JP2001024581A - Method and device for constituting frame, transmission medium, control of transmission power, and radio station - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize reduction of transmission power and increase of capacity and to secure the required quality of control bits themselves by setting up the electric energy of the control bits to a value capable of minimizing the required transmission power of individual channels. SOLUTION: The method for constituting frames in a CDMA mobile communication system is provided with a step for determining the optimum electric energy of transmission power, a step for setting up the transmission power of control bits equal to that of data bits, a step for setting up the transmission power of the control bits to the optimum electric energy by adjusting the number of control bits, and a step for setting up the transmission power of control bits to the optimum electric energy by offsetting the transmission power of data bits. The optimum electric energy E0 is the electric energy of control bits capable of minimizing the required transmission power of the whole individual channel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frame configuration method, a frame configuration device and a transmission medium using the method, and more particularly to a transmission power control method, a transmission power control device and a radio station using the method.

More specifically, the present invention relates to a CDMA (Cod) for performing multiple access using spread spectrum.
e Division Multiple Accesses
s: code division multiple access) mobile communication, control bits are arranged together with data bits in a dedicated channel for controlling transmission power, and a desired signal received signal power to interference power ratio (SIR) for transmission power control is provided. The present invention relates to a frame configuration technique which can control and control power bits and data bits in an optimal power amount distribution when such measurements are performed using the control bits.

[0003]

2. Description of the Related Art FIG. 1 shows a state of interference from another mobile station on an uplink (from a mobile station to a base station). A mobile station MS1 near the base station BS1, a mobile station MS2 far from the base station BS1,
When the MS3 communicates at the same time, the base station BS1
While the signal power from the nearby mobile station MS1 is received high, the reception power from the distant mobile stations MS2 and MS3 is received low. Therefore, the distant mobile station MS2,
The communication between the mobile station MS3 and the base station BS1 is performed by a nearby mobile station MS1.
The characteristic is greatly deteriorated by the interference from the light receiving device 1.

[0004] In a downlink (from base station to mobile station), a distant mobile station is more affected by noise.
In particular, in the cellular system, since the interference from the base station of another cell is also increased, the characteristics are greatly deteriorated.

As a technique for solving these problems, transmission power control has been conventionally studied. In the transmission power control, the reception power received by the receiving station or a desired signal reception signal power to interference power ratio (SIR) determined from the reception power.
However, it is controlled to be constant irrespective of the location of the mobile station, whereby uniform communication quality can be obtained within the service area. Since the signal power of another communicator is an interference signal, it is necessary to perform transmission power control so that the signal power does not become significantly larger than the signal power of the own channel. For the uplink channel, each mobile station needs to perform transmission power control so that the reception SIR from each mobile station becomes constant at the reception input of the base station.

[0006] Transmission power control of the mobile station in the base station is as follows.
Conventionally, for example, this is performed as follows.

(1) The base station has a required SIR corresponding to a satisfactory reception quality of a signal from a certain mobile station.
Set.

(2) The base station measures the reception SIR of the signal transmitted from the mobile station.

(3) The base station determines whether the received SIR of a signal from the corresponding mobile station is larger or smaller than the required SIR.

(4) The base station periodically inserts a transmission power control bit corresponding to the determination result into the frame of the downlink signal, and transmits the transmission bit to the mobile station using the transmission power control bit. Specify increase or decrease of power.

[0011] The same operation is performed on the downlink channel as in the uplink channel. Specifically, (1) the mobile station sets a required SIR corresponding to a satisfactory reception quality of a signal from the base station.

(2) The mobile station measures the reception SIR of the signal transmitted from the base station.

(3) The mobile station determines whether the received SIR of the signal from the corresponding base station is large or small with respect to the required SIR.

(4) The mobile station periodically inserts a transmission power control bit corresponding to the determination result into the frame of the uplink signal, and transmits the transmission power control bit to the base station using the transmission power control bit. Specify increase or decrease of power.

FIG. 2 shows an example of a frame structure of an individual channel in a CDMA mobile communication system according to the prior art.

