EP1135898A1

EP1135898A1 - Method and communications system for transmitting data for a combination of several services via jointly used physical channels

Info

Publication number: EP1135898A1
Application number: EP99959368A
Authority: EP
Inventors: Michael Benz; Anja Klein; Armin Sitte; Thomas Ulrich; Volker Sommer
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1998-11-30
Filing date: 1999-11-30
Publication date: 2001-09-26
Also published as: EP1006692A1; WO2000033516A1

Abstract

A common data rate for all of the different services being transmitted via jointly used physical channels is always known to the receiver, regardless of the momentary combination of transport formats. According to the invention, this fact is exploited for the purpose of reducing the in-band-signalling capacity needed. The common data rate is produced from a preceding resource allocation (number of spread codes and/or time slots, spread factor, etc.) by so-called "blind detection" by the receiving end (determination of the data rate or the spread factor) during detection or by receiving-end identification of the resources momentarily in use within the pool of allocated resources. The common data rate that is determined is an implicitly available piece of information for the combination of transport formats since only certain combinations are possible for a given common data rate. The invention is applied in UMTS mobile radiotelephone systems.

Description

description

Method and communication system for the transmission of data of a combination of several services via shared physical channels

The invention relates to a method and a communication system for the transmission of data of a combination of several services over shared physical channels, in particular in mobile radio systems with broadband radio channels.

A communication system provides one or more physical transmission channels for the transmission of data between a data source and a data sink. The transmission channels can be of various types, e.g. for wired transmission with electrical or optical signals or for radio transmission via a radio interface using electromagnetic waves. In the following, the radio transmission is dealt with in particular without restricting the generality of the field of application of the invention.

The radio transmission is used in mobile radio systems to establish a connection to non-stationary subscriber terminals. A mobile station of a mobile radio system is such a non-stationary subscriber terminal. The mobile station can request a connection from any location within the network coverage or a connection to the mobile station can be established. The most widespread mobile radio system is GSM (global system for mobile communications), which was developed for a single service for voice transmission. The GSM mobile radio system is referred to as the 2nd generation system.

For the following, the 3rd generation of mobile communications, which is currently standardized in Europe under the name UMTS (universal system for mobile communications), is in contrast provided to a plurality of services, the-earth within a transmission protocol via shared physi ^¬ channels to be transmitted.

The standardization documents ETSI SMG2 / UMTS L23 expert group, Tdoc SMG2 UMTS-23 257/98, from October 6, 1998, Tdoc SMG2 508/98 and Tdoc SMG2 515/98, from November 16, 1998, provide an overview of the current state of development of the standards ^¬ Discussion and in particular about the requirements as to how a transmission protocol can support the transport of data from several services.

The use of a common physical channel for the transmission of data from several services presupposes that a clear mapping rule specifies the assignment of the services to different segments of the physical channel. A physical channel is quenzband example, by Fre ^¬, a spreading code (CDMA code division multiple access) and, if a time slot within a frame defined.

The following terms are used to describe the mapping rule:

Transport Format (TF):

A transport format defines a data rate, a coding, an interleaving, a data rate adjustment by puncturing and an error protection regulation of a transport channel for a service.

Transport Format Set (TFS):

This is a set of possible transport formats that are permitted for a special service.

Transport Format Combination (TFC): This term indicates a possible combination of transport formats of the various services that are mapped onto a common physical channel.

Transport Format Combination Set (TFCS):

A set of possible TFCs is hereby designated as a subset of all TFCs that are permitted for a specific connection.

Transport Format Combination Identifier (TFCI): This information indicates the currently used combination of transport formats within the TFCS.

Examples of the transport formats can be found in ETSI SMG2 / UMTS L23 expert group, Tdoc SMG2 UMTS-23 257/98, from October 6, 1998, pp. 14-16.

In order to select the combination of transport formats of the various services that is currently used, it is necessary to change the TFC and thus to regularly signal the TFCI. However, this signaling ties up transmission capacity. The greater the number of possible combinations (TFCS), the more capacity is required for signaling.

The invention is based on the object of specifying a method and a communication system which reduce the required signaling capacity without restricting the number of possible combinations and their selection. This object is achieved by the method according to the features of claim 1 and the communication system with the features of claim 10. Advantageous further developments can be found in the subclaims.

