WO2000055985A1 - Method of controlling the output power in a radio communications system - Google Patents

Abstract

In a radio communications system, a characteristic value regarding the transmission conditions of the radio interface is detected and signaled to establish a communications link between a base station and a mobile radio station. Depending on the speed of the mobile radio station and/or the service transmitted in the communications link the characteristic value for the upward direction or the characteristic value for the upward direction and for the downward direction is taken into consideration to control the output power in the mobile radio station.

Description

description

Method for controlling the transmission power in a radio communication system

The invention relates to a method for transmitting power control in a radio communication system, in particular in a mobile radio system.

In radio communication systems, information 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, such as a base station or radio station. The electromagnetic waves are emitted at carrier frequencies that lie in the frequency band provided for the respective system. In GSM (Global System for Mobile Communication), which is known from J. Biala “Mobile Communications and Intelligent Networks ^x N Vieweg Verlag, 1995, among others, the carrier frequencies are in the range of 900 MHz, 1800 MHz and 1900 MHz. For future mobile radio systems with CDMA or TD / CDMA transmission methods via the radio interface, such as the UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems, frequencies in the frequency band of approximately 2000 MHz are provided.

In mobile radio systems that use a subscriber separation based on a known CDMA method, fast power control, in particular of the mobile radio stations, is necessary in order to ensure secure reception of all existing communication connections at the base station location with a simultaneous low interference interference from neighboring transmission channels. An arrangement for transmitting power control in a CDMA-based mobile communication system is known from EP 0 847 146 A2, in which the transmitting power is reduced in one direction, taking into account a transmission quality in the other transmission direction, in order to reduce the interference.

From WO 96/31014 AI a method for transmitting power control in a mobile communication system is known, in which the transmitting power of a mobile station is controlled by a base station according to the principle of a closed control loop. Here, speed information of the mobile station is taken into account for the control of the transmission power.

The invention is based on the object of specifying a method which enables flexible transmission power control. This object is achieved by the method according to the features of independent claim 1. Further developments of the invention can be found in the subclaims.

According to the method according to the invention, characteristic values relating to transmission ratios of the radio interface are determined and signaled periodically in a radio communication system for a communication connection between a base station and a mobile radio station. Depending on the speed of the mobile radio station and / or a service of the communication link, the characteristic values for the upward direction or the characteristic values for the upward direction and for the downward direction are alternatively taken into account for the transmission power control in the mobile radio station.

These methods advantageously enable fast transmission power control in the mobile radio station, for example in the case of a real-time service such as voice transmission and a low speed of the mobile radio station requires a fast transmission power control in order to enable secure reception of the base station. In this case, both the characteristic value for the upward direction and the characteristic value for the downward direction for the transmission power control are taken into account in the mobile radio station. In contrast, in a real-time service such as a video transmission (also referred to as LCD - Low Constraint Delay Service), which requires a comparatively high transmission capacity, and in an exemplary voice transmission at a high speed of the mobile radio station, only the characteristic value for the uplink direction can be used be considered for the transmission power control. Explicit signaling from the base station, which controls the transmission power of the mobile radio station, for example, via signaling messages, can advantageously be sought.

The methods according to the invention are used particularly advantageously in radio communication systems which additionally carry out a TDMA subscriber separation and, if appropriate, the information transmission in accordance with a TDD method. A common feature of these methods is that the time slot structure creates a respective time offset between the upward and the downward direction. As a result, rapid transmission power regulation by means of an explicit signaling described is not possible, or a maximum possible speed of the mobile radio station would be greatly reduced with regard to a sufficiently fast transmission power regulation.

According to advantageous developments, an interference situation is averaged as a parameter of the characteristic value over a first time interval. The determination can be carried out in the case of a described TDMA subscriber separation the interference situation is at least the time slots assigned to the communication connection. In the same way, a path loss, which represents a further parameter of the characteristic value, is averaged over a second time interval. By means of these averages, short-term transmission disturbances are advantageously relativized, as a result of which a more constant transmission power control is implemented.

