SE504161C2 - Device and method for digital communication systems - Google Patents

Abstract

The present invention relates to an arrangement and a method respectively for multiplexing/demultiplexing in a digital communication system using time division multiplex. The arrangement (US) comprises a switching arrangement with first switching means (USC) for switching of data and second switching means (TCU-1, TCU-2) for multiplexing and/or demultiplexing of data. One or more second switching means are connected to the first switching means over terminal connection links comprising a logical interface (USC-link) which comprises a number of time slots arranged in rows and columns. The arrangement further comprises means for providing resources on the interface of the first terminal connection link (USC-link) wherein resources for at least two different functionalities are reserved using reservation of resources based on columns in the interface and reservation based on time slots in the interface respectively.

Description

20 25 30 35 504 161 z indicates priority levels, identification, location in the buffer, etc.

Another table contains time indications of when messages from a particular voice source leave the buffer. Via a control unit that controls the contents of the sequence records from the buffer can be used on a priority basis for a priority algorithm, the tables and forwarding to the communication channels can be used. The items that have the in-first out principle and they are followed by the items that have lower priorities. the highest priority was transmitted in accordance with first Via the priority algorithm, data thus shifts out on a common communication channel.

WO 93/25031 relates to monitoring the filling rate of an elastic buffer memory in a synchronous digital communication system. The object of the invention shown therein was to enable the monitoring of the filling rate of the channels using less hardware than in known systems. This is essentially achieved by using a time division architecture for monitoring the fill rate so that the fill rate for two or more channels at the same hierarchical level is monitored on a time division basis in a monitoring unit common to the channels.

However, none of the cited documents shows a device for multiplexing digital communication system which efficiently uses the resources in the channels. In addition, it is difficult to connect transmission systems in such a way that the resources are used efficiently. In addition, only and / or demultiplexing in a transmission system for which the devices are specially designed can be connected thereto.

DISCLOSURE OF THE INVENTION It is an object of the present invention to provide an apparatus and a method respectively for providing optimal multiplexing and / or demultiplexing of channels in a digital also an object of the invention to communication systems. It is to provide a comprising device such as demultiplexing in a digital ie the time slots, multiplexing and / or selector device through which the resources can be used as efficiently as possible.

In addition, it is an object of the present invention to provide a demultiplexing in a digital selector device so that different frame devices for multiplexing and / or based transmission systems, in particular also other than 2 Mbit / s or 1.5 Mbit / s transmission systems, can be connected. in addition, especially while utilizing resources in a very efficient way.

It is also an object of the present invention to provide a selector device as a means for multiplexing and / or demultiplexing so that the channels or time slots can be used in an efficient manner. Another object of the invention is in particular to provide a selector device with a multiplexing / demultiplexing controlling means such that a comprising control of one or more transmission systems can be connected thereto during optimal use of the resources and even more particularly so that it is not designed only for one transmission system without various frame-based transmission systems can be connected thereto and thus allow a high degree of flexibility. limited number given to provide such (a) Another object of communication system as the invention comprises (s) selector device (s).

These as well as other objectives are achieved by a device and a method, respectively, in which the first selecting means for coupling data are connected to a number of second selecting means for multiplexing, first terminal and / or demultiplexing data via connection links.

The first consists of a first interface. An interface comprises a number of time slots which are the terminal connection links 10 arranged in rows and columns. Connections relating to the second selection means are provided by other terminal connection links which may comprise first and / or second interfaces. Means are provided for providing resources on the first interface of the first terminal connection link. Resources for first reservation of resources based on columns in the interface, for functionality are reserved (at least) one through a second functionality is the reservation of resources based on time slot reservation.

The objectives include multiplexing and / or demultiplexing control means which allow to be achieved also by a selector device which provides resources based on their functionality, ie the purpose for which they are first functionality reservation is made which intended, where for a based on columns in the time slots in the interface connecting the first the selection means are divided and for a second functionality, reservation is based on time slots.

An interface comprises a number of time slots per frame (and possibly a remainder of a number of bits) for a given number of bits per time slot in the interface. The interface is further divided into a given number of columns and rows of time slots plus possibly a number of extra time slots.

