WO2000031913A1 - Method and base station for the transmission of information elements via a radio interface of a radio communications system - Google Patents

Abstract

The invention relates to the transmission of a sum of information elements of a non real time service between a base station and a radio station within a certain time interval. The radio station determines transmission conditions of the radio interface and signals said conditions to the base station. Said base station then transmits a segmentation of the sum of the information elements to at least one data packet according to the respective determined transmission conditions and transmits a channel coding to the information elements in order to add redundancy, whereby the transmission is carried out with regard to a minimal number of physical transmission channels which are assigned for the transmission of a data packet within the time interval.

Description

description

Method and base station for the transmission of information elements via a radio interface of a radio communication system

The invention relates to a method and a base station for transmitting information elements via a radio interface of a radio communication system, in particular a mobile radio system.

In radio communication systems, useful information comprising a number of information elements, such as voice, image information or other data, is transmitted with the aid of electromagnetic waves via a radio interface between a transmitting and a receiving radio station. The electromagnetic waves are emitted at carrier frequencies that lie in the frequency band provided for the respective system. In the known GSM mobile radio system (Global System for Mobile Communication), as it is known from J. Eberspächer, H.J. Vögel, "GSM Global System for Mobile Communication", BG Teubner, 1997, is known, the carrier frequencies are in the range of 900 MHz, 1800 MHz and 1900 MHz. For future radio communication systems, for example UMTS (Universal Mobile Tele com unication system) or other 3rd generation systems, frequencies in the frequency band of approximately 2000 MHz are provided to distinguish between different signal sources at the location of the respective receiver using frequency division multiplexing (FDMA), time slot multiplexing (TDMA) and / or as code division multiplexing

(CDMA) and combinations of these known methods.

When transferring user information, there is always a difference between real-time services (RT - Real Time Services) and A distinction is made between non-real-time services (NRT). Real-time services are characterized by a constant occupancy of one or more physical transmission channels, so that the available transmission capacity is possibly only used to a certain percentage. An example of this is voice transmission: the transmission channel is also occupied during the pauses in speech, although there is effectively no information transmission. In contrast, non-real-time services are characterized by a segmentation of the information to be transmitted for individual data packets and a short-term occupancy of transmission channels for the transmission of one or more data packets. Internet services are a well-known example of a non-real-time service. This achieves a high level of utilization of the available transmission capacity, but in return only the currently available transmission capacity can be used. This leads, for example, to strong fluctuations in the transmission rate known from Internet applications, the transmission of the data packets possibly being postponed if transmission capacity is unavailable. In the case of Internet telephones, this can lead to delays in the transmission, as a result of which the subjective transmission quality is adversely impaired for the participants.

The future broadband radio communication systems will, in comparison to the known, narrow-band, GSM mobile radio system, offer the possibility of being able to provide individual services with a high transmission capacity. In addition to the exemplary real-time service of video transmission, this will be used in particular for the transmission of information from non-real-time services such as Internet applications. Due to the limited radio resources and transmission capacity of the radio However, the above-mentioned disadvantages of a delay in the transmission of information or only a small available transmission capacity can occur, especially with high traffic loads.

For this reason, a certain group of participants (so-called Premium Class Users) should have a certain quality of service (QoS - Quality of Service), which, for example, guarantees a certain bit error rate or a certain maximum transmission delay compared to normal participants (so-called.

Best Effort Users) of the radio communication system.

The invention is based on the object of specifying a method and a base station which enable a subscriber to have a certain quality of service when using a non-real-time service. This object is achieved according to the invention by the features of the independent claims. Advantageous refinements of the invention can be found in the respective subclaims.