The duration of the time intervals can be selected depending on the transmitted service in accordance with further developments, the respective duration being signaled, for example, from the base station to the mobile radio station. Furthermore, the first time interval can correspond to a nesting depth of the transmitted service, wherein different services can each have a different nesting depth. According to a further development, the second time interval is chosen to be shorter than the first time interval. As a result, the rapid transmission power control is advantageously achieved for the case of a slowly moving mobile radio station described by way of example if, for example, the path loss determined by the mobile radio station for the downward direction is taken into account for the transmission power control.

According to further developments of the invention, the mobile radio station additionally signals to the base station a transmission power which may have been averaged over the first time interval, as a result of which the path loss in the base station during transmission via the radio interface can be determined in the waiting direction. In the same way, the base station signals a transmission power to the mobile radio station, possibly averaged over the first time interval. As an alternative to this, the path loss for the downward direction transmission can be obtained from the mobile radio station by means of one from the base station with one of the mobile radio stations. Station known constant transmission power transmitted general signaling channel can be determined.

According to a further embodiment of the invention, a respective difference is signaled instead of absolute values of the parameters of the characteristic value, a respective absolute value being signaled when a connection is established and / or periodically. This advantageously simplifies the signaling and reduces the required transmission capacity. The periodic signaling of the absolute values ensures that a control deviation (offset) of the transmission power which arises, for example, due to temporary transmission disturbances can be corrected.

According to further developments of the inventions, a signal-to-noise ratio to be achieved is selected as a function of the transmitted service, a greater signal-to-noise ratio than for voice transmission for a secure reception being desired, for example, in the case of video transmission with a high transmission capacity. The signal-to-noise ratio to be achieved can also be signaled by the mobile radio station and / or by the base station when a connection is established and / or periodically according to a third time interval and taken into account for the respective transmission power control. Signaling is also conceivable when the service is changed or when a bit error rate is increased.

According to a further embodiment of the method according to the invention, the speed of the mobile radio station is determined by means of a time variation of the characteristic values. Depending on an exceeding or falling below a respective threshold value, different parameters for the transmission power control in the mobile radio station are taken into account according to the invention. A suitable dimensioning of the threshold values can be used to define a flexible and possibly adjustable switching hysteresis or a specific switching point for the change between the parameters.

According to a further development of the invention, reception is carried out in the base station and / or in the mobile radio station in accordance with a known joint detection method. This method advantageously enables a precise estimation of the interference situation in the radio cell of the base station or in the respective time slots of the communication link.

According to a further development of the invention, diversity reception is carried out in the base station and / or in the mobile radio station. It must be taken into account for the transmission power control and, if necessary, compensated for by signaling correction factors that a lower signal-to-noise ratio is required, and that in the case of diversity reception, for example, carried out only in the base station, the path loss in the downward direction and not the path loss in the upward direction corresponds.

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

Show

1 shows a block diagram of a radio communication system, in particular a mobile radio system, FIG. 2 shows a schematic representation of the frame structure of the

Radio interface and the structure of a radio block, FIG. 3 shows a flow chart of the method according to the invention, and 4 shows a further flow chart of the invention

Procedure.

The structure of the radio communication system shown in FIG. 1 and exemplarily configured as a mobile radio system corresponds to the 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 assigning radio resources RM. 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 trigger communication connections to further radio stations, which can be configured as mobile radio stations MS or stationary subscriber terminals, via a radio interface. The functionality of this structure is used by the method according to the invention.

1 shows, by way of example, a radio connection for the transmission of, for example, user data and signaling information between the base station BS and a mobile radio station MS, which is located in the radio coverage area of the base station BS and moves at a speed V.

An exemplary frame structure of the radio interface can be seen in FIG. 2. According to a TDMA component, a division of a broadband frequency band, for example the bandwidth B = 5 MHz, into a plurality of time slots ts, for example 16 time slots ts0 to tsl5, is provided. 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 structured according to a frame structure. In this way, 16 time slots ts0 to tsl5 are combined into a time frame tf, which has a duration of 20 ms, for example.

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. There is a switchover 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 is transmitted in radio blocks within the frequency channels fk. These radio blocks consist of sections with data d, in each of which sections with training sequences tseql to tseqn known on the reception side 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, n connections can be separated at the receiving end by this CDMA component. The combination of a frequency channel fk and a spreading code c defines a physical transmission channel that can be used for the transmission of signaling and useful information. For the transmission of user information, this physical transmission channel is also referred to as a traffic channel.

