FI100156B - Update of an electronic device's card unit - Google Patents

Description

100156

Electronic device card unit upgrade

The invention relates to a method according to the preamble of appended claim 1 and to an arrangement according to the preamble of appended claim 5 for updating an electronic device, in particular a card unit of a telecommunication device.

The communication device is known to comprise a plurality of card-10 units arranged in parallel in the card slots in the frame of the device. The card units have the necessary connectors for connecting external devices to the communication device and for connecting the communication device to the communication network.

15 When the recommendations of international standardization organizations change or define completely new features for devices or systems, or when for other reasons there is a need to add new features to an existing device, these changes must be brought to device 20 by updating its card units with equivalent features. In this context, an upgrade generally refers to changes related to the properties of a card unit, such as the introduction of new features to the card unit or the replacement of old features with new features. 25 la.

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Today, upgrades are typically handled by replacing the entire card unit with a new card unit equipped with new features. Such an exchange of the entire card unit is an unsatisfactory solution from an economic point of view, because the existing · cards. Units cannot be utilized efficiently, but can only be used occasionally after replacement, for example as maintenance spare parts or in teaching tasks.

An alternative way to perform the upgrade is to modify 35 existing card units so that its use can be continued on the same device after the modification. In practice, however, such modification of existing card units into a card unit with new features is very cumbersome, often even impossible.

5 Especially when new functions could not be foreseen at the manufacturing stage of the card unit, the replacement of the whole card unit is practically the only option.

It is an object of the present invention to provide an improvement over the above drawback by providing a new type of method for performing updates. This object is achieved by a method according to the invention, which is characterized by what is described in the characterizing part of the appended claim 1. The arrangement according to the invention is in turn characterized by what is described in the characterizing part of the appended claim 5.

The idea of the invention is to create new features for an additional card, which is connected to an existing card unit in the device and operatively connected to the card unit by allocating data corresponding to the new features to the free time slots of the time division bus formed for the card unit.

The solution according to the invention achieves flexible upgrade features without wasting existing hardware. A particularly important added benefit is that of a solution. 25 also flexibly allows the addition of features about which there is no information at the manufacturing stage of the card unit. The solution requires only suitable connections from the existing card unit and a time-shared bus with free capacity (va-30 shirt slots).

In the following, the invention and its preferred embodiments will be described in more detail with reference to the examples according to the accompanying drawings, in which Figure 1 illustrates at network level a possible device environment in which update 100156 is performed, Figure 2 schematically shows a card unit used in the environment of Figure 1 Fig. 3 illustrates an example of operations that can be performed on the base card, Fig. 4 illustrates updating the base card shown in Fig. 3 with an additional card, and Figs. 5a to 5c illustrate the frame structure of the bus on the base card 10 and its utilization in the update.

Figure 1 shows at the network level a possible environment in which the method according to the invention can be applied. The example case of the figure concerns a point-to-point connection established by two multi-15 plexiglass units DM1 and DM2. The connection can be, for example, a 32-channel PCM connection according to ITU-T (formerly CCITT) recommendation G.704 with a data rate of 2048 kbit / s. As is known per se, multiplexer units have subscriber interface cards 20 SUB1 ... SUBn to which subscriber devices, such as telephones SD1 and SD2, are connected. There may be several types of subscriber interface cards depending on the type of subscriber equipment used, and one or more subscriber equipment may be connected to one interface card. Figure 1 shows. In addition to the conventional subscriber interface card SUB1, there is a subscriber interface card SUBn which can provide both a high-quality audio connection and a data connection. In this exemplary case, an audio connection is established between the microphone MP and the speaker LD, and a data connection between the computers TE1 and TE2.

The subscriber interface cards are connected via their back connector to the internal bus of the multiplexer units, • which is marked with the reference mark IB. Since the transmission connection shown in Fig. 1 has been implemented using an ankle known per se and since it is not related to the actual inventive idea, it will not be described in more detail in this connection.