According to the invention, a sum of information elements of a non-real-time service is transmitted between a base station and a radio station via a radio interface of the radio communication system within a specific time interval. The radio station determines transmission conditions of the radio interface and signals them to the base station. The base station then controls, depending on the transmission conditions determined, segmentation of the sum of the information elements to form at least one data packet and channel coding to add redundancy to the information elements, the control unit assigning a minimum number of physical transmission channels to the transmission of the data packet within the time interval be done. Controlling the segmentation of the sum of the information elements into at least one data packet and the channel coding in accordance with the invention advantageously enables a certain quality of service, such as, for example, a low bit error rate and transmission delay, while at the same time ensuring a specific transmission rate. The segmentation of the sum of the information elements to be transmitted into data packets has the advantage that if a data packet is transmitted incorrectly, this can be requested again, for example according to the ARQ process (Automatic Repeat on Request), without it being due to a large amount of information leads to an adverse delay in information transmission.

For example, the channel coding and segmentation can be controlled in such a way that, if the transmission conditions are good, a large number of information elements are combined into one data packet and only a small amount of redundancy is added to the information elements, since the probability of the data packet being requested again due to a fault during the Transmission via the radio interface is low. With good transmission conditions, the bit error rate can already be achieved with a low protective coding; in the case of poor transmission conditions, however, the protective coding must be increased, as a result of which the effective transmission capacity required is increased. The smallest possible number of assigned transmission channels has the advantage of lower utilization of the limited radio resources, as a result of which further subscribers have a greater transmission capacity available.

According to a first development of the invention, a channel coding and / or a convolution coding is used as the channel coding. carried out. These coding types are already from the

_G SM mobile radio system known. The block coding, also referred to as an outer error protection is so far used only for the _S prachubertragung and the calculation of parity is ritatsbits that enable detection of EME up in the transmission ^¬ occurred errors. The convolutional coding adds a redundancy to the information elements for possible error correction. The convolutional coding rate describes the ratio of the uncoded to the coded number of information elements. The smaller this ratio, the better a faulty information element can be corrected, a large amount of redundancy being advantageously avoided in view of the limited radio resources.

According to a second development, the radio station signals the number of information elements in the data packet and / or the rate of the channel coding by the base station. This enables the radio station to control the channel coding and / or the number of information elements per data packet for the transmission of information elements to the base station analogously to the base station.

According to a further development of the invention, a particular transmission time for transmitting the data packet is varied within the time period depending on the number of data packets. This advantageously makes it possible, for example, for the time interval to be divided into a number of respective transmission times for the data packets in accordance with the number of data packets, so that there is a uniform occupancy of the radio resources within the time period. As an alternative to this, it is also possible, for example, to dimension the transmission times for the data packets in such a way that, after the data packets have been transmitted, there is still sufficient time within the time valls is available in order to carry out a repeated transmission of one or more data packets when a fault occurs.

In further developments of the invention

The radio station is determined as the transmission conditions for each interference situation at the location of the radio station and / or at least for a characteristic value. This advantageously makes it possible, for example, to only assign physical transmission channels for the transmission of the data packet which have a low level of interference or a low bit error rate. As a result, the number of information elements combined to form a data packet can advantageously be increased and the additional redundancy reduced.

According to further refinements of the invention, a TDMA subscriber separation is carried out in the radio communication system. The radio station can determine a respective interference situation within the time slots and signal it to the base station. As a result, the base station can advantageously assign transmission channels, for example, to one or more time slots which have only a slight interference. In the event that transmission channels have already been assigned, an intercell handover can be initiated on the basis of the interference conditions determined, in which the time slots with the least interference interference are selected in each case for the assignment of transmission channels.

Exemplary embodiments of the invention are explained in more detail with reference to the accompanying drawings.

Show 1e block diagram of a radio communication system, in particular a mobile radio system,

2 shows a schematic representation of the frame structure of the radio interface and the structure of a radio block, FIG. 3 shows a schematic representation of the assignment of a data packet to physical transmission channels within a time interval,

4 shows three schematic representations corresponding to FIG. 3 with two data packets, FIG. 5 shows a schematic representation according to FIG. 3, with four data packets,

6 e e schematic representation according to FIG 5, with a changed rate of convolutional coding, and

7 shows three schematic representations of the assignment of data packets to physical transmission channels, two parallel non-real-time services being assigned to one subscriber.

