JP2001285193A - Transmission power control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission power control system that can keep desired communication quality as to each of channels even when using only one transmission control bit that is sent from a base station to a mobile station. SOLUTION: A control section 19 transmits a frame error rate(FER) set in advance for each of channels to an outer loop control section 16 (3), which receives a data error rate (CRC) for each of the channels via error correction decoders 15 (1)-15 (N), compares the data error rate with the preset frame error rate(FER) set in advance for each of the channels, and returns gain control information for each channel to the control section 19. The control section 19 transmits control channel data whose gain control information is superimposed on a control channel for each channel to a mobile station while applying time division multiplex of the control channel data onto a PC bit generated by a PC bit generating section 16 (2).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a transmission power control method in a CDMA communication system.

[0002]

2. Description of the Related Art In the uplink of a CDMA communication system, the distance between a base station and a mobile station greatly affects communication quality. A number of transmission power control schemes have been proposed to minimize the influence of the distance on communication quality. The most general method is described below. The base station receives a transmission signal from the mobile station and calculates a data error rate (hereinafter, referred to as CRC) and a signal power to interference power ratio (hereinafter, referred to as SIR).

[0003] The base station determines from the calculation result whether or not the uplink transmission power is appropriate. If the transmission power is greater than the desired power, the base station issues a transmission power reduction instruction to the mobile station, and if the transmission power is less than the desired power, the base station Sends an instruction to the mobile station to increase the amount of transmission power. The base station puts the PC bit instructing the up / down operation in one slot of the encoded data.
Bits were added and transmitted to the mobile station.

[0004]

In recent years, with the development of multimedia communication, it is required to transmit a plurality of channels from one mobile station. In such a case, according to the above-described conventional technique, since the number of PC bits transmitted from the base station to the mobile station is one, when a plurality of channels are transmitted from one mobile station, control of the transmission power amount for each channel is performed. Can not do. If setting is made such that a desired communication quality is obtained for a channel having the highest target SIR value, there is a problem that a channel having an excessive quality, that is, a channel having an excessive amount of transmission power is generated.

In this case, a method of transmitting a plurality of PC bits from a base station to a mobile station to control transmission power of a plurality of channels for each channel is conceivable, but there is a problem that transmission efficiency is reduced. Also, by using the PC bits in a time-division multiplexed manner, it becomes possible to control the transmission power of a plurality of channels for each channel. In this case, however, the control cycle becomes 1 / the number of channels, There is a problem that characteristics are deteriorated.

[0006]

The present invention employs the following structure to solve the above problems. <Structure 1> An SIR measurement unit that receives a part of a plurality of channel-multiplexed uplink received signals received by a base station from a mobile station and calculates a signal power to interference power ratio (SIR), and for each of the plurality of channels, A data error rate (CRC) is received from an error correction decoder arranged, a frame error rate (FER) is calculated for each of the plurality of channels, and a target frame error rate (F) preset for each of the plurality of channels is calculated.
ER), an outer loop control unit for obtaining and outputting gain control information for instructing the mobile station to increase or decrease the transmission power for each of the plurality of data channels,
The signal power to interference power ratio (SI
R), one of the gain control information selected from the outer loop control unit is received as a target signal power to interference power ratio (SIR), and the increase or decrease of the transmission power is indicated by 1 or 0 bits. A PC bit generation unit for generating PC bits to be transmitted, and the target frame error rate (FE)
R) is transmitted to the outer loop control unit, the gain control information for each of the plurality of channels is received from the outer loop control unit, and the gain control information is mounted on the control channel for each of the plurality of channels. A transmission power control method, comprising: a base station including a control unit for time-division multiplexing channel data with the PC bit and transmitting the multiplexed data to the mobile station.

<Structure 2> In the transmission power control method according to structure 1, the outer loop control unit receives a data error rate (CRC) from an error correction decoder arranged for each of a plurality of channels, and A FER calculator for calculating a frame error rate (FER) of the received data for each of the channels; a frame error rate (FER) of the received data for each of the plurality of channels; and a target frame preset for each of the plurality of channels. A transmission unit that receives and compares an error rate (FER) and generates the gain control information for each of the plurality of channels.