Figure 2 illustrates the (mechanical) structure 5 of the single subscriber interface card shown in Figure 1 in terms of upgrades, showing the card unit seen from the side.

The subscriber interface card may have one or more front connectors and one or more rear connectors. In this example, there are two front terminals, FC1 and FC2, and one of the rear 10 terminals, BC1. These connectors are preferably connectors according to a standard, e.g. Euroconnectors. According to the invention, the new features are formed on a separate additional card, and for each additional card there is space and two pin strips are formed on the interface card. Thus, one-to-one card unit may have space reserved for one or more additional cards. In the example case of the figure, there are two places. The pin strips formed for the first additional card are denoted by the reference numerals NR1 and NR2, and the pin strips formed for the second additional card are denoted by the reference numerals NR3 and NR4. The option card is connected with its own connectors to these connectors already ready with the card unit. Part of the pins of the front connector, in this case the pins of the second and third quarters of the connector (the quarters are separated by dashed lines),. 25 is connected directly to the corresponding pin strip (NR1 or NR3). This is illustrated by arrows C. The pins NR2 and NR4 of the pin strips are in turn connected to the subscriber interface card. In the figure, both additional cards are illustrated by a dashed line with the reference mark AB. The additional 30 card thus comes "on" the subscriber interface card, and the signals pass through said pins of the front terminals and the pins of the pin strip NR1 (or NR3) to the additional card and from there on to the pins of the pin strip NR2 (or NR4, respectively) to the subscriber interface card. Since the subscriber interface card 35 forms an existing card, on top of which 5,100,156 (or in parallel) an additional card is introduced if necessary, the subscriber interface card is hereinafter also referred to as the basic card.

Figure 3 schematically illustrates the functions on the base card. For example, a sub-interface card SUBn 5 is taken, through which both audio and data connections are established. Audio connections are marked with reference marks AUDIO1 and AUDI02 and data connections with reference marks DATA1 and DATA2. For the sake of clarity and simplicity, the pin strips on the base card have not been shown.

The pins of the audio connections are connected to a converter unit 31 comprising A / D and D / A converters, which in turn is connected via an internal bus BUSO formed on the base card to a cross-connect circuit XC which cross-connects the incoming and outgoing time slots. (The cross-15 switching circuit may be a programmable logic circuit, e.g. type XC 3090, manufactured by Xilinx, USA or AT&T, USA). The base card also has two digital signal processors, DSP1 and DSP2, each for its own audio interface. The cross-connect circuit outputs two 20 bidirectional serial, time-divided 2048 kbit / s buses, BUS1 and BUS2, and each signal processor is associated with its own bus; DSP1 to BUS1 and DSP2 to BUS2. Each signal processor has time slots defined in the bus frame structure in which they operate.

25 The cross-connect circuit is connected via the back connector BC1 of the base card to the internal bus IB of the multiplexer unit and from there on to the PCM connection between the multiplexer units. (Several basic cards are connected to the internal bus IB.) 30 An A / D conversion is performed in the unit 31 to the audio interface for e.g. an analog audio signal received from a microphone MP, after which the signal goes in digital format as a serial bus to the BUSO cross-connect circuit XC, from where it is further connected to a signal processor. Ic. Thus, only 6,100,156 digital samples pass through the cross-connect circuit, which can be e.g. 16 bits long. The signal processor performs coding on the samples, which may be e.g. SBADPCM coding according to ITU-T Recommendations G.725 and H.221, which transmits the encoded audio signal on a 64 kbit / s channel (i.e. 2048 kbit / s in one time slot of the basic channelization system) . In this case, a total of 6 samples of the analog signal are taken in unit 31 per frame of 125 με: η in the basic channelization system, so that 6 16-bit wide samples are received by the signal processor 10 during each frame of the 2048 kbit / s signal. These samples are compressed by the signal processor into one frame of the bus (BUS1 or BUS2) frame, which is switched back to the cross-connect circuit and from there on to the internal bus-15e IB of the multiplexer unit.