The structure of the radio communication system shown in FIG. 1 and designed as an em mobile radio system corresponds to that of a known GSM mobile radio system, which consists of a large number 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 for the allocation of radio resources RNM. Each of these devices RNM in turn enables a connection to at least one base station BS. This base station BS is a radio station which can establish and initiate communication connections to mobile stations MS via a radio interface. The functional act of this structure is used by the method according to the invention.

1 shows, by way of example, a communication link for the transmission of information elements bit of a non-real time service servicel m data packets DPI shown between a mobile station MS and a base station BS. In the radio coverage area of the base station BS there is another mobile station MS, which in the case shown has not established a communication connection.

In order to illuminate the radio coverage area, the base station BS has at least one antenna device which, for example, consists of three individual radiators. Each of the individual emitters radiates in a sector of the supplied radio coverage area. However, a larger number of Emzelstahlers (according to adaptive antennas) can alternatively be used, so that spatial subscriber separation according to an SDMA method (Space Division Multiple Access) is also possible.

In addition to standard devices and components, the base station BS also has a transmitting / receiving device SEE for transmitting and receiving signals to / from radio stations. MS, which are located in the radio coverage area of the base station BS, and a control device ΞT according to the invention. In accordance with layer 2 of the ISO / OSI layer model, this control device ST pre-controls the number shown in FIG. 3 and FIG. 7. Information elements bit to at least one data packet DPI ... and a channel coding to add redundancy to the data packet (s) DPI ... In addition, the control device ST assumes the function of assigning physical transmission channels RU1 ... to transmit the data packet DPI .. via the radio interface to the radio station MS. The respective control takes place depending on the transmission conditions of the radio interface, which are determined by the radio station MS and signaled to the base station BS, and, if appropriate, on the current traffic load on the radio interface. By The parameters influenced by the control device ST can be signaled to the radio station MS in accordance with the corresponding signaling, as a result of which it is able to carry out a corresponding control analogously.

An exemplary frame structure of the radio interface can be seen from FIG. 2. According to a TDMA component, a division of a broadband frequency band, for example the bandwidth B = 5 MHz, is provided in a plurality of time slots ts, for example 16 time slots ts0 to tsl5. Each time slot ts within the frequency band B forms a frequency channel fk. Within a broadband frequency band B, the successive time slots ts are structured according to a frame structure. 16 time slots ts0 to tsl5 are combined to a time frame tf.

When using a TDD transmission method, part of the time slots tsO to tsl5 in the upward direction and part of the time slots tsO to tsl5 in the downward direction are used, the transmission in the upward direction taking place, for example, before the transmission in the downward direction. In between is a changeover point SP, which can be flexibly positioned according to the respective need for transmission channels for the up and down direction. In this case, a frequency channel fk for the upward direction corresponds to the frequency channel fk for the downward direction. The other frequency channels fk are structured in the same way.

Information of several connections m radio blocks are transmitted within the frequency channels fk. These radio blocks consist of sections with data d, in each of which sections with embedded training sequences tseql to tseqn are embedded. The data d are spread individually for each connection with a fine structure, a spreading code c (CDMA code), so that, for example, at the receiving end n Connections separable by this CDMA component s α.

The combination of a frequency channel fk and a spreading code c defines a physical transmission channel RU which can be used for the transmission of signaling and useful information.

The spreading of individual symbols of the data d with Q chips has the effect that Q subsections of the duration tchip are transmitted within the symbol duration tsym. The Q chips form the individual CDMA code c. Furthermore, a protection time gp is provided within the time slot ts to compensate for different signal propagation times of the connections of successive time slots ts.

The method according to the invention can also be used, for example, for TDMA methods known from the GSM mobile radio system or for CDMA subscriber separation methods, with the CDMA method only defining the transmission channel by means of frequency band B and a CDMA code , and there is a continuous transmission of useful and signaling information in the transmission channels.