<Structure 3> In the transmission power control method according to Structure 2, the outer loop control unit receives the gain control information from the comparison unit and converts the gain control information into the target signal power to interference power ratio (SIR). And output target S
A transmission power control method comprising a base station including an IR update unit.

<Structure 4> A transmission gain calculator for calculating a gain or loss of a transmission signal by accepting a PC bit of 1 or 0 sent from a base station to a mobile station in order to increase or decrease transmission power, and a downlink control channel. A control unit that accepts data, separates and outputs gain control information for each of a plurality of channels,
A channel gain calculator that receives the gain control information from the controller and calculates and outputs the channel gain for each of a plurality of channels; and receives the channel gain from the channel gain calculator and transmits the channel gain for each of the plurality of channels. A channel gain adjustment unit that adjusts the gain, and a transmission gain adjustment unit that adjusts the transmission power amount of the uplink transmission signal sent from the mobile station to the base station by receiving the increase or decrease of the gain of the transmission signal from the transmission gain calculation unit. A transmission power control method, comprising:

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below using specific examples. FIG. 1 is a block diagram (part 1) of the configuration of the present invention. FIG. 2 is a block diagram (part 2) of the configuration of the present invention. FIG. 1 shows a configuration of a base station 1 of a transmission power control system according to the present invention, and FIG. 2 shows a configuration of a mobile station 2 of a transmission power control system according to the present invention.

The base station 1 includes an error correction code section 11, a spread modulation section 12, a signal multiplexing section (MUX) 13, a rake (RAKE) receiver 14, and an error correction decoder 15 (1).
To 15 (N), a transmission power control unit 16, and a control unit 19. Further, the transmission power control unit 16 includes an SIR observation unit 16 (1), a PC bit generation unit 16 (2), and an outer loop control unit 16 (3).

[0012] The mobile station 2 has error correction encoders 21 (1) to 21 (1).
21 (N), a spread modulation section 22, and a transmission gain adjustment section 2
3, a rake receiver 24, an error correction decoding unit 25, a transmission gain calculation unit 26, a control unit 27, a channel gain calculation unit 28, and a channel gain adjustment unit 29.
(1) to 29 (N).

The above configuration is only the configuration related to the transmission power control system according to the present invention, and the configuration of other components not directly related to the present invention is omitted. That is, in the downlink from the base station 1 to the mobile station 2, only the configuration of the control channel will be described, and in the uplink from the mobile station 2 to the base station 1, the configuration of only the data channel will be described. The configuration of the parts not directly related to the present invention is omitted.

The components of the base station 1 will be described with reference to FIG. The error correction encoder 11 encodes downlink control channel data transmitted from the base station 1 to the mobile station 2 based on a predetermined method. In the CDMA system, the number of subscribers can be increased by the coding gain by incorporating an error code into a part of the spread. That is, the number of subscribers can be increased by adopting a correction method having a large coding gain. Usually, a convolutional coding method or the like is adopted.

The spread modulation unit 12 includes a control unit 1 described later.
9, the mobile station 2 receives the downlink control channel data, spread-modulates it with a predetermined spreading code, converts it into electromagnetic waves, and
This is the part that sends it out. Signal multiplexing unit (MUX) 1
3 corresponds to P from the PC bit generator 16 (2) described later.
This is a part that accepts C bits and multiplexes the encoded control channel data received from the error correction encoding unit 11. This multiplexing usually employs a time division multiplexing method.

A rake (RAKE) receiver 14 is a part that combines and receives uplink reception signals arriving through a plurality of paths in a radio space interposed between the mobile station 2 and the base station 1. Normally, a signal arriving through a plurality of paths is received using a diversity antenna or the like, and is synchronously detected using pilot symbols to perform maximum ratio combining.

