WO2004073203A1

WO2004073203A1 - Method for adjusting the transmission outputs of two channels of a link, station and communication system

Info

Publication number: WO2004073203A1
Application number: PCT/DE2003/004097
Authority: WO
Inventors: Hans Kroener; Stefan Oestreich
Original assignee: Siemens Aktiengesellschaft
Priority date: 2003-02-13
Filing date: 2003-12-11
Publication date: 2004-08-26
Also published as: DE10306170A1; AU2003293285A1

Abstract

Data (DAT) of the first link (V1) is simultaneously transmitted via two channels (CH1, CH2). The transmission outputs (P1, P2) of the two channels (CH1, CH2) are initially adjusted to different values. When alterations occur in the transmission output (P1) of the first channel (CH1), the transmission output (P2) of the second channel (CH2) is then modified in the same way.

Description

description

Method for setting the transmission powers of two channels of a connection, station and communication system

The invention relates to a method for setting the transmission powers of two channels of a connection, a corresponding station for a communication system and a communication system with such a station.

Data of a connection can be transmitted in a variety of ways between a transmitter and a receiver. The data transmission can, for example, be wired or via radio. With radio transmission, data is transmitted via an air interface using high-frequency carrier vibrations. Examples of radio transmission systems are the now widespread mobile radio systems, such as e.g. prevailing GSM (Global System of Mobile Communication) in Europe or the IS-95 system, which is particularly widespread in the USA.

To increase the data rate of a connection, it may be desirable to assign more than just one channel for the data transmission to the connection. Depending on the multiplex method used, the channels can either be a time slot of a time frame, a spreading code or a specific frequency, or a combination of these. According to the future UMTS-FDD (Universal Mobile Telecommunication Standard-Frequency Division Duplex) standard, intended primarily for Europe, the assignment of several channels to one connection is provided, for example. In this context, the question arises as to how the broadcasting power should be set for example for two channels of the same connection.

The invention is based on the object of specifying a method for setting the transmission powers of two channels of a first connection in a communication system.

This object is achieved with a method according to claim 1. Furthermore, this object is achieved by a station for a communication system and a communication system with such a station in accordance with the independent claims. Advantageous further developments of the invention are the subject of the dependent claims.

The method according to the invention provides that data of a first connection are transmitted simultaneously over at least two channels. In a first step, the transmission powers of the two channels are set to different values. Then, in a second step, when the transmission power of the first channel changes, the transmission power of the second channel changes in the same way. “In the same way means that the transmission powers of the two channels still have different values, but that when the transmission power of the first channel is reduced, the transmission power of the second channel is also reduced and that when the transmission power of the first channel is increased, the transmission power of the second channel is raised. In particular, the amount of change in the transmission power can be chosen to be the same for both channels.

The invention makes it possible to choose a common mechanism for setting the transmission power for both channels and yet individually on properties of the respective channel to be able to respond by selecting the transmission power required for the two channels by selecting different values of the transmission powers.

The invention is particularly suitable for use for connections within a third generation mobile radio system of the UMTS-FDD type. However, their application is not limited to this case and is rather also suitable for use in any other mobile radio systems and even other radio systems outside of mobile radio communication and for communication systems in which the data of the connection is not made via radio but by other means, for example line-bound , The only requirement for the application of the invention is that two channels are assigned to the first connection for simultaneous data transmission. Instead of radio transmission, transmission using other wireless transmission methods is also possible.

The invention can be used for any transmission direction of a connection. In particular, it can be used in mobile radio systems both for the downlink and for the uplink direction.

After a further development of the invention for the first

Channel regulates the quality of the data transmission by changing its transmission power. The transmission power of the second channel is then changed in the same way as the transmission power of the first channel. This makes it possible to regulate only one of the two channels in terms of its transmission quality by providing a corresponding control loop, while such a control loop is not necessary for the second channel, but rather only its transmission power in dependence is changed by the transmission power of the first channel. By providing only one control loop compared to providing separate control loops for each of the two channels, the method can be implemented with relatively little effort. In particular, the retransmission of measured values or control commands from the receiver to the transmitter, which is necessary in such a control loop, can be reduced, since with only one control loop this only has to be done for the corresponding channel and not for both channels.

The decision as to whether the transmission power of the first channel should be set higher than the transmission power of the second channel or vice versa can advantageously be made depending on which of the two channels is experiencing stronger interference. The transmission power of the channel with the stronger interference is then set higher than the transmission power of the other channel. “Interference *” means the influence of interfering signals on the transmitted signals at the location of the receiver.