FIG. 3 shows an assignment of physical transmission channels RU for the transmission of a first data packet DPI. The first data packet DPI, consisting of 1920 information elements, is intended to m four time frames tfl to tf4, which corresponds to a time interval T of 40ms in the 3rd generation UMTS radio communication system with a time frame duration tf of 10ms, via the radio interface to the radio station MS be transmitted. Based on the determined transmission conditions, for example with regard to the respective interference situation in the time slots ts for the transmission in the downward direction, the time slot ts10 for the assignment of physical transmission channels RU1 ... selected. Here, if only a small one

There is utilization of the transmission channels RU1 ..., one or more time slots ts are selected that have the most favorable interference conditions. If the transmission channels RU1 ... are heavily loaded, an intercell handover can be carried out before the assignment, the other radio stations MS supplied by the base station BS being allocated transmission channels RU1 ... in other time slots ts, so that, for example, for each radio - Station MS only the smallest possible number of time slots ts is provided or the respective interference situation in the time slots ts is approximately the same or constant.

Due to only a slight interference impairment in the selected time slot ts10, the channel coding is carried out in the form of a convolutional coding at the rate r = 1, the rate r = 1 meaning that no essential redundant information is added to the information elements bit of the first data packet DPI. In general, the folding coding is used for error correction, so that depending on the rate r of the folding coding, a certain number of incorrect information elements can be bit recognized and corrected. The channel coding can alternatively also be carried out by means of turbo coding. In addition to the convolutional coding, block coding, such as the CRC (Cyclic Redundancy Check) of the information elements bit, can be carried out, a block code consisting of parity check bits being calculated and bit being added to the sum of the information elements. This block code makes it possible to recognize that an error has occurred during the transmission via the radio interface. However, it is not always possible to correct errors. In the case of non-real-time services, the block code can be used, for example, to control a renewed request for the faulty first data packet DPI in accordance with the described ARQ method. In addition to the block coding, additional full bits are added to the information elements bit of the first data packet DPI so that the sum of the information elements bit to be transmitted corresponds to an integer multiple of the transmission capacity of a physical transmission channel RU1 .... In the example shown in FIGS. 3 to 7, 244 information elements can be transmitted bit by means of a transmission channel RU1 ... m a time slot ts.

The sum of the information elements to be transmitted is 1952 bits. These are each assigned to two transmission channels RU1, RU2 within the selected time slot ts10. The assignment of the information elements bit takes place in such a way that an even assignment of two

Transmission channels RU1, RU2 within the time frame tfl to tf4 of the time period T is given. As an alternative to this, it is also conceivable to assign four transmission channels RU1 ... the first two time frames tfl, tf2, o- by the possibility of repeated transmission m to the subsequent time frames tf3, tf4 in the event of interference during the transmission, and advantageously no transmission delay occurs. A disadvantage of the latter option is greater utilization to the disadvantage of further subscribers, since a larger number of transmission channels RU1 ... are assigned, which are assigned over the entire time frame tfl to tf4 of the time period T if faults have occurred.

Starting from FIG. 3, FIG. 4 shows a summary of the given number of information elements bit into two data packets DPI, DP2, each with 920 information elements bit. This can occur, for example, on the basis of a greater probability of a malfunction in the transmission via the radio interface, as determined by the radio station MS to be controlled. The rate r = 1 of the convolutional coding has, however, remained unchanged. Data packets DPI, DP2 with a smaller number of information elements bit have the advantage of a lower probability of a malfunction and a shorter time for retransmitting a respective data packet DPI, DP2 in the event of a malfunction, as a result of which the transmission delay is advantageously reduced compared to FIG. 3. In the example in FIG. 4a, the first data packet DPI is assigned to the transmission channels RU1, RU2 m the first two time frames tfl, tf2 of the time interval T and the second data packet DP2 is assigned to the same transmission channels m the last two time frames tf3, tf4 of the time interval T. The assignment of physical transmission channels RU1 ... is therefore not carried out separately for each data packet DPI, DP2, but together for the total sum of the information elements to be transmitted. This simplifies the assignment procedure and advantageously reduces the signaling load to the radio station MS.