According to the invention, the fact is used that, regardless of the combination of the transport formats, a total data rate for all services is known to the recipient. This total data rate results from a previous resource division (number of spreading codes and / or time slots, spreading factor, etc.), by a so-called "blind detection" of the receiving side (determination of the data rate or spreading factor) during the detection or by detection of the currently used resources within the pool of allocated resources ( The specific total data rate is an implicit information for the combination of the transport formats, since only certain combinations are possible for a given total data rate. This exclusion of possible combinations for a given total data rate is used to reduce the signaling requirement.

Only partial information relating to the combination of the currently used transport formats is thus generated on the transmission side and signaled to the reception side, which uses binary coding with a number of digits which is reduced in comparison to the total of the permitted combinations. If only 2 possible combinations could normally be signaled with n bits, this number can be increased considerably in accordance with the invention or the bits required for signaling reduced. This reduces the transmission capacity required for signaling. This saved transmission capacity can be used to transmit user data and thus to increase the performance of the communication system.

The total data rate, which is taken into account when determining the combination of the transport formats, indicates a bit or symbol rate before or after a channel coding. The total data rate denotes the sum of all data rates of the physical channels to which the partial information relates. The symbol rate after the channel coding indicates the rate on the physical channel or channels (for example the radio interface). Alternatively, the total data rate can also mean the useful bit rate. A common reference size for the total data rate can be defined. The symbol rate is determined by the spreading factor.

According to an advantageous development of the invention, the data transmission takes place via a radio interface of a radio communication system. In radio communication systems, e.g. UMTS, the transmission resources are particularly scarce. The number of available frequency bands is limited and each operator can only use a certain part of it. Nevertheless, high data rates (up to 2 Mbit / s) should be offered for some services. The invention has particular advantages in such a radio communication system.

A particularly flexible allocation strategy of transmission capacities to connections is made possible if a radio interface is formed by a broadband frequency channel (e.g. 5 MHz), signals in several physical channels that can be separated by spreading codes or additionally by time slots being transmitted simultaneously. By changing the spreading code or by assigning additional spreading codes, the transmission capacities can be quickly adapted to the requirements. The invention is suitable both for use in the FDD (frequency division multiplex) and in the TDD (ti e division multiplex) mode of a radio communication system.

For particularly fast signaling, the partial information is transmitted in every frame of the data transmission of the common physical channel. This also results in a very quick change of the selected combination. The joint transmission of data from several services can relate to one or more channels. In the case of a number of shared channels, the data from a number of services are mapped onto a coded common transport channel and the data from the coded common transport channel is in turn evenly distributed over a number of physical channels. Embodiments of the invention will be explained in more detail with reference to the beilie ^¬ constricting drawings.

1 shows a schematic representation of a radio communication system, FIG. 2 shows a layer model of the transmission protocols, FIG. 3, 4 shows data of different services on common physical channels, FIG. 5, 6 shows tables with a mapping rule below

Taking the total data rate into account, and FIG. 7 shows a frame-by-frame data transmission with in-band

Signaling.

The mobile radio system shown in FIG. 1 as an example of a radio communication system consists of a multiplicity of mobile switching centers MSC which are networked with one another or which provide access to a fixed network PSTN. Furthermore, these mobile switching centers MSC are each connected to at least one device RNM for controlling the transmission resources. Each of these devices RNM in turn enables a connection to at least one base station BS.

A base station BS can establish a connection to subscriber stations, for example mobile stations MS or other mobile and stationary terminals, via a radio interface. At least one radio cell is formed by each base station BS. 1 shows connections for the transmission of useful information between a base station BS and mobile stations MS. Within a connection VI, data from, for example, three services S (S1, S2, S3) within one or more physical channels Phy CH and signaling information, for example the allocated radio resources for a connection VI, are transmitted via a connection-accompanying control channel FACH (Forward link Access CHannel ) transfer. An operation and maintenance center OMC implements control and maintenance functions for the mobile radio system or for parts thereof. The functionality of this structure can be transferred to other radio communication systems in which the invention can be used, in particular for subscriber access networks with a wireless subscriber connection.