As shown in FIG. 2, a control bit portion 22 indicating control information such as a transmission power control bit and a rate identification bit is arranged in the dedicated channel 20 together with a data bit portion 24 indicating user information. I have. The control bit portion 22 and the data bit portion 24 are collectively referred to as a frame.

FIG. 3 shows the relationship between the power amount of the control bits and the bit error rate of the control bits.

[0018] In Figure 3, the amount of power in one frame that satisfies the required quality of control bits indicates that the E _1.
In the related art, when a control bit is allocated in a frame, the control bit is arranged in an individual channel with an amount of power that satisfies the required quality of the control bit itself (for example, E _{1 in} FIG. 3).

[0019]

Since the control bits are always transmitted unlike the data bits in which the number of transmission bits and the transmission power can change sequentially with the change in the speed of the user data, the control bits are used for controlling the transmission power. It may be used for SIR measurement.

FIG. 4 shows the amount of control bit power per frame when SIR measurement is performed using control bits.
4 shows a relationship between required transmission power of an individual channel. Here, the required transmission power of the dedicated channel refers to the transmission power obtained by combining the control bits and the data bits so as to satisfy the required quality of the data bits.

As shown in FIG. 4, when the control bits are used for SIR measurement, as the power amount of the control bits is increased, the SIR measurement accuracy is improved and the transmission power control can be performed with high accuracy. Although the required transmission power of the dedicated channel can be reduced, if the power amount of the control bits is increased more than necessary, the transmission power of the entire dedicated channel increases.

Therefore, there is an optimum point of the power amount of the control bit so as to minimize the required transmission power of the dedicated channel. For example, in FIG. 4, E ₀ is the optimum power amount.

However, conventionally, as described above, the control bits are arranged and transmitted with a power amount (for example, E _{1 in} FIG. 3) that satisfies the required quality of the control bits.
If the power is less than E ₀ in FIG.
There has been a problem that the accuracy of the R measurement is deteriorated, which causes an increase in transmission power and a deterioration in capacity.

Therefore, the present invention reduces the power amount of the control bit by
By matching the required transmission power of the dedicated channel to the lowest point, the control bit and the data bit have a frame configuration that optimizes the power distribution, thereby realizing a reduction in transmission power and an increase in capacity. The purpose is to make the quality of the control bits themselves equal to or higher than the required quality.

[0025]

According to one aspect of the present invention, there is provided a method for configuring a frame in a CDMA mobile communication system, the method comprising: determining an optimum amount of power to be allocated to control bits. And, making the transmission power of the control bits equal to the transmission power of the data bits, and adjusting the number of bits of the control bits to make the transmission power amount of the control bits the optimum power amount. It is characterized by having.

According to a second aspect of the present invention, there is provided a method for configuring a frame in a CDMA mobile communication system, comprising the steps of: determining an optimum amount of power to be allocated to control bits; and providing an offset to transmission power of data bits. Setting the transmission power amount of the control bits to the optimum power amount.

According to a third aspect of the present invention, in the frame configuration method according to the first or second aspect, the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. It is characterized by being.

According to a fourth aspect of the present invention, there is provided a frame configuration apparatus in a CDMA mobile communication system, comprising: means for determining an optimum amount of power to be allocated to a control bit; And means for adjusting the number of control bits so that the transmission power amount of the control bits is set to the optimum power amount.

According to a fifth aspect of the present invention, there is provided a frame forming apparatus in a CDMA type mobile communication system, comprising: means for determining an optimum amount of power to be allocated to a control bit; and providing an offset to a transmission power of a data bit. Means for setting the transmission power amount of the control bit to the optimum power amount.

According to a sixth aspect of the present invention, in the frame configuration apparatus according to the fourth or fifth aspect, the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. It is characterized by being.

According to a seventh aspect of the present invention, there is provided a transmission medium in a CDMA mobile communication system, comprising: a data bit having a transmission power equal to a transmission power of a control bit;
And the control bits, the number of bits of which is adjusted so as to obtain an optimum amount of power.

The invention according to claim 8 is a transmission medium in a CDMA mobile communication system, wherein an offset is given to transmission power of data bits,
It is characterized by including a control bit for setting the transmission power amount to the optimum power amount.

