RU2328076C2 - Transmission control in radio communication system - Google Patents

Abstract

FIELD: data transfer.

SUBSTANCE: invention is related to control method in radio communication systems which provides for transmission of, at least, one control command from one to another radio station with transmission parameters individual for time intervals. Besides, the command is dynamically distributed along respective time interval changing from time frame (Subframe No i, Subframei+1) to time frame (Subframe No i+1, Subframe No i+2).

EFFECT: dynamic distribution of time intervals minimizes the longest interval between two control periods of time interval in ascending communication line.

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Description

The invention relates to a transmission control method in a radio communication system, and in particular, to a radio communication method and system for controlling synchronization and / or radiation power in a radio communication system.

In a radio communication system, for example, the second-generation European mobile radio communication system GSM (Global System for Mobile Communications), information (eg, speech, image information and other data) is transmitted via electromagnetic waves via electromagnetic communication interface. A radio interface refers to a connection between a base station (NB Node B) and a subscriber station (UE user device), wherein the subscriber stations can be, for example, mobile stations or fixed radio stations. The radiation of electromagnetic waves is carried out with the carrier frequency, which lies in the frequency range provided for the corresponding system. For future radio communication systems, for example, UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems, frequencies in the frequency range of about 2000 MHz are provided. For the third generation of mobile radio communications, two modes are provided, one of which is called the FDD mode (full duplex communication with frequency division of channels), and the other - the TDD mode (full duplex communication with time division of channels). These modes find application in correspondingly different frequency ranges. Both modes support the so-called CDMA subscriber separation method (code division multiple access).

As part of the 3GPP standardization of the UMTS system, the TDD mode is divided into a high-speed information transfer mode, the so-called high chip rate (TDD-HCR) option of 3.84 MHz / s, and a low bit rate mode, the so-called low chip rate (TDD-LCR), equal to 1.2 to 8 MHz / s. At the same time, the transmission level structure for the low-speed chip option is closely related to the so-called TD-SCDMA system standardized in China by CWTS.

In the version 1.28 MHz / s of the UMTS-TDD standard, both for synchronization of upstream transmissions (English: Uplink, UL), i.e. From subscriber stations to the base station, fast signaling at the physical transmission level (level 1 of the ISO / OSI level model) is also used to control transmission power. For example, when transmitting a base station in a downstream direction (English: Downlink, DL), the so-called SS (synchronization shift) and TPC (transmission power control) commands are introduced to the subscriber station, which affect the subsequent transmission of the subscriber stations in terms of synchronization and power transmission. In this case, for example, it is possible to signal the subscriber station that it should increase or decrease the transmit power by one step or that it should change the time control (synchronization) of the transmission in the upstream direction one step forward or backward in time. TPC commands are also appropriately transmitted from the mobile station in the upstream direction to signal to the base station that it should increase or decrease the transmit power by one step.

The correct interpretation of this command sent from the base station in the downstream direction, and the resultant response, is possible for the subscriber station only if there is an unambiguous connection of the command in the downstream direction with the corresponding time interval used by the subscriber station to transmit the signal in the upstream direction.

This relationship is defined in 3GPP standard 3GPP TS 25.221, V4.5.0 (2002-6), “Physical channels and mapping of transport channels to physical channels (TDD) (Release 4),” in chapters 6.2.2.2 and 6.2.2.3 (cf .Annex G). According to this method, from the available commands and a controlled number of time intervals of the upward direction, respectively, a pool is formed. Then the teams are distributed in turn at controlled time intervals for the upstream direction.

Figure 2 and figure 3 shows a corresponding example for this method. It is assumed that the subscriber station UE in the UL upstream direction within the subframe has two time slots UL1 and UL2 (indicated by an up arrow) for transmitting data and / or signaling information. From the measurements of the base station NB with respect to the reception of the uplink in these time slots UL1, UL2, the base station NB generates time synchronization commands SS1, SS2 (synchronization shift), which are individual for time slots, which in subsequent time slots of the downlink (indicated by an arrow pointing down ) are sent to the subscriber station UE. In the same way, transmission power control (TPC) command is not shown in this example.