In the second transmission direction, the data of the desired time slots is received by the cross-connect circuit XC, which further switches the time slots to a signal processor which decodes the time slot data into six separate samples. These 20 samples are fed at regular intervals via a cross-connect circuit to the D / A converter of the unit 31, from which the analog signal is further switched on via the audio interface.

In this example, the data connections DATA1 and DATA2 of the subscriber interface card (base card) form a known V.28 / V.24 interface, which corresponds to a conventional RS232 serial interface. The subscriber interface card performs a level change on the outgoing and incoming signals in the conversion circuits 32, where the incoming V.28 compliant signals are converted to TTL level signals (± 5V) and the outgoing 30 TTL level signals are converted to V.28 compliant signals.

The conversion circuits are connected to a compression circuit 33 which performs compression for incoming signals in accordance with Recommendation V.110 and decompression for outgoing signals. V.110 is an ITU-T recommendation that describes how different terminal speeds are adapted to the frame structure of a 2048 kbit / s signal 7 100156 (i.e. bus BUS2). For example, the terminal speed of 9600 bit / s is adapted to the frame structure of a 2048 kbit / s signal according to the V.110 recommendation by enabling two bits from one time slot of the frame. The bits 5 are further forwarded via the cross-connect circuit XC. In this way, a two-way data connection is established between the computers 15 and 16 via the subscriber interface card SUB.

Figure 3 further shows a processor 34 which controls all functions of the base card (i.e., in this example, signal processors, circuit 33, and cross-connect). In practice, such a control processor may be, for example, type 68302, manufactured by Motorola, USA.

Since the V.28 / V.24 interface on the subscriber interface card supports bit rates between 0 ... 56 15 kbit / s, there may easily be a need to establish a new, faster data interface on the card, which is e.g. in accordance with Recommendation V.11. Such a need may arise, for example, from the fact that the user wants to switch from a conventional microcomputer to a workstation with a V.11 connection. (V.11 supports speeds of several hundred kilobits per second and also achieves significantly greater distances than the V.28 / V.24 interface.) The upgrade is accomplished by attaching the base card to the pin strips (only pin strip NR3 shown) of Figure 4. 25 an additional card AB with new features.

In the example of Figure 4, two V.11 terminals, DATA3 and DATA4, are introduced into the two middle quarters of the front terminal FC2. Thus, the previous connections, DATA1 and DATA2, remain unchanged as their signals travel from the first and fourth quarter pins of the front terminal 30 FC2 on the base card to the conversion units 32 and further to the circuit 33 (which remains on the base card under the option card). The pins of the two middle quarters of the front terminal FC2 * are connected directly to pin pin NR3 on the base card, the pins of which are further connected to the conversion circuits 42, 8 100156 on the option card where the incoming V.11-compatible signals are converted to TTL-level signals and the output TTL-level signals signals according to recommendation V. The conversion circuits are further connected to a matching circuit 43 which matches the continuous data stream from the direction of the terminal FC2 to the internal bus BUS2 of the base card in the correct time slots (i.e. collects data in chunks of suitable length and feeds them to the bus bus bus in The matching circuit can be implemented, for example, as an ASIC circuit, a RAM-based FPGA circuit or a PLD circuit, and in practice it can be implemented, for example, by the above-mentioned circuit type XC 3090.

Thus, according to the invention, it is essential that a time-divisional bus is formed on the base card, which can be configured so that each part utilizing the bus can be assigned the time slot in which it operates. The bus must also have free slots for the 20 new functions to be imported using the option card. Figure 5a illustrates the frame structure of buses BUS1 and BUS2. Consecutive frames have 32 time slots each (TS0 ... TS32) and each time slot has a total of eight bits (B1 ... B8). The frame structure of the buses otherwise corresponds to the frame structure according to recommendation 25 G.704, but the time slots TS0 and TS16 do not have to be used in this case as described in the recommendation (because it is an internal bus of the device). Fig. 5b shows the situation before the update (Fig. 3), in which e.g. the time slots TS0 and TS1 are allo-30 for the signal processors (one for each) and the time slot TS29 for the circuit 33. Fig. 5b shows the situation after the update; the free slots TS2 and TS3 and TS30 and TS31 are allocated for use by circuit 43.