In the radio communication system according to FIG. 1, data transmission means, receiving means and signaling means are provided both in the base stations BS and in the mobile stations MS, which communicate with one another. The data transmission means serve to transmit data of a combination of several services S via the currently available common physical channels Phy CH. The signaling means determine partial information TFCI on the selected combinations of transport formats for services S1, S2, S3 and carry out in-band signaling of the transport formats TF.

The layer model according to FIG. 2 shows a division of the

Protocols of the radio communication system in three layers. Layer 1: physical layer to describe all functions for bit transmission via a physical medium (e.g. coding, modulation, transmission power control, synchronization etc.),

Layer 2: Layer of the data connection to describe the

Mapping of data to the physical layer and its

Control,

Layer 3: Network layer for controlling the resources of the radio interface.

Further details can also be found in ETSI SMG2 / UMTS L23 expert group, Tdoc SMG2 508/98, dated November 16, 1998, pp. 9-25 (figure 11). In layer 3, the TFCS is defined for a connection, during which layer 2 is used to select a combination (a TFC) which, as shown later, is signaled using a TFCI in-band. The exchange of parameters between layers 1 and 2 supports the functions of transferring frames with layer 2 data via the radio interface and displaying the status of layer 1 to higher layers. The parameter exchange between layers 1 and 3 supports the control of the configuration of the transmission in layer 1 and generates system information about layer 1.

The mapping of the data of different connections S onto a common physical channel Phy CH corresponds to the interaction of layers 1 and 2.

According to FIGS. 3 and 4, there is a need for signaling transport formats TF for currently transmitted services.

3 shows a functional representation of a coding and multiplexing unit which maps the data of a plurality of data channels DCH, these each corresponding to the data of a service S1, S2, S3, onto a coded common transport channel CCTrCH. A mapping is a regulation according to which bit pattern the data are entered in a serial data sequence. A demultiplexer / allocation means distributes the data of the encoded common transport channel CCTrCH to several physical channels Phy CH. Data of several services S1, S2, S3 are thus constantly transmitted via the physical channels Phy CH. No physical channel Phy CH is assigned to a service S1 or S2 or S3 alone but to the coded common transport channel CCTrCH with all its services S1, S2, S3.

Since the receiving side must understand this figure and read the data from the physical channels Phy CH and display them again in separate transport channels DCH of the services, signaling is required. This signaling in the form of partial information TFCI gives the current used combination of the transport formats TF of the services again. Which combinations are permitted for the connection (TFCS) was agreed to establish the connection.

FIG. 4 shows the image in a slightly modified form, it becoming clearer that only when physical channels Phy CH are shared by several services S1, S2, S3 is it necessary to signal the partial information TFCI. If a service S1 or S2 or S3 uses a physical channel Phy CH exclusively, the signaling of the partial information TFCI can be dispensed with.

The services S can be of various types. For example, Sl, S2 are services with high data rate dynamics, e.g. Sl is a video transmission and S2 is an internet connection, and S3 is a service with low data rate dynamics, e.g. a voice transmission.

The selected combinations TFC of the transport formats TF are defined according to a first exemplary embodiment corresponding to FIG. 5, two different total data rates GR1, GR2 being possible. The total data rate GR plays no role for binary-coded partial information TFCI of “0000”. The combination TFC coded with “0000” is always TFC0. With the partial information "0001" is based on the total data rate

GR1 or GR2 differentiated into two different combinations TFCI or TFC2. This means that the number of combinations TFC that can be coded with 4 bits is greater than 2. In other words, a given number of TFC combinations can be encoded with fewer bits. However, it is also within the scope of the invention to use encodings other than binary.

The information about the total data rate GR is contained in a completely coded combination. However, this information is redundant and is replaced by partial information TFCI according to the invention. A second exemplary embodiment according to FIG. 6 assumes a total of five different total data rates GR, the levels between the total data rates GR1 to GR5 being identical to the levels of the data rates of the transport formats TF for simplification. Two services S1, S2 are supported, each of which can use four different transport formats TF11 to TF14 and TF21 to TF24. The mapping rule manages with just one bit as partial information TFCI for eight possible combinations. The symbol "-" means that this value can be arbitrary.

