US20010040876A1

US20010040876A1 - Device for a radio-communication system, in particular for point-to-multipoint connections

Info

Publication number: US20010040876A1
Application number: US09/012,640
Authority: US
Inventors: Siegfried Bruenle
Original assignee: Individual
Current assignee: Ericsson AB
Priority date: 1997-01-23
Filing date: 1998-01-23
Publication date: 2001-11-15
Anticipated expiration: 2018-01-23
Also published as: DE59712861D1; US6445689B2; EP0855844A2; EP0855844A3; EP0855844B1; DE19702028A1

Abstract

A device for a radio-communication system, in particular for point-to-multipoint connections, includes components for a supplementary transmission of ATM cells and for dynamically assigning the transmission capacity as a function of the traffic intensity.

Description

FIELD OF THE INVENTION

The present invention relates to a device for a radio-communication system, in particular for point-to-multipoint connections between a central station and radio-communication subscribers, the transmission being carried out in a radio frame by means of time slots which represent multiples of a basic bit rate.

BACKGROUND INFORMATION

German Patent No. 44 26 183 describes a radio relay system for point-to-multipoint connections in which the frequency channels available for communication between a central station and multiple subscribers can be assigned as needed. The bandwidth of the individual frequency channels can be adjusted to conform to the data transmission rates required by each of the individual subscribers. This system permits a flexible transmission capacity, adjusted to the needs of the subscribers.

SUMMARY OF THE INVENTION

The device according to the present invention expands a radio-communication system which is based on time slot transmission, in particular a radio-communication system based on n*64 kbit/s for the transmission of packet- or cell-oriented data, i.e., services such as ATM cells, the flexible assignment of transmission capacity being ensured both for a time slot transmission with, for example, n*64 kbit/s-time slots, and for packet- or cell-oriented data. The present invention permits the utilization of the compression capacity of ATMs, also in a connection network, having in particular, point-to-multipoint connections. The device according to the present invention is well suited for use in telecommuting workplaces where transmission capacities need to be flexibly assigned.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a block diagram of a modem for transmitting time slots and ATM cells. [0004]
FIG. 2 shows a device for dynamically increasing the bit rate for ATM cells. [0005]