For systems using channels that are formed by using a combination of scrambling codes and orthogonal spreading codes, the following situation exists: In the case of intracell interference, which is caused by transmissions via other channels within the same radio cell, the channels with the same scrambling code interfere due to the orthogonality of the spreading codes used theoretically not at all. In practice, however, the multipath propagation affects the orthogonality, which results in a so-called orthogonality factor between 0.06 and 0.4. The orthogonality factor indicates how a foreign channel interferes with a channel under consideration. Channels that different Using dice codes have an orthogonality factor with the value 1, which means that the reception power they cause at the receiver is to be considered in full as interference.

The quality of the data transmission can be regulated either for the channel with the stronger interference or for the channel with the weaker interference by changing the transmission power of this channel. The transmission power of the other channel is then the same as that

Transmitted power of this channel changes, while for him there is no regulation of the quality of the data transmission.

According to a development of the invention, the transmission power of the first channel is set lower or higher than the transmission power of the second channel by a certain difference, and the difference is changed during the operation of the first connection. The fact that the difference can be changed enables it to be adapted to changed conditions for transmission on the two channels, for example changed interference conditions at the receiver.

In particular, the value of a quality parameter of the data transmission can be determined for both channels and the difference can be changed depending on these values.

In order to increase the channels available for data transmission in a radio cell, it can be provided that data is scrambled with a first scrambling code before it is transmitted via the first channel and data is scrambled with a second scrambling code before it is transmitted via the second channel. A scrambling code is one preferably a relatively long sequence of bits with which the data bits intended for the transmission are multiplied (scrambled) bit by bit. Random sequences (PN, pseudo noise sequences) are preferably used as scrambling codes. Such scrambling codes are used, for example, in the downlink (this is the direction of transmission from the base station to the subscriber station) in UMTS-FDD.

If, in addition to the first connection, other connections are operated simultaneously, each with at least one

Have channel and their corresponding data are scrambled with a scrambling code before each transmission, the data to be transmitted of the first connection and the further connections before their scrambling are spread with spreading codes (spreading codes), channels being the same

Use scrambling code use different spreading codes, and more channels of the further connections are operated using the first scrambling code than using the second scrambling code, it is advantageous to set the transmission power of that channel of the first connection with the first scrambling code lower than the transmission power of the one Channel of the first connection with the second scrambling code.

The choice of orthogonal spreading code makes it possible to maintain the orthogonality of the spreading codes as far as possible using only one scrambling code and thereby achieve an optimal separation of the channels. However, if the spreading codes are used together with different scrambling codes, there are stronger interferences between channels despite the orthogonality of the spreading codes, which use different spreading codes but also different scrambling codes. The channels with the first Scrambling codes interfere despite the use of orthogonal ones

Spreading codes spread the channels with the other scrambling code far more than the channels with the same scrambling code interfere with each other. For this reason, there is greater interference for those channels associated with the scrambling code used by the relatively smaller number of channels than for the channels with the scrambling code used by a relatively larger number of channels.

This development of the invention is applicable to all CDMA transmission systems in which the frequency band used for the transmission is spread by means of spreading codes followed by scrambling.

The station according to the invention for a communication system and the communication system according to the invention have the means or devices necessary for carrying out the method according to the invention.

The invention is explained in more detail below on the basis of exemplary embodiments illustrated in the figures. Show it:

1 shows several connections within a mobile radio system,

FIG. 2 shows the time course of the transmission powers for two channels of a connection from FIG. 1,

FIG. 3 shows the structure of a mobile station from FIG. 1,

Figure 4 shows the structure of a base station from Figure 1 and Figure 5 shows the processing of data from different connections on the transmission side.

The invention is explained below on the basis of a third generation mobile radio system in accordance with the UMTS-FDD standard. However, it can also be used for other communication systems in which more than just one channel can be assigned to a connection. In particular, it is therefore applicable to any mobile radio system and to systems with any multiplex method. For the purposes of the invention, the channels can therefore optionally have different time slots of a time frame (TDMA), different frequencies (FDMA) or different spreading codes (CDMA), or combinations of these three channel properties. In the following exemplary embodiment, the channels are formed by a combination of a spreading code and a scrambling code.

Figure 1 shows the section of an individual radio cell of a mobile radio system according to the UMTS-FDD standard. A base station BS supplying the radio cell and three mobile stations MSI, MS2, MS3 are shown. The mobility of the stations is irrelevant to the invention. In other embodiments of the invention, they can therefore also be stationary subscriber stations. The base station BS maintains a connection VI, V2, V3 to each of the mobile stations MSI, MS2, MS3. In the following, only the transmission of data in the downlink (from the base station to the subscriber stations) is considered, although the invention can also be used for the reverse transmission direction (uplink) in other exemplary embodiments. The first connection VI is assigned two channels CH1, CH2 for the simultaneous transmission of the data. In contrast, only one channel CH3, CH4 is assigned to the second connection V2 and the third connection V3.