Another exemplary embodiment should be mentioned briefly: Does the TFCS consist of K different services Si with i = l..K for which Li allowed transport formats TF are defined.

TFC = (TFü, TF _i2 , ..TFi _L i)

For the purposes of the invention, the partial information TFCI only specifies the possible combinations of services 1 to K-1, while the transport format TF of service K can be determined via the total data rate GR minus the data rates of the other services 1..K-1. Service K is advantageously the one with the highest number of different transport formats. This results in the greatest reduction in the binary symbols required for coding.

The total data rate GR is transmitted in a fast connection-accompanying control channel FACH as a resource allocation (spreading code, spreading factor, time slot) or is obtained from the signals themselves according to a blind detection by the receiving side.

The in-band signaling of the partial information TFCI takes place according to FIG. 7. Within a frame-wise transmission of data (data) together with further information there is also capacity for transmission of the currently selected combination of the transport formats in the form of the partial information TFCI. In FDD mode, a frame has a duration of 10 ms, bits of a pilot sequence (pilot) are used for channel estimation, bits (pc) are required for transmission power control, and bits are reserved for in-band signaling of the TFCI. A data portion data with useful information follows. Error protection coding of the TFCI to, for example, 32 bits and scrambling of the useful information over several frames are not shown in FIG. 7.

The description of the selected transport formats applies to one direction of transmission. Data can of course be transmitted in a connection in both transmission directions (UL upward direction from the mobile station MS to the base station BS and DL downward direction from the base station BS to the mobile station MS), it being possible for the data rates to be determined asymmetrically and accordingly different transport formats TF.

Claims

claims

1. Method for transmitting data of a combination of several services (S) over shared physical channels (Phy CH), in which

- a set of permitted transport formats (TF) is defined for the services (S),

a combination of the currently used transport formats (TF) of the services (S) is determined, partial information (TFCI) relating to the combination of the currently used transport formats (TF) is signaled, the partial information (TFCI) using binary coding with a number of digits , which is reduced in comparison to the total of the permitted combinations, - the data of the services (S) are transmitted according to the combination via a shared physical channel (PhyCH) on the receiving end

an overall data rate (GR) of the combination of the services is determined,

- The combination of the currently used transport formats (TF) is determined from the total data rate (GR) and the partial information (TFCI), and

- The data are evaluated according to the combination determined.

2. The method according to claim 1, wherein the total data rate (GR) is signaled separately.

3. The method according to claim 1, wherein the total data rate (GR) is derived from a resource allocation for the data transmission.

4. The method according to claim 1, wherein the total data rate (GR) is derived from the resource use of allocated resources.

5. The method according to any one of the preceding claim, wherein the total data rate (GR) indicates a bit or symbol rate before or after a channel coding.

6. The method according to any one of the preceding claims, wherein the partial information (TFCI) in each frame (fr) of the data transmission of the common physical channel or the physical channels (Phy CH) is transmitted.

7. The method as claimed in one of the preceding claims, in which the data from a plurality of services (S) are mapped onto a coded common transport channel (CCTrCH) and the data from the coded common transport channel (CCTrCH) is in turn divided equally onto a plurality of physical channels (Phy CH) become.

8. The method according to any one of the preceding claims, wherein the data transmission takes place via a radio interface of a radio communication system.

9. The method according to claim 8, in which the radio interface is formed by a broadband frequency channel, signals being transmitted simultaneously in a plurality of channels which can be separated by spreading codes and, if appropriate, additional channels (Phy CH).

10. Communication system with data transmission means for the transmission of data of a combination of several services (S) via shared physical channels, whereby for the services (S) a set of permitted transport formats (TF) and a combination of the currently used transport formats (TF) of the services ( S) is determined with signaling means which signal partial information (TFCI) with regard to the combination of the transport formats (TF) currently used, the partial information (TFCI) uses binary coding with a number of digits that is reduced compared to the total of the permitted combinations, with receiving means - for determining a total data rate (GR) of the combination of the services, and - for determining the currently used transport formats (TF) from the total data rate (GR ) and the partial information (TFCI) the combination, so that the data are evaluated according to the determined combination.