In general, there are three time slots, namely base time slots (BTS), control time slots (CTS) and data time slots (DTS).

The base time slots are mainly used for frame control purposes and different types of their positions within a frame are fixed. Control time slots are used for control data packets and data time slots are used for switching data. To first and transmit information over the terminal connection links, the concept of logical interfaces is used. These are subjected to mapping and allocation. Allocation refers to the definition of a time slot in one interface either as a data time slot or as a control time slot and mapping refers to the connection of a data time slot in one interface to a data time slot in another interface. The means for providing resources in the terminal connection links, i.e. for controlling multiplexing and / or demultiplexing, comprise mapping and allocation functionality which, as referred to above, provide (at least) a first and a second reservation dependent on the functionality of the requested ISSUITSQITIB.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be further described in the following in a non-limiting manner with reference to the accompanying figures in which: FIGURE 1 schematically illustrates terminal connection links connecting a number of second selector means to a first selector means, FIGURE 2 schematically illustrates connection of an arbitrary transmission system to a terminal connection unit, FIGURE 3 illustrates a frame 1 the second interface, FIGURE 4 illustrates a frame for the first interface, FIGURE 5 illustrates the location of allocation memories and mapping memories in the first and second select means, and FIGURE 6 illustrates allocation of control time slots.

DETAILED DESCRIPTION OF THE INVENTION The invention will now be described with reference to a particular embodiment in which the selector device comprises a selector US which in principle can be said to comprise two selector means.

The first select means USC in this embodiment is responsible for the data connection. The other selector means consists of a circuit with a number of terminal connection units TCU and provides for multiplexing and / or demultiplexing of data. The selector device comprises a selector-controlled packet network (USC PN) used for control, operation and maintenance functions and the circuit responsible for the data connection. Figure 1 illustrates how other selector means comprising two TCU-1, TCU-2 are cascaded. The first terminal connection unit TCU-1 is connected to the first selector means USC, which can be said to form a terminal connection unit selector core, through a first terminal connection link USC link.

The terminal connection units TCU-1, TCU-2 are connected by a second terminal connection link TCU link, here TCL-2. As can be seen from the figure, a number of terminal units are TU (where n indicates any) connection unit TCU-1, TCU-2. For the connection of terminal units relevant number as connected to each terminal TU to the terminal connection units TCU, other TCU links were also used, here TCL-1.

TCU-1, TCU-2 communicates with detail processors DP. Other internal terminal connection links TCL-3 are used for the communication with the detail processors terminal connection links designated Terminal connection units DP. These are in the detail processor connection. As only schematically indicated in the exemplary embodiment shown exclusively intended for Figure 1, a number of terminal connection units can be connected to the first selector means or the selector core in accordance with this exemplary embodiment. Within the invention, terminal units TU can also be connected directly to the selector core USC, but this is not shown in To the first terminal connection unit TCU-1 as USC, terminal connection units can be connected which in turn can be the figure. connects to the selector core a further number of connected via other terminal connection links TCL-2 to other terminal connection units in cascade as explained above. In addition (not shown in the figure), a number of terminal units TU can be connected to each terminal connection unit TCU via TCL-1 as referred to above. communicate over internal TCU links (TCL-3) with one or more Each terminal connection unit TCU can in turn detail processors DP. For example, if redundancy is applied, there is more than one "Device Processor" in a TCU. Transmission systems can be connected to the TU terminal units. As schematically illustrated in Figure 2, in alternative embodiments these can also be connected directly to The connection of transmission systems will be described further below. the terminal connection units.

A terminal unit may also comprise a detail processor DP (not shown).

Each terminal connection link TCU, USC link consists of an interface or a logical interface. Through them, the understanding and transmission of information via the terminal connection links can be made possible. The first terminal connection link USC link connects to the first selector means, i.e. in this case the selector core USC and consists of an interface and the second terminal connection links comprise: in the embodiment which will be discussed here at least one interface which may or may not differ from said first interface depending on which are the terminal connection unit links TCU link (TCL-1, TCL-2 or TCL-3).