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, within the Time slot ts a protection time gp is provided to compensate for different signal propagation times of the connections of successive time slots ts.

3 and 4 each show an exemplary flow chart of the method according to the invention. The individual method steps in the mobile radio station MS are indicated on the left-hand side and the method steps in the base station BS on the respective right-hand side. The method steps are specified in a time sequence, but the individual steps can also be carried out, for example, in parallel or according to another time sequence. In the middle in each case, signaling via the radio interface between the mobile radio station MS and the base station BS is indicated, the chronological sequence of which can in turn be changed or which can be combined into a smaller number of signaling due to a signaling economy.

FIG. 3 shows a flow chart in which a transmission power Tms of the mobile radio station MS is regulated for a communication link with, for example, a voice transmission service. Both the mobile radio station MS and the base station BS each transmit data in the upward direction UL or in the downward direction, for example of a voice service, via the radio interface. For the respective transmission direction UL or DL, a characteristic value is periodically determined in the base station BS or in the mobile radio station MS, which provides information about the transmission conditions of the radio interface. Interference I, for example in one of the multiple time slots ts assigned to the communication connection, a signal-to-noise ratio C / I and a path loss PL are determined as parameters for the characteristic value. These parameters become the other radio station BS or MS signaled and evaluated in this. After the evaluation, a transmission power Tms is determined in the mobile radio station MS, which on the one hand realizes sufficient reception at the location of the base station BS, and on the other hand the lowest possible transmission power Tms for energy saving and for reducing interference in the radio cell of the base station BS. The transmission power can be regulated in the base station BS in the same way. The determined transmission powers Tms, Tbs are then signaled to the other radio station BS or MS.

As explained below in relation to FIG. 4, different parameters of the characteristic values for the transmission power control in the mobile radio station MS are taken into account depending on the speed V or the transmitted service.

4 shows an exemplary method according to the invention based on the flowchart in FIG.

The base station BS transmits a general signaling channel BCCH (Broadcast Control Channel) with a maximum transmission power at periodic intervals. This maximum transmission power is known a priori in the mobile radio station MS, so that it can determine a path loss PL [DL] for the downlink direction DL for the existing communication connection without explicit signaling of the current transmission power Tbs of the base station BS.

As a further distinguishing feature, instead of absolute values of the parameters I, C / I, PL of the characteristic values, only respective difference values d1, dC / I, dPL are signaled. This signaling has the advantage of a lower signaling load. However, at least one A one-off signaling of the absolute values can be carried out. Periodic signaling of the absolute values is furthermore advantageous in order to avoid a transmission malfunction due to a control deviation, for example due to a transmission malfunction.

After evaluating the signaled characteristic values, the parameters are averaged in the mobile radio station MS over a respective time interval t or tp, the interference I [DL] over a first time interval tm and the path loss PL [DL] over one second time interval tp can be averaged. The averaging advantageously relativizes short-term transmission interference and thus leads to a more homogeneous and constant transmission power control. The duration of the first time interval tm corresponds to the nesting depth of the transmitted service. In the case of a voice service, the nesting depth is, for example, two time frames tf corresponding to 20 ms. The duration of the second time interval tp is chosen to be shorter than the first time interval tm in order to enable fast transmission power control described below. The respective duration of the time intervals tm, tp can differ for different services, for example a respective signaling of the time intervals tm, tp to be taken into account is signaled by the base station BS. In the same way as in the mobile radio station MS, the parameters I [UL], PL [UL] are averaged over the time intervals tm, tp in the base station BS.

In addition to the current signal-to-noise ratio C / I [UL], C / I [DL] known due to the signaled characteristic value, the mobile radio station MS and the base station BS each generate a signal-to-noise ratio C / I [tgtUL], C / I [tgtDL] signals, the signaling for example when establishing a connection and periodic - the periodicity can be large compared to the first time interval tm.

