provided with stores for the identification data, characterized in that the stores for ■ the identification data are storage components in the modules and formed by EEPROMs (30) provided with a serial data input and a serial data output and can be polled address-selective and clock-controlled by means of the signal collector (10), and that the storage components (30) with their clock inputs (SCL), with their serial data inputs (301) and with their serial data outputs (301) over bus lines (51...54) is connected with the assigned s spark collector (10). 4. Connection device for collecting self-monitoring information in transmission devices in electrical telecommunications technology, where the transmission devices contain pluggable modules, of which at least a part comprises monitoring devices with transmitters for self-monitoring information, where the information transmitters are connected to signal collectors (10), where those of the signal collectors (10 ) registered self-monitoring information contains identification data and at least part of the modules are provided with stores for the identification data, characterized in that the stores for the identification data are storage components in the modules and formed by EEPROMs equipped with a serial data input and a serial data output (30) and can is polled address-selectively and clock-controlled by means of the signal collector (10), and that the signal collector (10) comprises a device for cyclically address-selective and clock-controlled reading of the identification data and a device for the comparison of old and new in the received identification data and which, with cyclic polling after the first message at start-up, transmits identification data only when the identification data changes, to a central monitoring device (data processing device 14). 5. Connection device according to claim 3 or 4, characterized in that the storage component (30) is provided with connections (A0, A1) for component erasure and which can be connected component wise and plug position wise with activation potential (goods or ground), and that the EEPROMs (3 0) can be called using serially transferable addresses over the data lines (51...54). 6. Connection device according to claim 3 or 4, characterized in that the storage components (30) are each connected with a connection (A0) for component deletion to a separate call line (81...8n). 7. Connection device according to one of claims 3-5, characterized in that, in addition to identification data, storage locations for parity bits and/or block fuse fields are arranged in the storage component. 8. Coupling device according to one of claims 3-6, characterized in that a data output on the storage component (30) is led to an input on a shift register connected to a further input to an error signal generator (F). 9. Switching device according to one of claims 3-6, characterized in that the storage component (30) with its supply voltage input is connected via a diode to the clock line and provided with a filter capacitor. 10. Connection device according to claim 3, characterized in that the storage component (30) is connected to its supply voltage input to the call line. 11. Connecting device according to one of claims 3-5 or 6-10, characterized in that the plug units (3) each comprise a device (4) for address setting and an address comparator (35) connected to this device (4) and to a with the signal collector (10) connected to the address bus (9), and that a connection (CS) on the storage component (30) is connected to the address comparator (41).