Error correction decoders 15 (1) to 15 (N)
Is a part that receives an uplink received signal from a rake (RAKE) receiver 14 and decodes the signal based on a predetermined decoding method. The multiplexed received signal is decoded for each channel, and further, a data error rate (CRC) for each channel is decoded.
Is measured and the outer loop control unit 16 described later is used.
This is also the part sent to (3). When the uplink received signal employs a convolutional coding method as a coding method, a soft decision Viterbi decoding method is usually used.

The SIR observation unit 16 (1) receives from the rake (RAKE) receiver 14 a part of an uplink reception signal in which a plurality of channels received by the base station 1 and multiplexed from the mobile station 2, and receives signal power versus interference. This is a part for calculating the power ratio (SIR) and sending it to the PC bit generation unit 16 (2) described later. Here, the signal power to interference power ratio (SIR) refers to the ratio of the energy of the received signal per bit of the uplink received signal received by the base station 1 from the mobile station 2 to the interference power plus the thermal noise power.

The PC bit generator 16 (2) sends the signal power to interference power ratio (SI
R), and the outer loop control unit 16 described later
From the gain control information calculated for each of the plurality of channels from (3), a specific one is set to a target signal power to interference power ratio (S
IR). Based on these two data, it is a part for generating a PC bit indicating increase or decrease of the transmission power by 1 or 0 bit and sending it to the signal multiplexing unit 13.

The outer loop control section 16 (3) receives the plurality of channels from the rake receiver 14 via error correction decoders 15 (1) to 15 (N) arranged for each of the plurality of channels. Accept the data error rate (CRC) every time. The frame error rate (FER) of the received signal is calculated from the data error rate (CRC). The calculation result is compared with a target frame error rate (FER) preset for each of a plurality of channels, and the base station 1 to the mobile station 2
This is a part for calculating gain control information for instructing an increase or decrease in transmission power for each of a plurality of data channels.

Next, the internal configuration of the outer loop control section 16 (3) will be described with reference to the drawings. FIG. 3 is a block diagram of a configuration of the outer loop control unit. From FIG. 3, the outer loop control unit 16 (3) includes the frame error (FER) calculation units 17 (1) to 17 (N) and the comparison unit 18
(1) to 18 (N), and a target SIR updating unit 20. A frame error (FER) calculation unit 17 (n) and a comparison unit 18 (n) are paired to correspond to each of a plurality of channels. Here, n = 1 to N.

The FER calculators 17 (1) to 17 (N)
From the RAKE receiver 14 (FIG. 1) via the error correction decoders 15 (1) to 15 (N) (FIG. 1), a data error rate (CRC1 to CRC1) is set for each of a plurality of channels of received data.
This is a part for receiving the CRCN) and calculating the frame error rate (FER) of the received data.

The comparison units 18 (1) to 18 (N) receive a frame error rate (FER) of received data for each of a plurality of channels and a frame error rate (FER) preset for each of a plurality of channels. This is a section for generating gain control information g1 to gN for each of a plurality of channels.

The target SIR updating unit 20 receives one of the gain control information g1 to gN and receives a frame error rate (FER) of the received signal and a target frame error rate (FE).
R), and if the frame error rate (FER) of the received signal is larger than the target frame error rate (FER), the target SIR is lowered, and the frame error rate (FER) of the received signal is reduced.
Is smaller than the target frame error rate (FER), the value of the target SIR is updated so as to increase the target SIR, and the PC bit generator 16 (2) (FIG. 1) is set as the target signal power to interference power ratio (SIR). This is the part that outputs to Here, as one of the gain control information g1 to gN, for example, a channel having the largest target frame error rate (FER),
A continuously transmitted channel is selected.

Returning to FIG. 1, the description of the configuration of the base station 1 will be continued. The control unit 19 sends a target frame error rate (FER) preset for each of the plurality of channels to the outer loop control unit 16 (3), and the outer loop control unit (3) transmits the target frame error rate (FER) for each of the plurality of channels. Accept gain control information. The gain control information is time-division multiplexed with the PC bits for control channel data mounted on the control channel for each of a plurality of channels and transmitted to the mobile station 2.

