DE10008058C1 - Preparation of a call forwarding between two radio communication systems - Google Patents

Abstract

To prepare a connection forwarding of a terminal device (MS) compatible with two radio communication systems (MSC1, RNC1, BS1; MSC2, RNC2, BS2) from a first of these radio communication systems (MSC1, RNC1, BS1) to the second (MSC2, RNC2, BS2) ), whereby at least in the first radio communication system (MSC1, RNC1, BS1) data is transmitted in successive frames divided into time slots, the terminal (MS) receives during certain time slots allocated to it of the first radio communication system (MSC1, RNC1, BS1) , referred to as downtime slots, signals of the second radio communication system (MSC2, RNC2, BS2) in order to obtain from these signals the information required for a call forwarding to the second radio communication system.

Description

The invention relates to a method for preparing a Connection forwarding (handover) one with different Radio communication systems compatible devices from one Radio cell of a first of these radio communication systems a radio cell of a second. The radio communication systems can be used for the same or different radio communications ons standards (e.g. GSM UTRA-TDD, UTRA-FDD,...) wherein at least the first radio communication system is a TDMA System is d. H. data in successive, in Time slots divided frame transmitted, the time slots within individual frames of individual devices be allocated. It also concerns one for such Process-compatible terminal and a radio communication system stem, which is adapted to such a method. The Erfin is especially for a call forwarding between digital mobile radio systems of the second and third Generation with different transmission methods bar.

In radio communication systems, information such as for example language, image information or other data with Using electromagnetic waves over a radio cut place between a transmitting and a receiving radio station, such as a base station or a Mo bilstation in the case of a mobile radio system. The electromagnetic waves are emitted with carrier frequencies that in the for the particular system provided frequency band. In the well-known GSM mobile radio system (Global System for Mobile Communication) the carrier frequencies in the range of 900 MHz, 1800 MHz and  1900 MHz. For future mobile radio systems with CDMA and TD / CDMA transmission method via the radio interface, such as for example UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems are carriers frequencies in the range of approximately 2000 MHz are provided.

Between the digital mobile radio systems of the second and third generation is said to be a problem-free connection circuit, especially at the beginning of the off build the third generation systems a complete Supply or coverage is not provided. Example initially only metropolitan areas with the system of third generation, whereas rural Areas continue to be exclusively on the mobile radio system systems based on the second generation. Accordingly, it becomes terminal devices at least in this initial phase give both the transmission process of the second genes ration, for example GSM, as well as one or more over Third generation transmission methods, for example TDD (Time Division Duplex) and / or FDD mode (Frequency Division Duplex).

Operates such a so-called multimode terminal Communication connection via a mobile radio system of the second Generation, it must have the ability to transfer properties of parallel existing mobile radio systems measure so that, if necessary, a call forwarding can be carried out to such a mobile radio system.

For TDMA (Time Division Multiple Access) communications systems such as GSM or UMTS (TDD mode) is the time in Frame divided, which in turn is divided into time slots are. Each terminal sends and receives within certain Time slots allocated to it by the system. Between The receiver can use two consecutive time slots  and transmitters of the terminal are used for other purposes, e.g. B. to listen to neighboring cells or base stations and this is the prerequisite for a possible connection circuit to another cell. The recipient ger of the terminal must ei at short notice on the frequency ner neighboring cell, leads to their Radio signal measurements and is then retuned.

This type of measurement is already used in the GSM system sets to measure the reception level of neighboring GSM cells. This measurement can be done at any time their duration is short.

A terminal device with two different radio communications is compatible with systems, while a transmission ver binding with a first system such as the GSM system stands, measurements on cells of the second system, for. B. the UMTS system, can perform, if necessary, the Ver Switch connection from the first to the second system can. Under "different radio communication systems" are ar here, for example, both according to the same standard processing systems from different network operators as well Understand systems working according to different standards.