As shown in FIG 4, the current speed V is determined in the mobile radio station MS. This determination can be carried out in the same way in the base station BS and the determined speed V can be signaled to the mobile radio station MS. The speed V is determined, for example, by means of a temporal variation of one or more parameters of the characteristic values, a rapid variation indicating, for example, a high speed V and a slow variation indicating a low speed V of the mobile radio station MS. The determined speed V is compared with an upper threshold value and, if exceeded, the parameters to be taken into account for the transmission power control are changed. In the same way, a comparison of the determined speed V with a lower threshold value is then carried out, and the parameters are changed again when the threshold value is undershot. The threshold values are dimensioned in such a way that optimum transmission power control is made possible in each case. A switching hysteresis or a specific switch point can be defined. Furthermore, the threshold values can be adapted individually to different services, the threshold values to be used in each case being known, for example, in the mobile radio station MS or signaled by the base station BS.

The effects of the determined speed V on the selection of the parameters to be used for the transmission power control are described below.

This is calculated for an exemplary voice service and a low speed V of the mobile radio station MS required transmission power Tms of the mobile radio station MS corresponding to:

Tms (1) - C / I [tgtUL] * / I [UL] * / PL [DL] (1)

with I: number of the time frame tf. Due to the necessary fast transmission power control, the mean path loss PL [DL] determined in the mobile radio station MS is taken into account for the downward direction DL. This value is available to the mobile radio station MS at any time or after a respective expiry of the second time interval tf m. Alternatively, the currently determined path loss PL [DL] can also be used. This advantageously means that there is no need to wait for signaling of the path loss PL [UL] determined and signaled by the base station BS for the waiting direction UL, which signaling is signaled periodically, for example, periodically in the first time interval tm by the base station BS. A faster reaction to variations in the transmission properties is thus possible.

With the exemplary voice service and a high speed V of the mobile radio station MS or with a service with a large required transmission capacity, such as, for example, video or multimedia transmission (so-called low-constraint delay services), the one determined by the base station BS is used and signaled mean path loss PL [UL] for the upward direction UL for the transmission power control. In the case of the services mentioned, fast transmission power regulation is dispensed with in order to ensure a constantly high transmission quality on the communication link. The average transmission power Tms of the mobile radio station MS is calculated accordingly:

/ Tms (l) = C / IttgtUL] * / I [UL] * / PL [UL] (l). The required transmission power Tbs of the base station BS is calculated in the same way, again taking into account parameters determined and signaled by the mobile radio station MS for the transmission power control. The average transmission power Tbs of the base station BS results from:

/ Tbs (i) = C / I [tgtDL] * / I [DL] * / PL [DL] (i).

If the bit error rate BER (bit error rate) deteriorates when data is received, the respective radio station MS, BS signals a higher signal-to-noise ratio C / I [tgtDL] or C / I [tgtUL] to be achieved, which has a direct influence on the regulation of the transmission power Tms, Tbs in accordance with the equations described.

Claims

claims

1. Method for regulating the transmission power in a radio communication system which uses a CDMA subscriber separation method in which - for a communication connection of at least one service between a base station (BS) and a mobile radio station (MS) periodically characteristic values (I [UL], PL [UL], PL [DL]) with respect to transmission ratios of the radio interface in the upward direction (UL) from the mobile radio station (MS) to the base station (BS) and in the downward direction (DL) from the base station (BS) to the mobile radio station (MS) are determined, the determined characteristic values (I [UL], PL [UL]) for the upward direction (UL) to the mobile radio station (MS) are signaled, and

- depending on a speed (V) of the mobile radio station (MS) and / or on the service of the communication link, the characteristic values (I [UL], PL [UL]) for the upward direction (UL) or the characteristic values (I [UL ]) for the upward direction (UL) and the characteristic values (PL [DL]) for the downward direction (DL) for the transmission power control in the mobile radio station (MS) are taken into account.

2. The method according to claim 1, wherein the determined characteristic values (I (DL), C / I (DL),

PL (DL) signals for the downward direction (DL) to the base station (BS) and is taken into account for the transmission power control in the base station (BS).

3. The method according to any preceding claim, in which an interference situation (I), a signal-to-noise ratio (C / I) and / or a path loss (PL) is determined as the characteristic value (I, C / I, PL).