The configuration of the mobile station 2 will be described with reference to FIG. The error correction encoders 21 (1) to 21 (N) encode a plurality of uplink data channel signals to be transmitted from the mobile station 2 to the base station 1 (FIG. 1) for each channel based on a predetermined method. Part. In the CDMA system, the number of subscribers can be increased by the coding gain by incorporating an error code into a part of the spread. That is, the number of subscribers can be increased by adopting a correction method having a large coding gain. Usually, a convolutional coding method or the like is adopted.

The spread modulation section 22 is a section that receives an uplink data channel signal from channel gain adjustment sections 29 (1) to 29 (N), which will be described later, and performs spread modulation using a predetermined spread code. The transmission gain adjustment unit 23 is a unit that adjusts the gain based on the calculation result of the transmission gain calculation unit 26 described later to increase or decrease the transmission power amount of the uplink transmission signal.

The rake (RAKE) receiver 24 combines a downlink control signal arriving through a plurality of paths in a radio space interposed between the base station 1 (FIG. 1) and the mobile station 2 and receives the combined signal. It is. Normally, a signal arriving through a plurality of paths is received using a diversity antenna or the like, and is synchronously detected using pilot symbols to perform maximum ratio combining. Furthermore,
It is also a part that separates the PC bit transmitted multiplexed with the downlink control signal and sends it to the transmission gain calculator 26 described later.

The error correction decoding unit 25 outputs a rake (RAK)
E) A part for receiving a downlink control signal from the receiver 24 and decoding it into control channel data based on a predetermined decoding method. Further, the data error rate of the control channel data (C
RC) is measured and sent to the control unit 27 described later. When the downlink control channel data employs the convolutional coding method as the coding method, the soft decision Viterbi decoding method is usually employed.

The transmission gain calculator 26 determines that the RAKE receiver 24 has separated from the downlink control signal,
This is a part for receiving the PC bit of 1 or 0 and calculating the amount of increase or decrease of the gain of the transmission signal. That is, the transmission gain adjustment unit 2 based on the instruction (1 or 0) of the accepted PC bit.
3 is a portion for calculating to increase or decrease the gain of No. 3 by a predetermined amount and sending the result to the transmission gain adjusting section 23.

The control unit 27 receives downlink control channel data from the rake (RAKE) receiver 24 via the error correction decoding unit 25, and obtains gain control information for each of a plurality of channels mounted on the control channel data. Is a part that separates and outputs It is also a part that sends this gain control information to the subsequent channel gain calculator 28.

The channel gain calculator 28 receives the gain control information from the controller 27, calculates the channel gains (G1 to GN) for each of a plurality of channels, and follows the channel gain adjusters 29 (1) to 29 (29). This is a part for outputting to (N).

Channel gain adjusters 29 (1) -29
(N) adjusts the transmission gain of transmission data for each of a plurality of channels based on the channel gains (G1 to GN) received from the channel gain calculation unit 28, and
It is the part to send to.

Next, the operation of the transmission power control system according to the present invention will be described with reference to FIGS. As shown in FIG. 1, the number of uplink transmission data channels of the mobile station 2 is CH1 to C1.
The N channel of HN is used. The mobile station 2 converts the uplink transmission data of each channel into error correction encoders 21 (1) to 21 (1).
21 (N). The encoded uplink transmission data is gain-adjusted by channel gain adjusters 29 (1) to 29 (N) and then sent to spreading modulator 22. Here, they are spread-modulated and multiplexed. The multiplexing usually employs a multiplexing method using a multicode.

The multiplexed uplink transmission data is converted into an electromagnetic wave after the transmission power amount is increased or decreased by the transmission gain adjusting section 23 and transmitted to the base station 1 as an uplink transmission signal. Here, the transmission power amount is increased or decreased under the control of the transmission gain calculator 26 based on the PC bit transmitted from the base station.

In the base station 1, a rake (RAKE) receiver 14 rakes the upstream transmission signal. A rake (RAKE) receiver 14 separates and demodulates this uplink transmission signal into a plurality of channels and outputs error correction decoders 15 (1) to 15 (15) corresponding to each channel as uplink transmission data.
Send to (N). At the same time, a part of the uplink transmission signal is sent to the SIR measurement section 16 (1).