In the following, an exemplary embodiment will be discussed, which comprises two special interfaces. However, these are only given for illustrative reasons and a number of other alternatives are of course also possible. embodiment where a transmission system is connected directly to a connection unit TCU. The TCU must then be able to find out (for example by reading) how the transmission system allocates its time slots in the interface. Z here denotes a selector or the like. In a particular embodiment, it could also be a TCU in which case a direct connection is provided.

Figure 2 illustrates a terminal- The two interfaces that will be described will hereinafter be referred to as USI 2 and USI 4 (the second and the first interface, respectively). The USI 2 interface (the second interface) is an 8.l92Mb / s interface with 113 time slots TS per frame and a remainder of 7 bits. USI 4 is an 184.32 Mb / s interface with 2560 10 15 20 25 30 35 504 161 8 time slots per frame. In both interfaces, there are 9 bits per time slot.

The frames of both interfaces are further divided into rows and columns. The USI 2 interface has 12 columns and 9 rows of time slots plus 5 extra time slots and the USI 4 interface has 284 columns and 9 rows of time slots plus 4 extra time slots. A frame of the USI 2 interface and the USI 4 interface is illustrated in Figures 3 and 4, respectively. The time slots TS are divided into three different types of time slots, namely base time slots BTS, control time slots CTS and data time slots DTS. The base time slots BTS are mainly used for frame control purposes and they are fixedly arranged within the frame, ie they have been assigned fixed positions within the frame. The control time slots CTS are used for and data time slots In the embodiment shown, a terminal control package is used for switching data. connection unit TCU equipped with one or more detail processors DP as will be described further later.

The communication channels of a detail processor DP comprise a detail processor interface DPI which in turn comprises a detail processor data interface DPDI and a control interface DPCI. detail processor- DPDI has two channels DPD and D64 (Data 64 kbit) through DPCI, a detail processor can receive information over the USC PN control packet network. control time slots CTS and to the detail processor via DPCI. A detail processor can also communicate with the selector data network, then provided via data time slots DTS. That information is introduced via DPDI to either DPD or D64. DPD and D64 include fixed channels in the interface. The DPD channel is always mapped to the DTSB1 time slot and the D64 channel is mapped to the DTSB2 time slot.

The transmission is made via the transmission Figures 3 and 4 respectively show a frame of each of the USI 2 and USI 4 interfaces. In the figures, base time slots are denoted B. The fields (time slots) without designation, ie the empty fields, indicate that the time slots can be allocated either as data time slots DTS or control time slots CTS. The remainder of 7 bits in Figure 3 is denoted X. A DPD is allocated in DTSB1 (1) and D64 in DTSB2 (2) as referred to above. 10 15 20 25 30 35 504 161 determines the allocation of time slots in is designated a Hardware circuit as the interfaces USI allocation memory AS.

The allocation memories can be accessed by terminals for allocation connection and they can be accessed from the central processor software via USC PN, the control packet network.

Allocation and mapping will now be explained with reference to Figure 5. Allocation refers to the definition of a time slot in an interface such as a data time slot DTS or a control time slot CTS.

The allocation memory AS is used for the definition of the time slots in the transmission direction. In data time slots and control time slots are separated by line coding, each time slot is coded either as a data time slot or son: a control time slot.

The allocation memories ASO, AS1, AS2, AS3, ..., ASn are arranged in the present exemplary embodiments in the reception direction first selector means, or in the selector core USC. Additional allocation memories AS are located in the terminal connection unit TCU so that there is an allocation memory AS for each TCU link. In the USC selector core, there is an allocation memory for each USC link.

How the time slots in the USI interface are allocated depends on the category of each TCU link. The allocation of the time slots in the interface on the TCU links used for detailed processor communication is hard coded: in the hardware and the allocation can not be changed by the central processor software, the allocation to the time slots on the TCU links used for connection to the terminal units each terminal is hard. In general, there is a frame delay between incoming and outgoing frames. This means that an outgoing frame (USI4) on the USC link is delayed relative to an incoming frame (USI2) on the TCU link. The same applies to transmission in the other direction, ie the outgoing frame (USI2) on the TCU link is delayed relative to the incoming frame (USI4) on the USC link. In general, the mapping algorithm (which will be explained in more detail below) will be more flexible the longer the frame delay. A terminal unit which terminates a transmission system and which is connected to a TCU via a TCU link must allocate data time slots DTS in USI2, one DTS for each traffic channel in the transmission system.