To be able to switch to the second system NEN, the terminal must synchronize before the actual measurement Read station information of the second system. This reading requires a relatively long reception time, so the time span between two time slots allocated to the terminal of the first system may be insufficient for this. Moreover parts of this synchronization information, as in for example a frame number, only at fixed times in transmitted within a frame. With unfavorable time delays Relationships between the framework of the two radio communications systems, it may be impossible to have complete information  to read. If the frame duration of the second system is longer than that of the first, it can happen that the complete information between two consecutive times slots of the first system is not transmitted. There are it is called idle fra in GSM at periodic intervals mes in which no data is transmitted, so that in peri odic intervals a period of more than one frame period is available for measurements. This period is however already planned or strong for other measurements busy. If you have additional measurements in these idle frames carry out solutions on a second radio communication system wanted, the time interval between successive measurements can be increased significantly. If the temporal Distance between the conventionally in the idle frames measurements taken become too large, d. H. the measuring frequency too is small, but there is a risk that results of this Measurements for the system control are used, the out of date and possibly unusable.

EP 1 005 246 A2 describes a method for handing over of radio connections in TDMA-based cordless communication cation systems known in which a mobile station during egg ner radio connection with a first base station on a Time slot tried on at least one other time establish a radio connection with a second base station to manufacture.

WO 96/05707 A1 describes a method for connecting Switching between two radio communication systems knows, in which a terminal during a certain period of time mes communicated simultaneously via the two systems.

The invention has for its object a method for Preparation of a call forwarding from a radio cell of a first in a radio cell of a second radio comm communication system, a terminal and a radio communication system that allow the terminal device to be used for the Call forwarding needed information about that to win second radio communication system, and also the frequency of the operation of the terminal in which he most system required measurements.

This task is accomplished through the process, the end device as well the radio communication system according to the features of the unab pending claims solved. Further training of the Erfin can be found in the subclaims.  

Instead of the usual in every time slot assigned to him Receive signals from the first radio communication system, receives the terminal according to the invention during so-called Downtime slots signals from the second system. With that stands along with unallocated time slots before and after egg such a downtime slot an uninterrupted longer one Time available in which the required measurement conditions can be carried out.

According to a first embodiment of the method, this sends first radio communication system during such an out fall time slot further data to the relevant terminal, so to a certain extent ignores the downtime slot. This Design has the advantage that it does not apply to them adjustment for the first radio communication system. End devices that work according to this method can also use the already implemented mobile radio systems of the second Ge neration work together without additional inv stitions in these systems.

So that such a downtime slot does not cause any interruption or gaps in the transmission link, it is desirable It is worth noting that the terminal data that during an off fall time slot from the first radio communication system be reconstructed from data stored in the off fall time slot neighboring, assigned to this terminal Time slots are sent. For that it is especially with the Transmission of voice data or in general of data that are in Real time must be transmitted cheaply if that of the he Most radio communication system data sent before Sen which are nested block by block so that data loss, that from non-reception during the downtime slot does not result in a total loss of data for the Duration of an entire frame leads to a partial loss  over the duration of several frames by appropriate Error correction algorithms are easier to compensate for.

The higher the error correction, the better it is possible Reliability of the device before and after the failure time slot received data is. It is therefore preferred then a time slot is selected as the down time slot if the data to be transmitted in the downtime slot can be reconstructed with high probability.

In this context, it is advantageous if the terminal the transmission quality of the first radio communication system measures received data and a time slot as off Fall time slot selects when the measured quality is little at least one previous time slot ranges or exceeds.

In a second embodiment of the method, the Pro due to the interruption of reception and the necessary Error correction avoided by the fact that the first radio comm nication system during a downtime slot no data ten sends. To do this, the system must be aware of one before downtime slot. The system can stop set fall time slots yourself, e.g. B. after a pre level temporal pattern. In this case, it appropriately shares the impending downtime slot is coming to an end device with, so that at the time in question there is no data expected and also sends none. The information about the out Fall time slot can be used when decoding the transmitted data in the receivers of the end device as well as the system be taken into account and leads to a significant improvement transmission security.

The system can take the downtime slots even under time set slots proposed to him by the terminal  become. This approach has the advantage that it is the terminal allows flexible on results of previous measurements on the second radio communication system to react and z. B. egg propose a timeslot as a downtime slot in which it is the transmission of a frame number or another for synchronization with the second radio communication system required information expected. The first radio communication The onsystem system in turn likes its own under these suggestions Make a choice, or like any suggestion unconditionally accept. The latter alternative means that the power set a downtime slot, completely at the endge advises. In this case, the communication is one of the first downtime slot from the first radio communication system stem to the end device can be dispensed with, unless it serves as an acknowledgment of receipt for the proposal.