According to a ninth aspect of the present invention, in the transmission medium according to the seventh or eighth aspect, the optimum power amount of the control bit is a power amount that minimizes the required transmission power of the entire dedicated channel. There is a feature.

According to a tenth aspect of the present invention, in the transmission medium according to any one of the seventh to ninth aspects, the control bits include a bit sequence corresponding to a result of comparison between reception quality and required quality. It is characterized by.

An eleventh aspect of the present invention is the transmission medium according to any one of the seventh to tenth aspects, wherein the transmission medium is a transmission signal.

According to a twelfth aspect of the present invention, in the transmission power control method, the first wireless station measures a reception quality of a signal transmitted by the second wireless station, and the measuring step includes: Comparing the measured reception quality with the required quality; generating a bit sequence corresponding to a comparison result of the comparing step; and generating a control bit including the bit sequence generated by the step of generating the bit sequence. And determining the optimal amount of power to be allocated to the control bits; equalizing the transmission power of the control bits to the transmission power of the data bits; and adjusting the number of bits of the control bits to achieve the control. Setting the transmission power amount of bits to the optimum power amount; and Comprising a step of configuring a frame including the control bits having the optimum power amount, and a step of transmitting the frame to the second wireless station, and transmitting the frame by the transmitting step at the second wireless station. Receiving the frame, and adjusting transmission power based on the bit sequence included in the frame received in the receiving step.

According to a thirteenth aspect of the present invention, in the transmission power control method, the first wireless station measures a reception quality of a signal transmitted by the second wireless station, and the measuring step includes: Comparing the measured reception quality with the required quality; generating a bit sequence corresponding to a comparison result of the comparing step; and generating a control bit including the bit sequence generated by the step of generating the bit sequence. And the step of determining an optimal power amount to be allocated to the control bits, and by giving an offset to the transmission power of the data bits, the transmission power amount of the control bits, the step of the optimal power amount, Configuring the frame including the control bit determined as the optimum power amount by the step of setting the optimum power amount. And transmitting the frame to the second wireless station, and receiving at the second wireless station the frame transmitted by the transmitting step; receiving by the receiving step Adjusting the transmission power based on the bit sequence included in the frame.

According to a fourteenth aspect of the present invention, in the transmission power control method according to the twelfth or thirteenth aspect, the optimum power amount of the control bit is a power that minimizes a required transmission power of the entire dedicated channel. Characterized in that it is a quantity.

The invention according to claim 15 is a radio station, comprising: means for measuring reception quality of a received signal; means for comparing reception quality measured by the measurement means with required quality; Means for generating a bit sequence corresponding to the comparison result of the means for generating, a means for generating a control bit including the bit sequence generated by the means for generating the bit sequence, and determining an optimum amount of power to be allocated to the control bit. Means, means for making the transmission power of the control bits equal to the transmission power of the data bits, and means for adjusting the number of bits of the control bits so that the transmission power amount of the control bits is the optimum power amount. Means for constructing a frame including the control bits which have been set to the optimum amount of power by the means for setting the optimum amount of power, and means for transmitting the frame. Characterized by comprising and.

The invention according to claim 16 is a radio station, comprising: means for measuring reception quality of a received signal; means for comparing reception quality measured by the measurement means with required quality; Means for generating a bit sequence corresponding to the comparison result of the means for generating, a means for generating a control bit including the bit sequence generated by the means for generating the bit sequence, and determining an optimum amount of power to be allocated to the control bit. Means, by giving an offset to the transmission power of the data bits, the transmission power amount of the control bits, the means for the optimal power amount, and the means for the optimal power amount was the optimum power amount And a means for constructing a frame including the control bits and a means for transmitting the frame.

According to a seventeenth aspect of the present invention, in the wireless station according to the fifteenth or sixteenth aspect, the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. There is a feature.

The invention according to claim 18 is a wireless station, wherein the wireless station according to any one of claims 15 to 17 receives the frame transmitted by the frame transmitting means. And means for adjusting transmission power based on the bit sequence included in the frame received by the means for receiving the frame.