If the terminal unit TU comprises a detail processor DP (discussed above), DTSB1 and / or DTSB2 must also be allocated. The allocation of DTS can be done in different ways, but the DTSs should be spread as evenly as possible over the selector terminating units which are not discussed further here.

USI2 frames. The allocation information The corresponding TCU allocation memory must be loaded with the same allocation, the TCU terminal unit TU about the special allocation to be able to and the CP software for must ask the CP software to load the allocation memory AS. The CP software of the terminal connection unit TCU determines the allocation of the time slots in the interface on the USC link and the TCU link used for cascade connections.

The allocation is identical in both directions, ie to the selector core USC and from the selector core USC, respectively.

The hardware circuit that determines the mapping of the time slots for this. The mapping memories are accessed by mapping setup terminals. These interfaces are referred to as a mapping memory MS. terminals are available from the CP software. Mapping means the connection of a data time slot DTS in one interface to a data time slot DTS in another interface. Mapping memories are located in the terminal connection unit, here two mapping memories per terminal connection unit, one of which is intended for the selector-to-link direction XL and the link-selector direction LX. The mapping is the same in both directions others are intended for (as is the allocation), ie the two mapping memories MS store the same information. The mapping is controlled by the terminal connection unit's TCU CP software. All time slots that are not mapped are allocated here as control time slots CTS. Figure 3 only indicates the fact that a number of TCUs can be connected to the selector core USC which may comprise one or more connection units of the terminal connection units EU-0, ..., EU-n. In each connection unit there are a given number of allocation memories, for example there are four allocation memories, ASO, AS1, AS2 and AS3 in the first connection unit EU-O. In the figure it is also indicated that a number of terminal units TU can be connected to each terminal connection unit TCU.

The first and second means of selection will be described in more detail below. The first selector means, in the illustrated embodiment shown as the iron core USC, performs the actual time and space selector operations on the data streams. the selector core USC equipped with a number of allocation memories AS, one for each USC input as discussed above. The allocation memories AS are in the example shown designed for the USI 4 interface as discussed above. They are owned by the USC CP software which, however, needs to retrieve the allocation information TCU CP software in the allocation memory AS-LX in the TCU which determines the allocation of the USI 4 interface on the USC link. the USC selector core comprises a device processor and an equipment processor (not shown) which are available from the USI 4 interface. There may be more of each if redundancy is applied; this is also generally applicable to the device processors within TCU. Communication with these device processors and equipment processors requires time slots on the USC link and two base time slots in the first USC links are reserved for this purpose. It is a hardware reservation that can not be changed from the CP software. The device processor (s) are mainly used for maintenance of the selector core USC, while the processor (processors) are used for equipment synchronization of the selector device.

The main task of the terminal connection unit TCU is to multiply the data streams between the multiplexing and / or demultiplexing terminal units (which will be explained further below) and well the iron core USC. The multiplexing and / or demultiplexing is controlled by the mapping and allocation function, also referred to as means arranged to provide resources or control means. The function as such is mainly implemented in the CP software for the terminal connection unit TCU. 10 15 20 25 30 35 504 161 12 The terminal connection unit TCU has an input for connecting the TCU to the previous unit in the core direction unless, of course, it is the first terminal connection unit which is directly connected to the selector core USC. However, this input is designed for the first number of connection unit link inputs connection units in question, i.e. the TCU variant. The TCU cascading link inputs are designed for the first terminal connection link USI 4. terminal- depends on the type of terminal used the interface USI connections to terminal units TU are designed for the first and / or second interface, ie for USI 4 and / or USI 2. The TCU link inputs used for detailed processor communication are in 4 while the TCU link inputs used for the illustrated embodiment are designed only for the second interface USI 2. Each input comprises an allocation memory AS which determines the allocation of the time slots in the transmission direction.