In a further development of the second embodiment, the is particularly suitable for the transmission of time-critical data such as voice data, it is contemplated that the first Radio communication system and the end device for each communication partner in close proximity to an outage fall time slot data to be transmitted and for the rest of transmitting data different radio transmission modes use with different transmission rates. During the Mode with the lower transfer rate may be sufficient is intended to be used in an operation without downtime slots to cope with falling data traffic, the mode with the higher transfer rate allow data that is actually would have been transmitted during the downtime slot to accommodate in other time slots. To the temporal shifts in data transmission before and keep as low as possible after a downtime slot, the mode with the higher transmission rate is preferred before and / or after a downtime slot and the Mode with the lower transfer rate while the rest  Time used. Instead of a higher transfer rate can also increase the compression ratio for voice data and thus the number of bits to be transmitted is reduced the.

In this further development, it is further preferred that a Communication partner the other an upcoming change signal from one of the radio transmission modes to the other in order to allow the other person to do so in time and errors in decoding the radio signal to avoid. The signaling communication partner be the one who also has the authority has to define a downtime slot; in this case can signal the upcoming change with the Notification of a defined downtime slot identical his. Conversely, the signaling communication part be the one who has no such authority; in In this case, the signaling of the upcoming change from the other communication partner as a confirmation be evaluated about the receipt of the message.

The two radio transmissions advantageously differ Modes in the data reduction ratios that are implemented a raw data stream in each case on the radio path transmitting data are used. Alternatively or in addition In addition, the two radio transmission modes can also be found under use different modulation methods. If the first Radio communication system is a GSM system, you can e.g. B. switch to EDGE (Enhanced Data Rate for GSM Evolution), or it can be switched from full rate to half rate coding be tested.

Since with the stronger data reduction mostly a certain information mation loss associated with voice transmission to a Increase in noise or decrease in bandwidth  of the acoustic spectrum can be more appropriate assign the radio transmission mode with the higher compression rate for only so many consecutive time slots apply as required to compared to the transfer mode with the lower data rate one time slot save.

The method according to the invention and the interaction with it the components of the radio communication systems and end devices are now closer to him based on graphic representations purifies. Show

Fig. 1 is a block diagram of two wireless Kommunikationssy Stemen, in particular mobile radio systems,

Fig. 2 is a flowchart of a first embodiment of the proceedings,

Fig. 3 schematically illustrates the structure of a terminal,

Fig. 4 shows the flow of a signaling procedure between ei nem terminal and a base station of the first radio communication system according to a second Ausgestal processing of the process, and

Fig. 5 is a flowchart of a second embodiment of the method

The mobile radio systems shown in FIG. 1 as an example of known radio communication systems each consist of a large number of network elements, in particular of mobile switching centers MSC, facilities RNC and base stations BS, network elements of the first system in the figure and the description below being appended Number 1 and those of the second system are identified by number 2 . The first system is, for example, a GSM system, the second a UMTS system.

Each system comprises a plurality of mobile switches lungsstellen MSC1, MSC2, of which, however, in the figure only one is shown, each within a system un are networked with each other and have access to a festival create the PSTN network. Furthermore, these are mobile switching represent MSC1, MSC2, each with at least one device RNC1, RNC2 to allocate radio resources ver bound. Each of these facilities RNC1, RNC2 enables how which is a connection to at least one base station BS1, BS1 'or BS2. Such a base station BS1, BS1 ', BS2 can a connection to end devices via a radio interface, e.g. B. mobile stations MS or other mobile and sta build up conventional end devices. The figure shows the simplicity for the sake of a single terminal MS that is able to choose wise with both the first and the second system to communicate. Between the terminal MS and a base station BS1 of the first system is a transmission ver binding, e.g. B. a call, symbolically Darge represents V1 as a double arrow.

At least one is transmitted through each base station BS1, BS1 ', BS2 Radio cell Z1, Z1 'and Z2 formed. With sectorization or in the case of hierarchical cell structures per base state tion BS1 also supplies several radio cells Z1. Radio cells Z1, Z2 of the different systems can geographically big overlap.

A respective operation and maintenance center OMC1, OMC2 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,  especially for subscriber access networks with wireless Subscriber connection.