According to a nineteenth aspect of the present invention, there is provided a transmission power control method, wherein the first radio station determines an optimum amount of power to be allocated to control bits, and determines the transmission power of the control bits as data bits. Equalizing the transmission power; adjusting the number of bits of the control bit to set the transmission power amount of the control bit to the optimum power amount; and setting the optimum power amount to the optimum power amount. Constructing a frame containing the quantified control bits, transmitting the frame to a second wireless station, and receiving, at the second wireless station, a signal transmitted by the first wireless station Measuring the quality, comparing the reception quality measured by the measuring step with required quality, and comparing the comparing step Generating a bit sequence corresponding to the result, transmitting the bit sequence generated by the step of generating the bit sequence to the first wireless station; Receiving the bit sequence transmitted by the wireless station, and adjusting transmission power based on the bit sequence received in the receiving step.

According to a twentieth aspect of the present invention, there is provided a transmission power control method, wherein the first radio station determines an optimum amount of power to be allocated to control bits, and sets an offset with respect to the transmission power of the data bits. By giving
Setting the transmission power amount of the control bits to the optimum power amount; forming a frame including the control bits determined to be the optimum power amount by the step of setting the optimum power amount; Transmitting to the first wireless station; and the second wireless station,
Measuring the reception quality of the signal transmitted by the wireless station, comparing the reception quality measured by the measuring step with required quality, and generating a bit sequence corresponding to the comparison result of the comparing step When,
Transmitting the bit sequence generated by the step of generating the bit sequence to the first wireless station;
The first wireless station, comprising: receiving the bit sequence transmitted by the second wireless station; and adjusting a transmission power based on the bit sequence received by the receiving step. Features.

According to a twenty-first aspect of the present invention, in the transmission power control method according to the ninth or twentieth aspect, the step of measuring the reception quality comprises the step of measuring the control bits transmitted by the first wireless station. It is characterized in that measurement is performed using at least a part thereof.

According to a twenty-second aspect of the present invention, in the transmission power control method according to the nineteenth or twentieth aspect, the step of measuring the reception quality includes the step of measuring the control bits transmitted by the first wireless station. The measurement is performed using at least a part and at least a part of data bits transmitted by the first wireless station.

According to a twenty-third aspect of the present invention, in the transmission power control method according to any one of the nineteenth to twenty-second aspects, the optimum power amount of the control bit is set such that a required transmission power of the entire dedicated channel is a minimum. The amount of power is

According to a twenty-fourth aspect of the present invention, a wireless station includes the frame configuration device according to any one of the fourth to sixth aspects, and means for transmitting a frame configured by the frame configuration device. It is characterized by having.

According to a twenty-fifth aspect of the present invention, in a wireless station, a means for receiving the frame transmitted by the means for transmitting the frame by the wireless station according to the twenty-fourth aspect,
Means for measuring the reception quality of the frame received by the means for receiving the frame, means for comparing the reception quality measured by the measurement means with required quality, and a bit sequence corresponding to the comparison result of the means for comparison And a means for transmitting the bit sequence generated by the bit sequence generating means.

According to a twenty-sixth aspect of the present invention, in the wireless station according to the twenty-fifth aspect, the means for measuring the reception quality uses at least a part of the control bits transmitted by the first wireless station. It is characterized by measuring.

According to a twenty-seventh aspect of the present invention, in the wireless station according to the twenty-fifth aspect, the means for measuring the reception quality includes at least a part of the control bits transmitted by the first wireless station and the The measurement is performed using at least a part of data bits transmitted by one wireless station.

According to the present invention, the power amount of the control bit is
By matching the required transmission power of the dedicated channel to the lowest point, the control bit and the data bit have a frame configuration that optimizes the power distribution, thereby realizing a reduction in transmission power and an increase in capacity. The quality of the control bits themselves can be equal to or higher than the required quality.

[0053]

Embodiments of the present invention will be described below with reference to the drawings.

Here, a transmission power control technique for controlling transmission power based on control bits in a CDMA mobile communication system will be described by way of example. However, the present invention is not limited to such an embodiment. It is apparent that the present invention can be similarly applied to a frame configuration technique in a CDMA mobile communication system.