FIG. 5 shows the processing on the transmission side for the different connections VI, V2, V3 from FIG. The data DAT1 which are to be transmitted via the first channel CH1 of the first connection VI are first spread with a first spreading code SP1 and then scrambled with a first scrambling code SCI. The data DAT2 of the second channel CH2 of the first connection VI are also spread with the first spreading code SP1, but then scrambled with a second scrambling code SC2. The data DAT3 of the channel CH3 of the second connection V2 are spread with a second spreading code SP2 and scrambled with the first scrambling code SCI. The data DAT4 of the channel CH4 of the third connection V3 are spread with a third spreading code SP3 and scrambled with the first scrambling code SCI. Accordingly, channels CH1, CH3, CH4 with the same scrambling code SCI use different spreading codes SP1, SP2, SP3. In contrast, channels CH1, CH2, which use different scrambling codes SCI, SC2, can have the same spreading code SP1. In the present exemplary embodiment, more channels, namely the channels CH1, CH3 and CH4, use the first scrambling code SCI than the second scrambling code SC2, which is only used by the second channel CH2 of the first connection VI. Therefore, the channels CH1, CH3 and CH4 interfere with the second channel CH2 by interference more than the second channel CH2 interferes with the channels CH1, CH3 and CH4. The spreading codes SP1, SP2, SP3 used are namely orthogonal to one another in this exemplary embodiment. However, this orthogonality only works optimally in the sense of channel separation, provided the same scrambling code is used. On the other hand, when using different scrambling codes stronger interference between the channels with the first scrambling code and the channels with the second scrambling code.

FIG. 2 shows the course of the transmission powers P for the two channels CH1, CH2 of the first connection VI from FIG. 1 over time t. The transmission power P1 for the first channel CH1 has lower values than the transmission power P2 of the second channel CH2. This is because the interference at the mobile station MSI for the second channel CH2 is stronger than for the first channel CH1 for the reasons mentioned with regard to FIG. 5. When the first connection VI is established, the value of the transmission power P2 of the second channel CH2 differs from the transmission power Pl of the first channel CHl by a difference amount Dl. This difference amount is also maintained during changes in the transmission power values up to a point in time tl. At time tl, the interference conditions for the two channels CH1, CH2 of the first connection VI change. In the case considered here, the interference situation for the second channel CH2 is said to have deteriorated relative to the interference situation for the first channel CH1. For this reason, the difference D2 between the transmission power Pl, P2 of the two channels CH1, CH2 after the time tl is greater than before this time. The changed interference situation can be changed by moving the mobile stations MSI,

MS2, MS3 in the radio cell of the base station BS or by connecting additional channels that use the first scrambling code SCI.

In the exemplary embodiment considered here, the quality of the data transmission for the first channel CH1 of the first connection VI is regulated. In contrast, the quality of the data transmission for the second channel CH2 is not separately regulates. Rather, the transmission power P2 of the second channel

CH2 only changes in the same way as the transmission power Pl of the first channel CH1 changes due to the regulation of the transmission quality of the first channel CH1.

FIG. 3 shows the structure of the first mobile station MSI from FIG. 1. The function of the control loop for the quality of the data transmission of the first channel CH1 can be explained on the basis of FIG. A reception unit RX receives the data of the channels CH1, CH2. A device BER determines a bit error rate BER1 for the first channel CH1 and compares it with a target value BER _T. As a result of this target / actual comparison, a target value SIR _T for the signal-to-noise ratio of the first channel CH1 is determined at the first mobile station MSI. This is compared with the signal-to-noise ratio SIR1 of the first channel CH1 determined by a corresponding device SIR. A device TPC generates control commands TPC1 corresponding to this comparison result for the setting of the transmission power Pl of the first channel CH1. These control commands TPC1 are transmitted from a transmitter TX of the mobile station MSI to the base station BS. In addition to the actual value of the signal-to-noise ratio SIR1 for the first channel CH1, the device SIR also determines the current signal-to-noise ratio SIR2 for the second channel CH2 and transmits both to a device D. The device D determines the ratio of these the two signal-to-noise ratios SIR1, SIR2 the difference amount Dl, D2 from Figure 2. This is also transmitted from the transmitter TX to the base station.