According to a rule supported by the standard, the SS1 command in any subframe controls the timing for the uplink UL1, and the SS2 command always controls the timing for the uplink UL2.

Based on various mechanisms supported by the standard, such as the possibility of changing the coding or the so-called (rate matching), it may arise that the resources used to communicate with the subscriber station are temporarily not used or are disabled, for example, to reduce the interference effect on parallel transmissions data. In this case, if necessary, the code used for downstream transmission that transmits SS and TPC commands for the subscriber station UE can also be temporarily disabled. In this case, the synchronization and / or regulation of the transmission power in the corresponding time interval of the uplink for a corresponding period of time is not controlled until, for example, the data rate in the time interval of the downlink is increased again and the corresponding code is activated again, which will then again contain the corresponding commands or control information for the time interval of the uplink.

Figure 3 shows a corresponding example in which the data rate transmitted to the subscriber station has become so small that the time interval of the downlink, which previously carried the command SS2, is disabled for two subframes. As can be seen from FIG. 3, during these two subframes (subframe # i + 1 and subframe # i + 2), no SS2 command is transmitted to control synchronization in the uplink UL2 time slot. In the worst case, this can lead to an uncontrolled situation and a general deterioration in system performance.

A method for controlling transmission power of subscriber stations is known from WO-A1-99 / 49595, in which transmission power commands for a plurality of subscriber stations are combined into so-called transmission power control groups and transmitted in a common channel. The corresponding positions of the transmit power commands within the group can be changed in accordance with the sequence applied in the look-up table.

Therefore, the objective of the invention is to provide a method that provides reliable transmission of commands in these situations. This problem is solved using the method according to the characteristics of claim 1 of the claims. Preferred other embodiments of the invention are disclosed in the dependent claims.

The invention is explained below in more detail based on an example implementation. The drawings show the following:

Figure 1 is a block diagram of a radio communication system,

Figure 2 is a sequence of subframes with the transfer of commands according to the prior art,

Figure 3 is a sequence of subframes with an exemplary interruption of the downstream command transmission according to the prior art,

Figure 4 - sequence of subframes with the transfer of commands according to the method according to the invention,

5 is a sequence of subframes with an example of interruption in the transmission of commands in the downstream direction,

6 is a sequence of subframes for the known static method and dynamic method according to the invention,

7 is a table of correspondence of commands to time intervals of the reverse link according to the prior art, and

Fig. 8 is a correspondence table of instructions for time intervals of the reverse link according to the invention.

The above example of execution describes the transfer of commands in the downstream direction. However, the claimed method can be applied to transmit commands in the upward direction, from the mobile station to the base station. In the general case, we are talking about the transfer of commands from the first radio station to the second radio station.

Figure 1 as an example of a radio communication system shows a mobile radio communication system consisting of a plurality of mobile switching centers (MSC), which are related to the switching network (SSS) and are interconnected or create access to a fixed network (public switched telephone network - PSTN), and one or more MSC-related base station systems (BSS). The base station system has at least one device for allocating radio resources (radio network controller - RNC) and at least one associated base station NB (Node B). The base station NB, via a radio interface, can establish and disconnect connections with subscriber stations UE. Using each base station, at least one radio cell is formed. The size of the radio cell, as a rule, is determined by the range of the common signaling channel, which is transmitted from base stations NB with a correspondingly constant transmit power. In the formation of sectors or in hierarchical cell structures, each base station NB may have a plurality of radio cells Z. The functionality of this structure can be transferred to other radio communication systems in which the invention can be used.

Figure 1 shows the subscriber stations UE1, UE2, which are located in the radio cell of the base station NB. The subscriber stations UE1, UE2 have established communication connections with the base station NB, by which a signal of one or more selected services is transmitted in the upstream direction of the UL and in the downstream direction of the DL. Communication connections with the help of one or more spreading codes and / or time intervals allocated to the corresponding subscriber station are separated with respect to communication connections established in parallel in the radio communication cell.