A terminal connection unit TCU is equipped with a detail processor (or more for redundancy), see figure 1. The detail processors DP are connected internally in the TCU via USI 2 interface. A detail processor in a TCU uses only the DPD channel (as discussed earlier in this document) and it is mapped to DTSB1. For each detail processor 'one is needed. reservation. This reservation is in accordance with the illustrated embodiment made on a time slot basis which will be explained further below.

Data time slots received on TSU links are terminated in two first-in first-out memories (FIFO) in the terminal connection unit. One of the FIFO memories is used for traffic time slots and another FIFO memory is used for DTSBs. DTSBs are dedicated to devices equipped with one or more detail processors as discussed above. However, FIFO memory for the control packet network control time slots. If an additional data is used, data is introduced into and / or removed from a selector device via a terminal unit TU. The selector device forms a selector structure comprising the first and second selector means USC and TSUnhL_Hm and the terminal units. It terminates in a selector terminating unit (not illustrated) which takes two different forms, one of which supports USI 2 and the other supports USI 4. A terminal unit may also comprise a mapping and allocating unit. The allocation of time slots in the interface between the terminal unit and the selector device is given by the selector termination unit circuit. If a transmission system with external is connected to the terminal units also map external time slots to the interface (USI2). Seen from the mapping and allocation function, the interface forms the terminal unit, the terminal unit mapping and allocation needs a constant, ie it is hard coded as the mapping and allocation function needs information about this allocation to be able to load the allocation memories AS and the mapping memories MS mentioned earlier. the terminal connection unit TCU. The terminal unit can data time slots DTS both via time slot-based reservation. column-based reservation and Column-based reservation and time slot-based reservation will be explained below.

There is one voter memory (not shown) per USC link. Therefore, consecutive TSs from the USC link are stored in consecutive positions within the selector memory. The position numbering of the time slots starts from the first USC link for extension 0 (EU-O).

Because USI 4 is used on the USC link, the selector memory is capable of storing 2560 Each multiple position. This means that the first link on EU-O "owns" multiple position 0 to 2559, the second link "owns" multiple position 2560 to 5119, and so on.

TS: er. selector memory position corresponds to a As soon as the mapping and allocation of time slots on the USC link is performed for a user, it is known which positions are assigned to the particular user. the allocation algorithm for the Below mapping and selecting device will be further discussed. Mapping and allocation in the selector basically consists of three sub-functions, namely reservation of, loading and releasing of mapping and allocation data. Mapping and allocation data charging is performed when a unit is put into operation. Mapping and allocation data is then loaded into the affected mapping and allocation memories. Mapping and allocation data release is performed when a device is disconnected. the mapping memories and allocation memories concerned are reloaded. Charging and Mapping and Allocation Data are released and the release functions will not be further described here as what is relevant to the present invention is Mapping and Allocation Data Reservation which includes an algorithm executed in a Mapping and Allocation Data Reservation sub-function when the unit requests resources for a transmission system and / or resources for a retail processor.

The algorithm is active with the construction of mapping and allocation data which will later be loaded into the mapping and allocation memories.

The mapping and allocation data reservation function in accordance with the invention specifies two algorithms for requesting resources on the terminal connection links, namely column based reservation and time slot based reservation. Column-based reservation is used for time slot-based reservation traffic channels are used while detail processor channels are used.

When a unit (eg a terminal unit TU) makes a column-based for the special unit. The number of reserved columns depends on the number of requests for data time slots, the entire column is reserved for data time slots that are requested. On the other hand, when a unit makes a time slot-based request for data time slots, time slots are reserved in the idle, or if possible, column that is reserved for time slot-based reservation. The data time slots within this column can belong to either one device or a number of different devices.

In the following, column-based reservation will be further explained. Column-based reservation is used for reserving data time slots for, for example, a transmission system. In accordance with the present invention, it is possible to handle arbitrary transmission systems which can vary, for example, from 1 up to 2547 64Kb / s channels. The invention is applicable to systems with 65Kb / s channels. In principle, however, it is also applicable to other transmission systems provided that a number of requirements are met, for example that the frames are synchronized, are equal in time OSV.