As an alternative to determining the difference D1, D2 from the signal-to-noise ratios SIR1, SIR2, the determination can be carried out also take place from the ratio of the bit error rates BER1, BER2. This is indicated in FIG. 3 by the dashed arrow between the device BER and the device D. Furthermore, instead of determining the difference D1, D2 already in the mobile station MSI and then transmitting it to the base station BS, it is possible to determine the values of the signal-to-noise ratios SIR1, SIR2 or the values of the bit error rates BER1, BER2 from to transmit the mobile station MSI to the base station BS. The difference D1, D2 is then determined in the base station BS. As an alternative to FIG. 3, the difference D1, D2 can also be determined by comparing other quality parameters of the data transmission instead of the signal-to-noise ratios SIR1, SIR2 or the bit error rates BER1, BER2. For example, the frame error rate of the two channels CH1, CH2 could also be compared.

FIG. 4 shows the structure of the base station BS from FIG. 1. As with the mobile station MSI in FIG. 3, only the components essential for the invention are shown in FIG. 4 for the base station BS. A device DAT, which carries out the preprocessing on the transmission side explained with reference to FIG. 5, feeds the data DAT1, DAT2 of the two channels CH1, CH2 intended for the transmission to the first connection VI of a transmission device TX ^λ , which transmits it to the mobile station MSI via the air interface , The transmission of the data DAT1, DAT2 takes place with the transmission powers P1, P2, which are communicated by a unit PC for setting the transmission powers of the two channels CH1, CH2 to the transmission unit TX ^λ . A receiving unit RX ^Λ receives the

Control commands TPCl and the difference Dl, D2 from the mobile station MSI and forwards these to the power setting unit PC. The power setting unit PC changes the transmission power Pl of the first channel CH1 in accordance with the control commands TPC1. The control commands TPC1 signal the base station BS to either increase or decrease the transmission power Pl. The transmission power control unit PC adjusts the transmission power P2 of the second channel CH2 so that it corresponds to the value of the transmission power Pl of the first channel CH1, plus the difference D1, D2. Of course, only one value of the difference D1, D2 is transmitted from the mobile station MSI to the base station BS at the same time, namely the current value. Referring to FIG. 2, this means that before time t1 only the first difference D1 and after time tl the larger difference D2 is transmitted from the mobile station MSI to the base station BS. A transfer of the difference is only necessary if the value changes.

The interferences differ particularly strongly for the first channel CH1 and the second channel CH2 of the first connection VI, the more channels CH1, CH3, CH4 use the first scrambling code and the fewer channels CH2 use the second scrambling code SC2.

Compared to the separate regulation of the transmission quality for both channels of the same connection, the invention has the advantage that only one control circuit has to be implemented and the transmission power for the second channel CH2 only has to be changed in accordance with the changes in the transmission power of the first channel CH1. It is also advantageous over a solution in which only one of the two channels is subjected to regulation of its transmission quality and the transmission power of the other channel is set to the same value as that of the first channel. at In the latter solution, the transmission power for the second channel would either be too low or too high to achieve a sufficient transmission quality for the second channel. By setting the transmission powers of the two channels CH1, CH2 according to the present invention, on the other hand, it is possible to take into account different transmission conditions for the two channels CH1, CH2 of the first connection VI.

It is particularly favorable if, by deliberately choosing the total number of channels used for connections in the radio cell, it is influenced that as many of the channels as possible use the first scrambling code SCI and as few as possible the second scrambling code SC2. The first scrambling code SCI is in particular the code referred to as primary scrambling code in UMTS-FDD and the second scrambling code SC2 is the secondary scrambling code.

As an alternative to FIG. 3, the difference D1, D2 can, as already mentioned, also be determined in the base station BS. For this purpose, the transmission of the quality parameters required for determining the difference from the mobile station MSI to the base station BS can be provided. If the base station BS forwards these quality parameters to a central network device such as a base station controller, the difference can also be calculated by this central network device and then made available to the base station BS.

Again, alternatively, no transmission of the quality parameters from the mobile station MSI to the base station BS is necessary. Instead, the base station BS can estimate the parameters yourself. For example, it can determine the interferences approximately if it knows its own transmission powers on all channels. The orthogonality factor for each channel can be estimated from the received signal in the uplink (assuming similar relationships between uplink channels and downlink channels), or from the size or topology of the radio cell. The orthogonality factors can be set permanently or recurrently determined.