According to the invention, it is advantageous that the bus of the control processor 35 is connected via a pin strip (NR2 or NR4) to the additional card 9 100156, because then the control processor of the base card can control the bus matching circuit 43 and thus flexibly-change the time slots allocated to the bus matching circuit. However, this is not necessary for the invention, because one or more time slots can be fixedly allocated to the bus matching circuit.

Synchronization information must also be imported from the base card to circuit 43 so that it can operate at the correct time slot. Connections NR2 and NR4 thus include a synchronization interface.

The cross-connect circuit on the base card is advantageous for the invention, in particular if one or more time slots are fixedly allocated to the bus matching circuit 43. In this case, the time slots can be "shuffled" in a further 15 cross-connect circuits if another card unit connected to the bus IB happens to have exactly the same time slot (s) in use.

An update has been presented above regarding the data interfaces of the base card. By connecting an additional card to pins NR1 20 and NR2, the properties of the audio connections can also be updated. With the aid of an additional card, for example, locally stored voice messages could be added to various public address systems, or various devices could also be connected to the audio connection, such as, for example, CD players or DAT tapes.

Although the invention has been described above with reference to the examples according to the accompanying drawings, it is clear that the invention is not limited thereto, but can be modified within the scope of the inventive idea set forth above and in the appended claims. The detailed implementation of the invention will therefore vary depending on the type of base card and the type of upgrade features in question. It also depends on the operating environment, for example, whether direct access to the option card is required from the external connection pins 35 of the card unit. In principle, the 10 100156 option card could also have its own external connection, so that the base card would not need pin strips NR2 and NR4.

Claims (8)

1. A method for updating an electronic device, in particular a card unit (SUB1, ... SUBn) in a telecommunication device, properties with new characteristics, characterized in that the new features are formed on a special supplementary card (AB), which is arranged next to the card unit and is functionally coupled to the card unit by allocating data corresponding to the new characteristics 10. Free time slots in a time-distributed bus (BUS2) formed for the card unit. Method according to claim 1, characterized in that the allocation is performed by means of a control processor (34) arranged on said card unit, the interface (NR2; NR4) between the card unit and the supplementary card comprising the control signals to be connected from the control processor to the supplementary card. Method according to claim 1, characterized in that a part of the external connector pin of the card unit is connected directly to pins (NR1; NR3) formed on the card unit of the supplementary card, said external connection pin having direct access to the supplementary card. . 4. A method according to claim 1, characterized in that space is reserved for several additional card (AB) in one and the same card unit. 5. Arrangements for updating an electronic device, in particular a card unit (SUB1, ... SUBn) in a telecommunication device, features with new features: «30, which arrangement comprises a time-distributed bus (BUS2) arranged on the card unit, characterized in in addition, it comprises - an additional board (AB) provided with said new features, 35. connecting means (NR1, NR2; NR3; NR4) in the 100156 additional card and on the card unit for electrically connecting the supplementary card to the card unit, and - on the supplementary card ( AB) provided bus matching means (43) for entering data corresponding to the new features of the time-distributed bus (BUS2) time slots and / or for reading said data from said time slots. 6. Arrangement according to claim 5, characterized in that some of the outer connector pins of the card unit are directly connected to pins (NR1; NR3) arranged on the card unit of the supplementary card, said external connection pins having direct access to the supplementary card. 7. Arrangement according to claim 5, characterized in that the connection means comprise an interface to the data and address buses in the control processor (34) arranged on the card unit. 8. Arrangement according to claim 5, characterized in that there is more than one additional card 20 (AB) for a card unit.