In a particular embodiment described herein, the USI4 interface is used on the USC link. this interface has 9 allocable time slots within a column and there are 283 reserveable columns. For column-based reservation, the USI4 framework is divided into areas. By dividing the number of requested data time slots DTS by 9, ie the number of allocable time slots within a column, the number of frames is given in areas. The number of reserveable columns in the interface, ie here 283, is divided by the required number of areas, which thus gives the number of columns within the areas. The remaining columns are then grouped together at the end of the frame to form a residual area. For the requesting entity, a column in each area will be reserved unless the request is denied which will be explained below.

An example will now be given in accordance with which a 2Mbit / s transmission system with 32 channels is connected to a terminal unit.

Since there are 32 time slots, these will be divided by 9 which gives 3.55 areas. This number will be rounded up and it thus gives 4 areas.

To determine the number of columns per area, the 283 columns will be divided by the 4 areas giving 70.75 columns per area. This number will be rounded up and thus gives 70 columns per area and a residual area of three columns, here the last columns numbers 283, 282 and 281. This number also means that a maximum of 70 2Mb / s transmission systems can be connected to the USC link.

The algorithm then begins with a search for the first free column in the first area after which a jump of 70 columns is made 10 15 20 25 30 35 504 161 16 to find the corresponding column in the second area etc. for columns 3 and 4 etc. If the corresponding column is occupied in area 2, 3 or 4, the procedure is started again. This means that the next free column in the first area, area 1, is selected. The procedure is restarted because it is an ambition to have the columns located at equal distances and to form a structure of reserved columns that makes alternative and / or future reservations of columns optimal. The columns are advantageously equidistant for performing column switching. If it is not possible to request equidistant columns, the first free column in each area is reserved, which is referred to as shifted columns. If it is not possible to reserve so-called shifted columns either, the request will be rejected.

If the number of data time slots requested is not a multiple of 9 (in this case), a number of time slots will remain. These will be allocated as control time slots as referred to above.

For the 2Mb / s transmission system, there will be 4 time slots allocated as control time slots because four columns x 9 time slots are equal to 36 time slots and 36 time slots minus 32 time slots are equal to 4 time slots. is allocated in the reserved column in the last area as can be seen from figure 6. The control time slots CTS are allocated in this way to eliminate the risk of bottling or spillage in the FIFO memories for Then these control time slots CTS will reach the terminal connection units. Column reservation is I fl. a advantageous reservation method, for example when loading mapping and allocation data into the memories and when a user wants to switch an entire column.

Time slot-based reservation will now be explained further.

Time slot-based provisioning is used here for detail processor channels or DP channels that include communication channels to a detail processor. The detailed processor interface DPI consists of a detailed processor data interface DPDI and a detailed processor control interface DPCI. The detail processor data interface DPDI supplies two detailed processor channels DPD and D64 as previously referred to. 10 15 20 25 30 35 504 161 17 A device can use either one of the channels or both. The DPD channel is mapped in the DTSB1 slot into a USI frame and the D64 channel is mapped in the DTSB2 time slot. If a DTSB is not used, it will be allocated as a control time slot CTS.

The time slot-based reservation starts from the last column, in the embodiment described here from column 283.

Since 283 is a prime number, column 283 will never be reserved for traffic channels except for a case in which either one or 283 channels must be reserved. The number of columns that will be used for traffic channels depends on the specially connected transmission system or systems. In the case of the 2Mbit / s transmission system, three columns, namely columns Nos. 283, 282 and 281, will never be used for column-based reservation.

The time slot-based reservation algorithm can be said to form a compromise between using the residual area, ie the remaining columns, to spread the columns evenly across the interface frame to minimize the effects of the column-based reservation and to take into account that different types of transmission systems can be connected to one and same USC link.

The time slot-based starts by examining whether any columns are reserved on a time slot basis. If there are no columns reserved on a time slot basis, the column reservation algorithm 283 is selected and the requested number of time slots is allocated as data time slots. If, on the other hand, columns have been reserved on a time slot basis, these columns are examined and if there are sufficient free time slots in each of the columns, these are reserved and allocated as data time slots.