DETAILED DESCRIPTION

FIG. 1 illustrates a radio-[0006] communication subscriber 1 having a modem 2 of a device for a radio-communication system, in particular for point-to-multipoint connections. Both central station 3 and individual radio-communication subscribers 1, which can be individual or PBX lines, have such modems. Central station 3 has as many modems 21, 22, 23, connected in parallel, as the number of radio-communication subscribers that, at a maximum, can establish a radio link with central station 3. The point-to-multipoint radio-communication system utilized here is based on the transmission of n*64 kbit/s-time slots in a radio frame of, e.g., 2 mbit/s, i.e., 32*64 kbit/s. The time slots are chosen in such a way that they represent multiples of the basic bit rate, 64 kbit/s. By means of DBA (Dynamic Bandwidth Allocation), it is only the active time slots that are thereby transferred. In addition to the DBA compression function of the n*64 kbit/s time slots, a similar DBA compression function is also provided for packet- or cell-oriented services, e.g., the ATM cells. In one transmission system, there can either be one of the DBA compression functions singly or, on the other hand, both compression functions in parallel, as the exemplary embodiment in FIG. 1 shows.
The variation of the transmission capacity for a dynamic assignment, i.e., one that is changeable during an existing radio link, especially of the bit rate, on a radio propagation path between radio-communication subscribers and [0007] central station 3 is controlled by measuring the traffic intensity, which is able to be determined from the number of data packets or, e.g., of ATM cells and/or time slots received during a prescribed time period.
Modem [0008] 2 has two external interfaces, for example, for 1*2 mbit/s for n*64 kbit-time slots and 1*10 mbit/s for ATM cells. Alternatively, as shown in FIG. 1, only one interface block 6 can be provided for a compressed time-slot-ATM transmission signal of 1*12 mbit/s. A multiplexer 7 separates the signal arriving from radio interface 6 into the data streams n*64 kbit/s and ATM. In the return direction, a multiplexer compresses both incoming signals into a data stream. The time slot- ATM signals, which have been separated from each other, are each fed to a module 4 or 5, in which the dynamic bit rate assignment for the time slot or ATM data stream is performed. The two outputs of modules 4 and 5 are compressed in two multiplexers 8 and 9 through direct and crossover coupling, as shown in FIG. 1. A modulator 10 or 11 is provided at the output of each of these multiplexers for editing the transmission signals in question and for translating them into the radio-frequency position. In the return direction (direction of reception), multiplexers 8 and 9 separate the signal arriving from a modulator into the data streams n*64 kbit/s and ATM.
The design of module [0009] 5, i.e., of the module for recording and evaluating ATM cells, is depicted in detail in FIG. 2. The ATM cells received from interface 6 are written into a storage device 12, and the filling level of this storage device 12 is determined. For this purpose, provision is made for a cell counter 13 or 14 at the input and output, respectively, of the storage device. A comparator device 15 for the counter readings is used to determine whether the bit rate should be raised. If the number of ATM cells received per period of time is greater than the number of ATM cells transmittable at the radio interface, a threshold value of comparator device 15 is exceeded, and a REQUEST signal 16 for increasing the bit rate is sent to modem control system 17. This modem control system 17 communicates with radio traffic control device 20 of central station 3 via control cells and/or radio multiframes. Block 18, for altering the bit rate, increases or decreases the bit rate by the quantity given by modem control device 17. In addition, the block synchronizes the read-out of storage device 12 over control line 19 adjusted to the set bit rate. Moreover, from the control information from modem control unit 17, block 18 generates control cells which are mixed into the ATM data stream and controls the DBA function, i.e., achieves a switch-over free of bit errors.
A comparable evaluation of the time slots can be performed in [0010] module 4. It is here, in conformance with the time slot evaluation, that more or fewer time slots and/or transmission channels are allotted via the modem control unit.
Since with ATMs various classes of services are provided, e.g., time-critical services such as POTS, ISDN, or video transmission with synchronous information, and also non-time-critical services such as data transmission, various transmission concepts are employed. [0011]
For time-critical services, a basic channel between a radio-[0012] communications subscriber 1 and central station 3 is always available. The transmission capacity, i.e., the bit rate or bandwidth of this basic channel, is determined by the time requirements, synchronicity, and number of necessary control cells. If necessary, the bit rate of a basic channel can be increased.
When a basic channel is used, it is of no importance that the synchronization for increasing the bandwidth lasts, for example, 300 ms, because time-critical cells can be immediately sent over the basic channel. [0013]
For non-time-critical services, between the radio-communication subscribers and the central station, a small basic channel for control cells can always be available, whose bit rate can be increased, as needed. Alternatively, i.e., in the absence of a basic channel, the bandwidth request can be carried out over a radio-communication multiframe. The increase of the bit rate can be executed as follows: the receiver determines on a modem [0014] 2 that the number of ATM cells received is greater than the number of ATM cells transmittable at the radio interface over the basic channel. The receiver sends a request signal REQUEST via a control cell or a radio-communication multiframe to radio traffic control device RASCO (Radio System Controller) 20 of central station 3, requesting a higher bit rate. Since similar REQUESTs can arrive simultaneously from a plurality of receivers, the RASCO processes these REQUESTs with the help of a collision protocol and, if indicated, increases the bandwidth on a link. The increased bandwidth is retained
either for a predetermined time (e.g., maximally 500 ms) [0015]
or until the capacity of the basic channel by itself is again sufficient, [0016]
or until the RASCO cancels the increase (e.g., so that higher priority links are able to send cells). [0017]
As the exemplary embodiment of FIG. 1 shows, in each modem there are two sending and two receiving channels, each of which is supplied by [0018] modules 4 and 5, by means of the direct and crosswise coupling. Signal transmission is always carried out only in one transmitting and one receiving channel; the other transmitting and receiving channel is not active then. When control device 17 receives a request for a change in the transmission rate and it thereupon recalculates the transmission parameters in accordance therewith, it transmits its new transmission parameters as control signals to the relevant switching blocks of the transmitting/receiving channel not in operation. As soon as the new transmission parameters have been set in the relevant modems 21, 22, 23 of the central station, and the radio subscribers have also confirmed at control device 20 the acquisition of the new transmission parameters via the signaling channel (basic channel or radio-communication multiframe), signal transmission and processing in all the modems concerned are continued in the other signal path, where the conversion to the altered transmission parameters is made. Therefore, when a change in the transmission parameters is necessary, for example because one or more supplementary transmission channels or increased bit rates are requested, or there is a different requirement for frequency bands or bit rates, the signal transmission is continued with the old transmission parameters until the new transmission parameters have been set in the as yet inactivated transmitting/receiving channel, and the switchover to this channel will take place only when the transmission is secured (setup before brake). In this way, disruptive interruptions in signal transmission are avoided.
Further details on this subject as well as generally on the assignment of bandwidths during a radio link can be found, for example, in German Patent Application No. 196 12 107.8. [0019]