As an alternative or in addition to taking into account the quality parameters signal-to-noise ratio or bit error rate explained with reference to FIG. 3, other parameters can also be taken into account when determining the difference D1, D2, for example the propagation profile of the

Multipath of the connection under consideration, from which the orthogonality factors can be determined, the total reception power at the mobile station MSI, which corresponds in the first approximation to the interference for the second channel CH2 if significantly fewer channels are transmitted using the second scrambling code SC2 than using the first scrambling code SCI, or the total transmission power of the base station BS, which approximately corresponds to the intra-cell interference of the second channel CH2 under the same conditions.

Claims

claims

1. Method for setting the transmission powers (P1, P2) of two channels (CH1, CH2) of a first connection (VI), in which

data (DAT) of the first connection (VI) are transmitted simultaneously over both channels (CH1, CH2),

- First, the transmission powers (Pl, P2) of the two channels (CHl, CH2) are set to different values - and then when the transmission power (Pl) of the first channel (CHl) changes, the transmission power (P2) of the second channel (CH2) in is changed in the same way.

2. The method according to claim 1, in which - for the first channel (CHl) the quality of the data transmission is regulated by changing its transmission power (Pl),

- And the transmission power (P2) of the second channel (CH2) is changed in the same way as the transmission power (Pl) of the first channel (CH1).

3. The method according to any one of the preceding claims, in which

- one of the two channels (CH2) is exposed to stronger interference than the other channel (CHl) - and the transmission power (P2) of the channel (CH2) with the stronger interference is set higher than the transmission power (Pl) of the other channel (CHl) ,

4. The method according to claim 3, wherein - the quality of the data transmission for the channel (CH2) with the stronger interference or for the channel (CHl) with the weaker interference is regulated by the

Transmit power (P2; Pl) of this channel is changed,

- And the transmission power (Pl; P2) of the other channel (CHl; CH2) is changed in the same way as the transmission power (P2; Pl) of this channel (CH2; CHl).

5. The method according to any one of the preceding claims, in which

- The transmission power (Pl) of the first channel (CHl) is set by a certain difference (Dl, D2) lower or higher than the transmission power (P2) of the second channel (CH2)

- And the difference (Dl, D2) is changed during the operation of the first connection (VI).

6. The method according to claim 5, in which the value of a quality parameter (BER, SIR) of the data transmission is determined for both channels and a change in the difference (D1, D2) takes place as a function of these values.

7. The method according to any one of the preceding claims, in which for the first compound (VI)

- Data is scrambled with a first scrambling code (SCI) before it is transmitted over the first channel (CHI) - and data before it is transmitted over the second channel

(CH2) with a second scrambling code (SC2).

8. The method according to claim 7, in which - in addition to the first compound (VI), at the same time further connections (V2, V3) are operated, each with at least one channel (CH3, CH4), the corresponding the data are scrambled before each transmission with a scrambling code (SCI), the data to be transmitted of the first connection (VI) and the further connections (V2, V3) are spread with spreading codes (SP1, SP2, SP3) before being scrambled, whereby

Channels that use the same scrambling code (SCI, SC2) use different spreading codes,

- More channels (CH3, CH4) of the further connections (V2, V3) are operated using the first scrambling code (SCI) than using the second scrambling code (SC2)

- And the transmission power (Pl) of that channel (CHl) of the first connection (VI) with the first scrambling code (SCI) is set lower than the transmission power (P2) of that channel (CH2) of the first connection (VI) with the second scrambling code ( SC2).

9. The method according to any one of the preceding claims, wherein the data of the first connection (VI) are transmitted via an air interface.

10. The method according to claim 9, wherein the data of the first connection (VI) from a base station (BS) of a mobile radio system to a subscriber station (MSI) are transmitted.

11. Station (BS) for a communication system

with means (DAT, TX ') for simultaneously sending data of a first connection (VI) over at least two channels (CH1, CH2),

- And with means (PC) for setting the transmission powers

(Pl, P2) of the two channels (CHl, CH2) to different values, - Their means (PC) for setting the transmission powers (Pl,

P2) are designed so that when the transmission power (Pl) of the first channel (CH1) changes, the transmission power (P2) of the second channel (CH2) is changed in the same way.

12. Communication system with a sending station (BS) and a receiving station (MSI)

- whose sending station (BS) has means (DAT, TX ') for simultaneously sending data of a first connection (VI) over at least two channels (CH1, CH2) to the receiving station (MSI), the sending station ( BS) has means (PC) for setting the transmission powers (P1, P2) of the two channels (CH1, CH2) to different values,

- And in which the means (PC) for setting the transmission powers (Pl, P2) of the transmitting station (BS) are designed so that when the transmission power (Pl) of the first channel (CHl) changes, the transmission power (P2) of the second channel (CH2) is changed in the same way.