Fig. 2 shows in the form of a flow chart the sequence of the inventive method according to a first embodiment. The first radio communication system here is a conventional GSM system, which must not be adapted to the procedure. As an example of a terminal MS, a highly schematic block diagram of a mobile phone is shown in FIG. 3. During an existing transmission connection to a GSM base station BS1, the terminal MS continuously checks the quality of the radio signal received from there. For this purpose, the terminal MS, as shown in Fig. 3, is equipped with a measuring circuit 1 , which monitors a received signal delivered by an RF transceiver module 2 for its quality by measuring the received field strength or the bit error rate (step S1). If the quality for a time slot assigned to the terminal or a plurality of successive time slots is better than a limit value (step S2), it can be expected that the data to be transmitted in the subsequent time slot can be reconstructed with a high degree of probability if this time slot fails. The measuring circuit 1 reports this to a control unit 3 . If necessary, the control unit 3 then defines the subsequent time slot as the downtime slot (step S3). This has the consequence that the stay on that frequency during the subsequent failure time slot immediately after reception of the prior reciprocating time slot on the frequency of the second radio kommmunikationssystems tuned RF transceiver module. 2 There is thus a period of time from the end of a time slot assigned to the terminal MS to the beginning of the next time slot assigned to it, in which the terminal can carry out measurements on the cell Z2 of the second radio communication system, which prepare a connection forwarding. For example, by measuring the reception field strength of cell Z2, the terminal MS can assess its suitability for handover in comparison with other cells of the first or second radio communication system (at which point in time it is still open whether a handover to this cell will take place or not ) or by preparing a frame number used by the base station BS2 and measuring a time offset between itself and the station BS2, prepare a connection forwarding that has already been decided.

Basically, several successive, the Terminal MS allocated time slots as downtime slots to be set if this is going to take lengthy Measurements is necessary.

During the downtime slot, the terminal can neither send nor receive on the frequency of the first radio communication system. The data that are received during a downtime slot from the RF transceiver module 2 do not originate from the base station BS1 and cannot be processed by the decoder 4 of the terminal. The latter therefore receives no data from the transceiver module 2 during the downtime slot and therefore has to reconstruct the data not received on the basis of data transmitted in previous and subsequent time slots. This is possible without too great a loss in quality if the signal sent by the base station BS1 is interleaved in blocks and the decoder 4 contains a deinterleaving circuit for restoring the original chronological order of the data.

Data supplied by encoder 5 during the downtime slot cannot be sent and is lost. In order to limit the loss of quality in the uplink transmission from the terminal MS to the base station, interleaving and deinterleaving of the data is also provided in the uplink.

After completing the measurements, the procedure can begin Return to point S0 if the measurements are only the current Monitoring the suitability of cell Z2 for a connection mode Switching served, or it can be a forwarding follow, if the measurements are to be forwarded required synchronization information was valid and successful were.

If the threshold of reception quality is not in step S2 the method returns to the starting point S0 return However, the limit can be reduced beforehand (Step S5), in particular if the limit value exceeds one larger number of time slots have not been reached and there is a risk of downtime slit is needed to make measurements, this measurement but cannot take place because there is no time slot is recognized as suitable. Through this dynamic adjustment the limit value is avoided that in a situation with poor reception quality in which a connection continues circuit may be required, this is not carried out can be carried out because for a long time no measurements on others Cells have been carried out and therefore not sufficient current information about reception quality in others Cells are available. Complementary to this measure the limit can also be increased if the Checking in step S2 the limit value is frequently exceeded and therefore the number of time slots that are considered potenti All downtime slots are viewed as actual Demand for downtime slots significantly exceeds.

Fig. 4 illustrates the sequence of a signaling process according to a second embodiment of the method.

As described above for the first embodiment, leads here the terminal MS regularly measures the reception quality of the signal coming from the base station BS1. The he results are transmitted to BS1, e.g. B. as RXLEV or RXQUAL values via MEAS_RES or MEAS_REP messages from the GSM Protocol if the first radio communication system is a GSM System is, however, with the peculiarity compared to the conventional GSM messages that they have information about Emp trapping qualities of base stations can include the egg nem second radio communication different from the GSM system on system.

The base station BS1 evaluates the measurement results, and if they have been better for a given number of time slots are as a limit, it sends a downtime slot on termination signal AAS to the terminal MS. In one variant the method, the base station BS1 can also if the limit has not been reached, however there is an urgent need for measurements, additional AAS-Si generate signals.