4 illustrates a method according to the invention. In accordance with the invention, the above-described static mapping of the downlink time-slot transmitting the command to the corresponding time-spacing of the uplink is replaced by a randomly controlled and thereby dynamic mapping. This leads to the choice of the command belonging in the downlink time interval to the uplink time interval, for example, so that it is excluded that the control command, for example SS1, always controls the same uplink time interval (UL1 in FIG. 2 and 3). On the contrary, the distribution of commands in the downlink time slots is carried out in such a way that the corresponding control commands in the downlink time slots as uniformly as possible correspond to the time slots of the uplink. For this, in the example of FIG. 4, in each odd subframe, the assignment of control commands SS1, SS2 to the time intervals of the uplink UL1, UL2 is changed, and due to this, a uniform probability distribution of errors based on the obtained diversity is achieved.

When temporarily shutting down in the situation of FIG. 3 (or due to interference with the lack of command reception) of the second downlink time slot, both uplink time slots UL1, UL2 can be controlled with respect to synchronization using the corresponding commands SS1, SS2, which are alternately transmitted in the first downlink time interval.

The same is accordingly true for transmitting a command with respect to transmit power control (TPC).

Fig. 7 shows, by way of example, the distribution of three teams SS1, SS2, SS3 over three uplink time slots UL1, UL2, UL3 in accordance with the method prescribed by the standard. If in this case there is a case that the transmission of the SS3 command is interrupted, for example, due to the coordination of the transmission rates, then it is impossible to control the synchronization of the third time interval of the uplink UL3.

On Fig presents the distribution in accordance with the method according to the invention. In the event of an error or when the SS3 command is skipped, satisfactory control of the synchronization of all uplink time slots is possible in the future. Also, in the absence of two commands, the management of all relevant uplink time slots is still guaranteed. If all commands are passed on, diversity in the general case also leads to improved team protection.

FIG. 6 illustrates, by way of example, the distribution sequence of synchronization commands received from the subscriber station (received SS command #) over uplink time slots to be controlled (UL TS # control) depending on the system time frame number (SFN). The time frame is subdivided into two time sub-frames. In this example, two commands (0, 1) control the four time slots of the uplink (0, 1, 2, 3).

The upper drawing shows the static distribution according to the following formula in the current regulatory document TS 25.221, V 4.5.0:

UL _pos = (SFN ¹ .N _SSymbols + SS _pos ) mod (N _ULslot )

The lower drawing shows, on the contrary, the dynamic distribution according to the following formula according to the invention:

UL _pos = (SFN ¹ .N _SSymbols + SS _pos + ((SFN ¹ .N _SSymbols + SS _pos ) div (N _ULslot ))) mod (N _ULslot )

The definitions of the individual elements of the formula correspond to those used in the regulatory document.

As can be seen from the upper drawing, no control of the time interval of the uplink is performed if the command SS1 is not transmitted or received, for example, due to the coordination of speeds. With dynamic allocation according to the lower drawing, this undesired loss of control does not occur. The above formula for dynamic allocation preferably allows you to minimize the largest interval between two control periods of the time interval of the uplink communication. The size of the interval depends on the ratio between the number of commands and the time intervals of control. If there is the same number of commands and time slots to be controlled, then control is performed in each subframe.

The method described above can equally be used to control transmit power using TPC commands, as well as in the reverse direction of transmission.

Claims (4)

1. A transmission control method in a radio communication system in which a command is transmitted from a first radio station (NB) for controlling transmission parameters (SS) individual for time intervals to a second radio station (UE), the command being dynamically allocated to a corresponding time interval varying from a time frame ( Subframe # i, Subframe # i + 1) to the temporary frame (Subframe # i + 1, Subframe # i + 2). 2. The method according to claim 1, wherein, as a transmission parameter, the synchronization of transmission to the first radio station (NB) and / or transmission power for transmission to the first radio station NB is controlled. 3. The method according to claim 1 or 2, in which the dynamic distribution of the team in the time interval is carried out in accordance with a predetermined algorithm. 4. A radio station (NB, UE) of a radio communication system with means for transmitting at least one command for controlling individual transmission parameters for time intervals to another radio station (UE, NB) and for dynamically distributing the command to a corresponding time interval varying from a time frame (Subframe # i, Subframe # i + 1) to the temporary frame (Subframe # i + 1, Subframe # i + 2).

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