FIG. 4b shows an example of a first alternative to the assignment of FIG. 4a, in which the information elements bit of the first data packet DPI four physical transmission channels RU1 to RU4 in the first time frame tfl, and the information elements bit of the second data packet DP2 four physical transmission channels RU1 are assigned to RU4 in the third time frame tf3. As a result, the respective data packet DPI or DP2 can be retransmitted in the subsequent time frame tf2 or tf4 in the event of a faulty transmission.

FIG. 4c shows a second alternative in which four physical transmission channels RU1 to RU4 are assigned to the first DPI or second data packet DP2 in the first tfl or second time frame tf2. Stand by this Within the time interval T, two time frames tf3, tf4 are subsequently available for possibly retransmitting one or both data packets DPI, DP2.

5 shows the segmentation of the sum of information elements bit m four data packets DPI, DP2, DP3, DP4 each with 480 information elements bit. After the convolutional coding described with the rate r = 1 and the block coding, the data packets DPI, DP2, DP3, DP4 are each assigned to the transmission channels Rül, RU2 in one of the time frames tfl, tf2, tf3, tf4 of the time period T. This segmentation of the sum of the information elements bit into a large number of data packets DPI, DP2, DP3, DP4 enables repeated transmission in the event of a fault, without the required transmission capacity being increased by additional redundancy. In comparison with FIGS. 3 and 4, it becomes clear that regardless of the size or the number of data packets DPI ... the required transmission capacity is advantageously constant.

FIG. 6 is based on the representation of FIG. 5 with a segmentation of the total information elements bit into four data packets DPI, DP2, DP3, DP4. A larger transmission capacity is required due to a changed channel coding in accordance with a changed rate r of the convolutional coding. The rate r = 1/3 of the convolutional coding describes the relationship between the net sum of information elements bit and the gross sum of information elements bit, which must be effectively transmitted via the radio interface. After block coding and a certain number of added full bits, six transmission channels RU1 ... RU6 must be assigned for the transmission of each data packet DPI, DP2, DP3, DP4, which corresponds to a tripling of the required transmission channels RU1, RU2 in the example of FIG. 5 . In addition to the two rates of convolutional coding mentioned, further Rates are used, which is selected depending on the transmission conditions determined in each case and with regard to the smallest possible number of physical transmission channels RU1 ... to be assigned. Furthermore, the gross sum of information elements bit should correspond to a whole multiple of a transmission channel RU1 ... if possible, in order to keep the number of full bits low.

7a and 7b show the effects of different channel coding on the utilization of the radio interface. The entire transmission channels Rül ... of the time slot ts10 are available to a subscriber as an example. In the example, the subscriber has set up two communication connections, each with a non-real-time service servicel, servιce2. According to the invention, the subscriber is assured of a certain transmission rate for the first Nic t real-time service, which can be, for example, voice communication over the Internet. As in the examples in FIGS. 3 to 6, this transmission rate corresponds, for example, to a net sum of 1920 information elements bit within a time period T of four time frames tfl to tf4. According to the example in FIG. 4a, the sum of information elements bit is segmented into two data packets DPI, DP2 in FIG. 7a, and each data packet DPI, DP2 at a convolutional coding rate of r = 1 in two transmission channels RU1, RU2 within two time frames tfl, tf2 or tf3, tf4 transmitted. The subscriber is therefore provided with six transmission channels RU3 to RU8 for the information transmission of the second non-real-time service servιce2, for example an Internet application. This second non-real-time service servιce2 is not guaranteed a specific transmission rate, which means that the throughput can change depending on the occupancy of the transmission channels. Such a change is shown in FIG 7b.

Due to an exemplary deterioration in the transmission conditions, greater redundancy is added to the information elements bit of the first non-real-time service servicel by a changed rate r = 1/3 of the convolutional coding, and the net sum of information elements bit m four data packets DPI, DP2, DP3, DP4 segmented. Due to the greater redundancy, a larger number of transmission channels Rül ... is required for the transmission of the gross total information elements bit, whereupon six transmission channels RU1 to RU6 m each are assigned to the time slot ts10 of the time frames tfl to tf4. With a maximum number of eight transmission channels RU1 to RU8, only two transmission channels RU7, RU8 are available for the information transmission of the second non-real-time service servιce2, which results in an effective reduction in the transmission rate for the second non-real-time service servιce2 Has.