The terminal recognizes from the AAS signal that the base station no data in the subsequent time slot assigned to her will send (symbolized by the crossed out arrow DATA in the figure) and responds to it by while this time slot remains tuned to the BS2 to to carry out the measurements already mentioned at this station ren, shown here as an arrow SYNC from the base station BS2 to the MS terminal. At the same time, it interprets the signal AAS as an announcement that the base station BS1 after the end fall time slot for a limited time over another wear mode, and as a command, in turn the Do the same. So z. B. if the connection between Terminal MS and base station BS1 before the downtime slot was operated in full-rate mode, the base station BS1 and  the terminal MS the user data on the downtime slot send the following time slot in half-rate mode DATA-HR, um, even if the playback quality is somewhat impaired, Voice data corresponding to the duration of two GSM frames, to accommodate in a time slot and for the same time to switch their decoders to half-rate decoding decrypt the received data correctly. Then keh Ren terminal MS and base station BS1 for full-rate coding back.

The two transmission modes can also be used by the Differentiate modulation methods, e.g. B. can second method EDGE can be used.

If the second transmission mode is related to that to be transmitted raw or voice data is a factor x larger Transmission rate reached, you need a total of n = x / (x - 1) time slots transmitted in the second mode to the loss of transmission caused by a downtime slot balance time.

Also in the method explained with reference to FIG. 4, there is the possibility of reducing the limit value of the transmission quality, which must be exceeded so that a time slot can be considered as a selection time slot, if the current limit value does not find enough suitable time slots, or increase it if more suitable time slots are found than necessary. Since the results of the reception quality measurements are transmitted quantized from the terminal to the radio communication system in the form of the RXLEV or RXQUAL data, such an adjustment is only possible in rough steps in each case according to a quantization level.

A variant of the method now described with reference to FIG. 5 allows a finer adjustment in that the evaluation of the quality measurements is already carried out by the control unit 3 of the terminal, before it is quantized and transmitted to the first radio communication system. Steps S1 to S3 and S5 are therefore identical to those from FIG. 2. Only a message is transmitted to the system here, which indicates that the reception quality of the data blocks received in the last time slots was good enough so that a downtime slot can be inserted. The terminal thus proposes possible downtime slots to the radio communication system, and the latter decides in step S6 whether or not a downtime slot is required. For this decision, for example, information stored in the first radio communication system is taken into account, which indicates how long ago the last measurement was made on the second radio communication system and whether an update is due.

If the decision is positive, an AAS signal is sent to the terminal as described with reference to FIG. 4 (step S7), which also informs the terminal that the next time slot allocated to it is a failure time slot, as well the announcement implies that the base station will switch to a "faster" transmission mode after the downtime slot. The terminal performs the measurements on the second system during the next time slot (step S4), and the terminal MS and base station BS1 then use the "faster" transmission mode for a limited number of time slots (step S8) in order to avoid the downtime slot compensate for the transmission delay caused before the process returns to the starting point or the connection is forwarded if necessary.

If the decision is often negative, in Step S9 the limit is raised and the ver driving returns to the starting point.

In a further variant of the method, it is not only the responsibility the evaluation of the transmission quality (step S2), but also deciding whether to have a downtime slot is pushed (step S4), the terminal MS. To this end the end device itself has storage space for recording information regarding the topicality of the information provided by him measurement carried out on the second radio communication system Based on this information, it judges whether an out fall time slot is needed, and transmits to the base station tion BS1 a message that a downtime slot is closed can be used. The first radio communication system must now insert a downtime slot. It announces this like described above by the signal AAS. The reception of the Si gnals AAS through the terminal is a prerequisite for the fact that Terminal the next time slot actually as a failure time slot treated. The AAS signal is important here a confirmation that the first radio communication system has correctly received the message from the terminal. Remains this confirmation because the transfer conditions are bad (and the limit may be repeated times dyna mix has been reduced to a downtime slot could allow the insertion of a downtime sled zes by the terminal without the base station BS1 appropriate pause, easy to tear off the Connect.

Basically, all the options described are common sam that a downtime slot is only applied when needed will, d. H. if measurements are required and only can be made possible by a downtime slot.