Claims

What is claimed is:

1. A device for a radio-communication system, a transmission being carried out in a radio-communication frame using time slots, the time slots representing multiples of a basic bit rate, the device comprising:

means for providing a supplemental transmission of at least one of packet-oriented data and cell-oriented data; and

means for dynamically assigning a transmission capacity as a function of at least one of a traffic intensity in the transmitted time slots and a number of data packets or cells, the dynamic assignment being an assignment that is changeable during an existing radio link.

2. The device according to

claim 1

, wherein the system includes point-to-multipoint connections between a central station and radio-communications subscribers.

3. The device according to

claim 1

, wherein a module for recording and evaluating the data packets or cells, within a prescribed time period, and for outputting a request signal to increase the transmission capacity when a number of the data packets per time period exceeds a threshold value, is assigned to a radio-communication subscriber.

4. The device according to

claim 1

, wherein, in order to change the transmission capacity, at least one of the bit rate and a bandwidth of a transmitter of a radio-communication subscriber is switchable.

5. The device according to

claim 1

, further comprising a multiplexer for separating a signal supplied by a radio interface of a radio-communication subscriber into data streams for the transmission of the time slots and of ATM cells, and for, in a return direction, compressing into one data stream the data streams sent by the radio-communication subscriber for the transmission of the time slots and the transmission of the ATM cells.

6. The device according to

claim 1

, wherein a basic channel for control cells requests the transmission capacity between a radio-communication subscriber and a central station.

7. The device according to

claim 1

, wherein a radio-communication multiframe requests the transmission capacity between a radio-communication subscriber and a central station.

8. The device according to

claim 1

, wherein each of a plurality of radio-communication subscribers is assigned one modem with two transmitting and two receiving channels, a signal transmission in the modem being carried out on only one of the two transmitting/receiving channels, wherein, in response to a change in the transmission capacity based on a request signal, another one of the two transmitting/receiving channels not currently in operation undertakes an acquisition of a new transmission capacity, while the transmission in the one transmitting/receiving channel in use is continued until, after a completed acquisition, a switch-over free of bit errors is made to the another one transmitting/receiving channel not in use.

9. The device according to

claim 8

, wherein the modem has devices for dynamically assigning the transmission capacity, both for the time slots and for ATM cells.

10. The device according to

claim 9

, wherein the devices are connected in each case, on an output side, to an input of a first and second multiplexer such that, with each of the first and second multiplexers, the time slots and the ATM cells are compressed into one data stream and are separated, in a return direction, into the time slots and the ATM cells.

11. The device according to

claim 1

, wherein, to evaluate ATM cells, the means for providing includes:

a storage device for storing the ATM cells;

a cell counter for the ATM cells at both an input and an output of the storage device;

a comparator device coupled to the cell counter; and

a modem control device which, as a function of an output of the comparator device, directs a control signal to a device for altering the bit rate.

12. The device according to

claim 11

, wherein the output of the storage device is synchronized by the device for altering the bit rate.

13. The device according to

claim 11

, wherein, in order to transmit a request signal for a higher transmission capacity, the modem control device communicates with a central station via a radio-communication channel.

14. The device according to

claim 13

, wherein the central station includes means for processing the request signal of each of a plurality of radio-communication subscribers using a collision protocol.

15. The device according to

claim 14

, further comprising means for maintaining an assigned increased transmission capacity for a set time period.

16. The device according to

claim 14

, further comprising means for maintaining an assigned increased transmission capacity until the transmission capacity of a basic channel is again sufficient by itself.

17. The device according to

claim 14

, further comprising means for maintaining an assigned transmission capacity until a further control device of the central station cancels the assigned transmission capacity.