Error correction decoders 15 (1) to 15 (N)
Decodes the uplink transmission data, measures the data error rate (CRC1 to CRCN) for each channel, and sends the measurement result to the outer loop control unit 16 (3). The SIR measuring section 16 (1) receives a part of the uplink transmission signal from the rake (RAKE) receiver 14, and calculates a signal power to interference power ratio (SIR) of the received signal. The SIR measurement value, which is the result of this calculation, is sent to PC bit generation section 16 (2).

The PC bit generator 16 (2) compares the SIR measurement value received from the SIR measurement unit 16 (1) with the target SIR received from the outer loop control unit 16 (3). When the SIR measurement value is larger than the target SIR, the PC bit instructing to lower the transmission power amount of the mobile station 2 is set. It is generated and sent to the signal multiplexing unit (MUX) 13.

The outer loop control section 16 (3) determines the frame error rate of the received data for each channel based on the data error rates (CRC1 to CRCN) received from the error correction decoders 15 (1) to 15 (N). (FER1 to FER
N). Next, one channel, for example, channel n is selected from the plurality of channels, and the frame error rate (FER) of the received signal is compared with the target SIR. When the frame error rate (FER) of the received signal is smaller than the target SIR, Updates the target SIR value to increase the target SIR,
It is sent to PC bit generation section 16 (2).

As one channel selected from a plurality of channels, for example, a channel having the largest target SIR, a channel transmitted continuously, or the like is selected. For the remaining channels, the comparison units 18 (1) to 18 (N) (FIG. 3) compare the frame error rate (FER) of the received signal and the target SIR for each channel, and When the FER is smaller than the target SIR, the control unit 1 sets gain control information (g1 to gN) for each channel so as to increase the transmission gain of the channel.
Send to 9.

The control section 19 mounts the gain control information (g1 to gN) for each channel on the control channel data from the base station 1 to the mobile station 2 and sends it to the error correction coding section 11. This signal is encoded by the error correction encoding unit 11,
The signal multiplexing unit (MUX) 13 performs time division multiplexing with the PC bits. Thereafter, the signal is spread-modulated by the spread modulation unit 12, converted into an electromagnetic wave, and transmitted to the mobile station 2 as a downlink control signal.

In the mobile station 2, a rake (RAKE) receiver 24 receives a downlink control signal and separates PC bits. The control signal is sent to the error correction decoding unit 25, where it is decoded into control channel data and then sent to the control unit 27. The control unit 27 separates the gain control information (g1 to gN) for each channel from the control channel data and sends it to the channel gain calculation unit 28.

The channel gain calculator 28 calculates channel gains G1 to GN for each channel based on the gain control information (g1 to gN), and
9 (1) to 29 (N). On the other hand, transmission gain calculator 2
No. 6 raises or lowers the gain of the transmission gain adjuster 23 by a predetermined amount based on the received PC bit. As a result, the transmission power amount of the uplink transmission signal is increased or decreased.

Although not specified in the above description, the gain control information (g1 to gN) of each channel may be instructed to increase or decrease only the transmission power amount as 1-bit information similarly to the PC bit. Or a plurality of bits. That is, in the case of one bit, the mobile station 2 raises or lowers the transmission gain of each channel by a predetermined amount based on the instructions of the gain control information (g1 to gN). On the other hand, when a plurality of bits are used, if the number of bits is n bits, the update amount can be set to 2 (n-1) powers. As a result, the amount of increase or decrease is determined by the frame error rate (FER) of the received signal.
And the target frame error rate (FER), or the priority of transmission data, that is, the priority of a channel. Alternatively, both can be combined.

In the above description, only the transmission power control of the uplink transmitted from the mobile station to the base station has been described, but the present invention is not limited to this example. That is, the present invention can be applied to downlink transmission power control for transmission from a base station to a mobile station. Furthermore, in the above description, each component is configured individually, but the present invention is not limited to this example. That is, it is also possible to operate in accordance with a preset program by a microprocessor which is integrally formed by a logic LSI or the like and arranged inside.