However, if there are not enough vacancies, a new column must be reserved. The residual area of the last connected transmission system is examined and the first free column is selected and the requested number of time slots is allocated as data time slots DTS. 10 b5 20 25 504 161 18 However, if none of the columns in the residual area is free, a calculation must be made based on the requested number of time slots for the last This answer connected transmission system. calculation calculation made for column-based reservation as discussed above. The number of requested time slots is thus divided by 9 which gives the number of areas and the number of columns is divided by the number of areas which thus gives the number substantially towards the columns per area. In accordance with the time slot-based reservation, the last column in the last area is examined first. If this column is occupied, the corresponding column in the penultimate area will be examined, and so on. until a free column is found or all areas have been examined. If all areas have been examined, the algorithm starts again from the penultimate column in the last area and repeats the described procedure until a vacant rejected column is found and so on. If no free column can be found, request.

In accordance with the invention, the resources of the interface on the link connecting to the selector core can be used optimally for one or only 32 and 24 in accordance with transmission systems. Today there are channel systems (2Mbit / s and 1.5Mbit / s) present invention, it will also be possible to connect several but in, for example, other types of transmission systems or future transmission systems.

Claims (30)

10 15 20 25 30 35 504 161 19 PATENT REQUIREMENTS A multiplexing / demultiplexing device in a digital communication system using time division multiplexing (TDM) comprising a selection device (US) comprising first selecting means (USC) for coupling data and (TCUh, q, H_m) for multiplexing and / or demultiplexing of data, connection means in the form of terminal connection links (TCL) for connection of selection means (USC, TCU; TCU, TCU), where control data and connection data are transmitted on the terminal connection links (TCL) comprising logic interfaces (USI4, USI2) comprising a number of time slots ( TS) arranged in rows and columns and means for providing other selector means resources in the form of time slots (TS), characterized in that the terminal connection links (TCL) terminal connection links (USC links) for connecting a number of other selector means (TCU; TU) to the first selector means (USC), the first comprising a first interface (USI4) and second terminal connection links (TCU links) for connections of the second selector means (TCU) comprising first and / or second interfaces (USI4, USI2) and that via means for providing the interface of the first terminal connection link (USI4), resources are reserved for at least two different functionalities using the first terminal connection links include resources on that reservation of resources based on columns in the interface and provisioning based on time slots in the interface. Device according to claim 1, characterized in that the other selecting means comprise a number of terminal connection units (TCU). Device according to claim 2, characterized in that the other selecting means further comprise terminal units (TU) 10 15 20 25 30 35 504 161 20 connected to the terminal connection units (TCU). Device according to any one of claims 1-3, characterized in that the first selector means (USC) consist of a selector core. Device according to one of the preceding claims, characterized in that the other terminal connection links (TCL) comprise one or more (TCL-1) for terminal units (TU) to other select means, terminal connection links (TCL-2) for cascade connection. 'of other selector means (TCU), terminal connection links (TCL-3) second selector means (TCU) for communication with detail processors (DP). terminal connection links connection of internally within the Device according to one of the preceding claims, characterized in that either directly to terminal connection units (TCU) or to number of terminal units (TU) connected (TCU), a transmission system is connected indirectly via the terminal connection units. Device according to one of the preceding claims, characterized in that the resources (TS) are reserved by column-based reservation for the first functionality relating to the reservation of time slots for traffic ducts. Device according to one of the preceding claims, characterized in that the resources (TS) are reserved by time slot-based reservation for detail processor channels (DP channels), which thus refers to a second functionality. Device according to one of the preceding claims, characterized in that a number of time slots denoted base time slots (BTS) have fixed positions within the frames in the interfaces and that they are mainly used for frame control purposes. Device according to any one of the preceding claims, characterized in that the means for providing allocation means for defining data time slots (DTS) to control time slots (CTS) used for control packets. includes (TS) as resources time slots are used for connection data and 11. ll. Device according to claim 10, characterized in that the data time slots (DTS) are reserved and / or via time slot-based reservation. can be requested via a column-based Device according to claim 11, characterized in that for requests of data time slots (DTS) of a terminal unit (TU) for a transmission system which. is connected to it, column-based reservation was used. Device according to claim 11 or 12, characterized in that a terminal unit comprises a retail processor (DP) and that for this, time slot-based requests of resources for reservation are used. Device