Combinations of the individual examples in FIGS. 3 to 7 and an exemplary use of the invention radio communication systems, such as, for example, mobile radio or wireless subscriber access systems, with a subscriber separation method other than that shown are also conceivable.

Claims

claims 1. Method for the transmission of information elements (bit) in a radio communication system in which - a sum of the information elements (bit) of a non-real-time service (servicel) between a base station (BS) and a radio station (MS) a radio interface of the radio communication system is transmitted within a certain time interval (T), - transmission conditions of the radio interface are determined by the radio station (MS) and signaled to the base station (BS), - Depending on the transmission conditions determined, the segmentation of the sum of the information elements (bit) to at least one data packet (DPI ...) and channel coding for adding redundancy to the information elements (bit) are controlled by the base station (BS), the Control with regard to a minimum number of physical transmission channels (Rül ...), which are assigned for the transmission of the data packet (DPI ...) within the time period (T). 2. The method according to claim 1, in which a block coding and / or a folding coding is carried out as the channel coding, a rate (r) of Convolutional coding is varied depending on the determined transmission conditions. 3. The method according to the preceding claim, in which the number of information elements (bit) m the data packet (DPI ...) and / or the rate (r) of the channel coding to the radio station (MS) is signaled by the base station (BS) . 4. The method according to any preceding claim, in which a respective transmission time for the transmission of the data packet (DPI ...) within the time interval (T) is varied depending on the number of data packets (DPI ...). 5. The method according to any preceding claim, in which the radio station (MS) determines the respective interference situation at the location of the radio station (MS) as the transmission conditions of the radio interface. 6. The method according to any preceding claim, in which at least em characteristic value is determined by the radio station (MS) as the transmission conditions of the radio interface, the statement about a reception level, a bit error rate and / or the signal transit time between the base station (BS) and the Radio station (MS) proportional value and / or em signal-to-noise ratio includes. 7. The method according to any preceding claim, in which in the radio communication system a subscriber separation is carried out in accordance with a TDMA method, wherein a physical transmission channel (RU1 ...) is defined by at least the frequency band (B) and a time slot (ts) . 8. The method according to the preceding claim, in which the radio station (MS) as the transmission conditions A radio interface determines a respective interference situation in the time slots (ts) and signals it to the base station (BS). 9. The method according to the preceding claim, wherein the interference situation determined in each case the time slots (ts) from the base station (BS) for the assignment of the transmission channels (Rül ...) for the transmission of the data packet (DPI ...) m at least one time slot (ts) is taken into account. 10. The method according to any preceding claim, wherein the information transmission is carried out according to a TDD method, the transmission from the radio station (MS) to the base station (BS) and from the base station (BS) to the radio station (MS) being separated in time in the same frequency band (B). 11. The method according to any preceding claim, in which a subscriber separation is carried out in the radio communication system in accordance with a CDMA subscriber separation method, a transmission channel (Rül ...) being defined at least by a frequency band (B) and a connection-specific spreading code (c) . 12. Base station (BS) of a radio communication system for the transmission of information elements, with - A transceiver (SEE) for sending a sum of the information elements (bit) of a non-real-time service (servicel) to a radio station (MS) via a Radio interface of the radio communication system within a certain time interval (T), and for receiving signaled transmission conditions of the radio interface, which are determined by the radio station (MS), - a control device (ST) for controlling a segmentation of the sum depending on the transmission conditions determined of the information elements (bit) for at least one data packet (DPI ...) and for controlling a channel coding for adding redundancy to the information elements (bit), and for assigning a minimal one Number of physical transmission channels (Rül ...) for the transmission of the data packet (DPI ...) to the radio station (MS) within the time interval (T).