[0046]

As described above, in a CDMA mobile communication system in which a plurality of channels are transmitted from a mobile station to a base station, a frame error rate (FER) of a received signal and a target frame error rate are provided for each of the plurality of channels. (FE
R) to generate control information for each channel.
By mounting this control information in the control channel data and transmitting it from the base station to the mobile station, the following effects can be obtained.
1. Even when there is only one transmission control bit from the base station to the mobile station, desired communication quality can be maintained in each of the plurality of channels. 2.
As a result, a channel for transmitting with excessive power can be eliminated, and an increase in interference power can be suppressed.

[Brief description of the drawings]

FIG. 1 is a block diagram (No. 1) of the configuration of the present invention.

FIG. 2 is a block diagram (part 2) of the configuration of the present invention.

FIG. 3 is a block diagram of a configuration of an outer loop control unit.

[Explanation of symbols]

 Reference Signs List 1 base station 11 error correction code unit 12 spreading modulation unit 13 signal multiplexing unit (MUX) 14 rake (RAKE) receiver 15 (1) to 15 (N) error correction decoder 16 transmission power control unit 16 (1) SIR observation Unit 16 (2) PC bit generation unit 16 (3) Outer loop control unit 19 Control unit

Claims (4)

[Claims] An SIR measuring unit that receives a part of a plurality of channel-multiplexed uplink received signals received by a base station from a mobile station and calculates a signal power to interference power ratio (SIR); Receives a data error rate (CRC) from an error correction decoder arranged at a plurality of channels, calculates a frame error rate (FER) for each of the plurality of channels, and calculates a target frame error rate (FER) preset for each of the plurality of channels. FER), an outer loop control unit for obtaining and outputting gain control information for instructing the mobile station to increase or decrease transmission power for each of the plurality of data channels, and outputting the signal from the SIR measurement unit. Power to interference power ratio (SI
R), and one of the gain control information selected from the outer loop control unit is accepted as a target signal power to interference power ratio (SIR), and the increase or decrease of the transmission power is indicated by 1 or 0 bits. A PC bit generator for generating a PC bit to be transmitted, and sending the target frame error rate (FER) to the outer loop controller, receiving the gain control information for each of the plurality of channels from the outer loop controller,
A base station including a control unit for transmitting the gain control information to the mobile station by time-division multiplexing control channel data loaded on the control channel for each of the plurality of channels with the PC bit, to the mobile station. Transmission power control method. 2. The transmission power control method according to claim 1, wherein the outer loop control unit receives a data error rate (CRC) from an error correction decoder arranged for each of a plurality of channels, and F for calculating frame error rate (FER) of received data for each channel
An ER calculation unit that receives and compares a frame error rate (FER) of received data for each of the plurality of channels and a target frame error rate (FER) preset for each of the plurality of channels, and And a comparing unit that generates the gain control information for each transmission power control method. 3. The transmission power control method according to claim 2, wherein the outer loop control unit receives the gain control information from the comparison unit and converts the gain control information into the target signal power to interference power ratio (SIR). A transmission power control method comprising a base station provided with a target SIR updating unit for outputting a target SIR. 4. A transmission gain calculator for receiving a 1 or 0 PC bit transmitted from a base station to a mobile station in order to increase or decrease transmission power and calculating an increase or decrease in gain of a transmission signal; A control unit that receives and separates and outputs gain control information for each of a plurality of channels; and a channel gain calculation unit that receives the gain control information from the control unit and calculates and outputs the channel gain for each of a plurality of channels. A channel gain adjustment unit that receives the channel gain from the channel gain calculation unit and adjusts the transmission gain for each of the plurality of channels; and a mobile station that receives the increase or decrease in the gain of the transmission signal from the transmission gain calculation unit. And a transmission gain adjusting unit for adjusting the transmission power amount of an uplink transmission signal transmitted from the mobile station to the base station. Power control scheme.