Claims (19)

1. Procedure for preparing a connection scarf device with two different radio communication systems compatible (MSC1, RNC1, BS1; MSC2, RNC2, BS2) Terminal (MS) from a first of these radio communicati onsystems (MSC1, RNC1, BS1) for the second (MSC2, RNC2, BS2), at least in the first radio communication system stem (MSC1, RNC1, BS1) data in successive, in Time slots divided frames are transmitted at the the terminal (MS) during certain assigned to it Time slots of the first radio communication system (MSC1, RNC1, BS1), referred to as downtime slots, Signals of the second radio communication system (MSC2, RNC2, BS2) receives order from these signals for one Call forwarding to the second radio communication cation system to gain the information needed, and that first radio communication system (MSC1, RNC1, BS1) No data to the end due to a downtime slot device (MS) transmits. 2. The method according to claim 1, characterized in that the first and the second radio communication system after work to the same standard. 3. The method according to claim 1, characterized in that the first and the second radio communication system after different standards work. 4. The method according to any one of the preceding claims characterized in that the information is a synchro nization information includes.   5. The method according to claim 1, characterized in that the first radio communication system (MSC1, RNC1, BS1) defines the downtime slots and the end device (MS) announces in advance (AAS). 6. The method according to claim 5, characterized in that the first radio communication system (MSC1, RNC1, BS1) the downtime slots are pre-selected by the terminal (MS) time slots. 7. The method according to claim 6, characterized in that the terminal (MS) the quality of the in a time slot from the first radio communication system (MSC1, RNC1, BS1) received data measures (S1) and, if this quality ei a limit value is reached or exceeded (S2), one subsequent time slot the first radio communicati on system (MSC1, RNC1, BS1) as a downtime slot beats. 8. The method according to claim 7, characterized in that Bitfeh as a criterion for evaluating the quality rate or the reception field strength on the end device (MS) is turned. 9. The method according to claim 5, characterized in that the first radio communication system downtime slit according to a predetermined time pattern sets. 10. The method according to any one of claims 1 or 5 to 9, there characterized in that the first radio communication system (MSC1, RNC1, BS1) and / or the terminal (MS) for to the end device (MS) or the first radio communication system (MSC1, RNC1, BS1) in close proximity to one Downtime slot data to be transferred and for the rest  data to be transmitted different radio transmission modes with different transmission rates applies. 11. The method according to claim 10, characterized in that the first radio communication system (MSC1, RNC1, BS1) the terminal (MS) or the terminal (MSC1, RNC1, BS1) the first radio communication system (MSC1, RNC1, BS1) an upcoming switch between the two over wearing modes signaled (S7). 12. The method according to claim 10 or 11, characterized in net that the two radio transmission modes are different Apply data reduction ratios. 13. The method according to any one of claims 10 to 12, characterized characterized in that the two radio transmission modes under use different modulation methods. 14. The method according to any one of claims 10 to 13, characterized characterized in that the radio transmission mode with the higher data rate for so many consecutive times slots are used as required to be in the ver equal to the transmission mode with the lower data advise to save a time slot. 15. The method according to any one of the preceding claims, since characterized in that the two radio communications systems (MSC1, RNC1, BS1; MSC2, RNC2, BS2) a GSM system stem and a UMTS system. 16. Com with two different radio communication systems patible terminal (MS), whereby at least in the first radio Communication system (MSC1, RNC1, BS1) data in one subsequent frames divided into time slots are transmitted and the time slots each individual  End devices that are able to be assigned rend certain, called downtime slots Time slots of the first radio communication system Si signals of the second radio communication system (MSC2, RNC2, BS2) to receive from these signals for a Call forwarding to the second radio communication cation system to obtain the information required, whereby from the first radio communication system during one Downtime slot no data to the end device (MS) be transmitted. 17. Terminal (MS) according to claim 16, characterized in that that it is set up in an ongoing transfer connection data in different radio transmission modes with different transmission rates gene. 18. Radio communication system with at least one transmitter / Receiver station (BS1) for the transmission of data in successive frames divided into time slots men from and / or to a plurality of terminals, wherein the time slots are allocated to individual terminals and that is set up, the transfer of Data to a mobile device (MS) during certain time slots assigned to the terminal, as downtime slots designated to interrupt, and the setup is a downtime slot under from the terminal (MS) proposed time slots, where it no data on that during a downtime slot Terminal (MS) transmits. 19. Radio communication system according to claim 18, characterized ge indicates that it is set up to run in one the transmission link data in different radio transmission modes  with different transmission rates to send.