according to one of Claims 11 to 13, characterized in that for column-based reservation in the interface (USI4) used on the first terminal connection link (USC link), the frames are divided into areas by dividing the number of requested data time slots ( DTS) with the number of allocable time slots within a column to find the number of areas needed and by dividing the number of columns that can be reserved in the interface (USI4) by the requested number of 10 15 20 25 30 35 504 161 22 areas, thus giving the number columns within the area and that one column in each area is reserved for the terminal unit (TU) or for a device in a transmission system that is directly connected to a terminal connection unit (TCU). Device according to claim 14, characterized in that in the interface (USI4) on the first terminal connection link (USC link) 9 time slots (TS) within a column are allocable and that the number of columns that can be reserved is 283. Device according to claim 14 or 15, characterized in that the allocating means consist of an algorithm for finding columns in each area which is equidistant, preferably starting from the first free column in the first area, and so on. Device according to claim 16, characterized in that if it is not possible to reserve equidistant columns, the first free column is reserved in each area, ie shifted columns. Device according to claim 17, characterized in that a request is rejected if it is not possible to either reserve equidistant columns or to reserve shifted columns, (ie the first free column in each area). Device according to any one of claims 14-17, characterized in that if the requested number of data time slots (DTS) is not a multiple of the number of allocable time slots within a column, the remaining time slots are allocated as control time slots (CTS) in accordance with a given schedule. 10 15 20 25 30 35 504 161 23 Device according to one of the preceding claims, characterized in that time slot-based reservation is used for reserving detailed processor channels (DP channels). Device according to claim 20, characterized in that for time slot-based reservation, the reservation is started from the last column of the columns in which the frames in the interface (USI4) for the first terminal connection link (USC) are divided and, time slot-based that if reserved for reservation , the last column is selected and the requested number of no columns are time slots allocated as data time slots (DTS). Device according to claim 20, characterized in that if columns are reserved for time slot-based reservation and if there are a sufficient number of free time slots therein, these time slots are reserved and allocated as data time slots (DTS). Device according to claim 20, characterized in that if the columns are reserved for time slot-based reservation and if there are not enough free time slots in any of the remaining area of the last connected these columns, the transmission system and the first free column are selected. . Device according to claim 20, characterized by reserved columns which are not in that if none of the column-based reservation contains a sufficient number of free time slots, the allocation means make a calculation to find the number of columns per area after which, starting from the last column in the last area, the columns are examined in a reverse consecutive manner, corresponding to columns in each area, until a free column is found. 10 15 20 25 30 35 504 161 24 A digital use time division multiplexer (TDM) selector comprising at least the first and communication systems second selection means and control means for controlling multiplexing / demultiplexing of time slots, wherein connecting means are provided for first selecting means with a selecting means, connecting at least said or several other connecting means. interface with a number of frames with time slots arranged in rows rows and columns, characterized by the fact that the control means reserve resources (TS) in the interface (USI4) which are requested for a first functionality on a column basis and that they reserve resources (TS) in the interface for a second functionality on a time slot basis. Selector device according to claim 25, characterized in that the first traffic channels. the functionality refers to resources (TS) for A selector device according to claim 25 or 26, characterized in that the second functionality refers to resources (TS) for internal detail processors within the other selector means (TCU; TU). 28. A method for reserving resources, for example in the form of time slots in a connection of at least a second selection means with a first selection means in a selection device used: in a digital communication system using time division multiplex (TDM), where the resources in the interface (eg time slots) are arranged in frames' in which the resources are connection means interfaces arranged in rows and columns, characterized in that when resources are requested for traffic channels, depending on the number thereof, resources needed, one or more columns are reserved with resources according to a given schedule, and resources that are requested for detail processor channel resources are reserved on a resource basis. 10 15 504 161 25 A method according to claim 28, characterized in that the other selecting means comprise a terminal connection unit (TCU) and at least one terminal unit (TU) connected thereto, and that resources for traffic channels and / or detail processor channels connected to one are requested by a terminal unit ( TU) terminal connection unit (TCU). A method according to claim 28, characterized in that resources for traffic channels and / or detail processor channels are requested by a device in a transmission system connected directly to a terminal connection unit (TCU) for a second selection means.