4. Method according to a preceding claim, in which a real-time service is transmitted as a service.

5. The method according to claim 3 or 4, in which the interference situation (I) is averaged over a first time interval (tm), and the averaged parameter (/ I) for the transmission power control in the mobile radio station (MS) and / or in the base station (BS) is taken into account.

6. The method according to any one of claims 3 to 5, wherein the path loss (PL) averaged over a second time interval (tp), and the averaged parameter (/ PL) for the transmission power control in the mobile radio station (MS) and / or m of the base station (BS) is taken into account.

7. The method according to claim 5 or 6, wherein the duration of the first (tm) and / or the second time interval (tp) is selected depending on the transmitted service.

8. The method according to the preceding claim, in which the duration of the first (tm) and / or the second time interval (tp) to the radio station (MS) is signaled by the base station (BS).

9. The method as claimed in one of claims 5 to 8, in which a nesting depth of the transmitted service is used as the first time interval (tm), different services being nestable with a respective nesting depth.

10. The method according to any one of claims 5 to 9, wherein the second time interval (tp) is chosen to be shorter than the first time interval (tm).

11. The method according to any preceding claim, in which the mobile radio station (MS) additionally signals the current transmission power (Tms) to the base station (BS).

12. The method according to any one of claims 3 to 11, in which the path loss (PL [DL]) in the downward direction (DL) from the mobile radio station (MS) by means of a transmission power (Tbs) signaled by the base station (BS) or by means of a is determined by the base station (BS) periodically transmitted general signaling channel (BCCH).

13. The method according to claim 11 or 12, in which the mobile radio station (MS) and / or the base station (BS) additionally averages the respective transmission power (Tms, Tbs) over the first time interval (tm) and averages them Transmitting power (/ Tms, / Tbs) to the base station (BS) or to the mobile radio station (MS) is signaled.

14. The method according to any preceding claim, in which a respective difference between the determined characteristic value (dl, dC / I, dPL) and an absolute characteristic value (I, C / I, PL) is signaled, the absolute characteristic value Value (I, C / I, PL) is signaled when a connection is established and / or periodically.

15. The method according to any preceding claim, in which a signal-to-noise ratio (C / I [tgt]) to be achieved is selected as a function of the transmitted service.

16. The method according to claim 15, wherein the signal-to-noise ratio (C / I [tgt]) to be achieved in each case when a connection is established from / to the mobile radio station (MS) and / or periodically from the base station (BS) and / or is signaled by the mobile radio station (MS).

17. The method according to claim 15 or 16, wherein the signal-to-noise ratio (C / I [tgt]) to be achieved in each case is signaled by the base station (BS) and / or the mobile radio station (MS) when the service changes.

18. The method according to any one of claims 15 to 17, in which the signal-to-noise ratio (C / I [tgt]) to be achieved is increased when the bit error rate is increased and the increase to the transmitting base station (BS) or mobile radio station (MS) is signaled.

19. The method according to any preceding claim, in which the speed of the mobile radio station (MS) is determined by means of a temporal variation of the characteristic value (I, C / I, PL), and if an upper threshold value is exceeded, the characteristic value (I [ UL], C / I [UL], PL [UL]) for the upward direction (UL) and if the value falls below a lower threshold, the characteristic value (I, C / I, PL) for the upward direction (UL) and for the Downward direction (DL) is taken into account for the transmission power control.

20. The method according to any preceding claim, in which reception is carried out according to a joint detection method in the base station (BS) and / or in the mobile radio station (MS).

21. The method according to any preceding claim, in which diversity reception is carried out in the base station (BS) and / or in the mobile radio station (MS).

22. The method according to a preceding claim, in which subscriber separation is additionally carried out in accordance with a TDMA method, a physical transmission channel being defined by at least one time slot (ts) and a spreading code (c).

23. The method according to the preceding claim, in which the information transmission is carried out according to a TDD method, the transmission in the upward direction (UL) from the mobile radio station (MS) to the base station (BS) and in the downward direction (DL) from the base station (BS) to the mobile radio station (MS) takes place at different times in the same frequency band (B).

24. The method according to claim 22 or 23, in which the radio station (MS) and / or the base station (BS) determines the respective interference situation (I) in at least one time slot (ts) assigned to the communication connection.