FIG. 5 is a block diagram showing an example of the configuration of a CDMA mobile station according to the present invention.

The mobile station 100 can be roughly divided into mobile station receiving blocks 102 to 126 and mobile station transmitting block 1
30 to 140.

First, mobile station receiving section blocks 102 to 12
6, the downlink signal transmitted from the base station 200 and received by the mobile station is converted into an RF (high frequency) section / down converter 102 for performing high frequency demodulation, an AGC (automatic gain control) amplifier 104, and a quadrature detector. Through 106,
The despreading unit 108 is entered. The despreading unit 108 despreads the signal spread by the pseudo noise (PN) code. The output signal of the despreading unit 108 is supplied to a demodulator / rake combiner 110, a timing generator 114, a desired signal power detector 116, and an interference signal power detector 122, respectively.

The demodulator / rake combiner 110 performs demodulation processing such as inverse transform of a Walsh-transformed signal, and combines signals received from the multipath at a plurality of timings by a maximum ratio combining method or the like. Frame separation unit 112
Separates and extracts transmission power control bits from the symbol sequence of the downlink signal thus combined. The timing generator 114 detects the pilot signal of the downlink signal,
A timing signal for synchronizing is generated and supplied to the desired signal power detector 116 and the interference signal power detector 122. Desired-wave signal power detection section 116 measures the desired-wave received signal power (level) from the base station. The desired signal reception signal power (level) is calculated by the reception SIR calculation section 124.
Sent to

The transmission power determination section 120 receives the transmission power control bits from the frame separation section 112, generates instantaneous transmission power control information based on the transmission power control bits, and outputs the information to the amplitude adjustment section 135.

The instant transmission power control information is created by, for example, any of the following methods.

1) When the bit sequence included in the received transmission power control bits is “1”, instantaneous transmission power control information is created so that the transmission power is reduced by 1 dB. In this case, instantaneous transmission power control information is created so as to increase the transmission power by 1 dB.

2) If the bit sequence included in the received transmission power control bits contains many “1” s, instantaneous transmission power control information is created so as to lower the transmission power by 0.5 dB, and “ If a large number of “0” s are included, instantaneous transmission power control information is created so as to increase the transmission power by 0.5 dB.

3) When the bit sequence included in the received transmission power control bits is “11”, the transmission power is set to 1.5
Create instantaneous transmission power control information to lower dB,
When the bit sequence is "10", the transmission power is 0.5d
B, the instantaneous transmission power control information is created so that the bit sequence included in the received transmission power control bits is
In the case of “00”, instantaneous transmission power control information is created so as to increase the transmission power by 0.5 dB, and the bit sequence is
In the case of "01", instantaneous transmission power control information is created so as to increase transmission power by 1.5 dB.

The interference signal power detection unit 122 and the reception SIR calculation unit 124 measure the reception power of the desired signal from the base station and the interference signal power, and execute the process of calculating the reception SIR.

The required SIR determining section 123 determines the required SIR of the signal from the base station corresponding to a satisfactory received SIR.
Determine the IR. The required SIR may be stored in a memory or the like in advance.

SIR comparing section 125 compares the received SIR calculated by received SIR calculating section 124 with the required SIR determined by required SIR determining section 123.

The result of comparison by SIR comparing section 123 is sent to control bit determining section 126.

Control bit determining section 126 generates a predetermined bit sequence corresponding to the comparison result, and determines a transmission power control bit including the bit sequence.

The bit sequence is generated, for example, by one of the following methods.

1) The magnitude relationship between the received SIR and the required SIR is indicated by one bit. For example, if the received SIR is the required SIR
If it is larger, the bit sequence is set to “1”. If the received SIR is smaller than the required SIR, the bit sequence is set to “0”.

2) The magnitude relationship between the received SIR and the required SIR is indicated by one bit, and the information of the one bit is repeated. For example, if the received SIR is larger than the required SIR, the bit sequence is set to “11111”, and if the received SIR is
If smaller than R, the bit sequence is set to “00000”.

3) Gray code is used. For example, the reception S
If the value obtained by subtracting the required SIR from the IR is 1 dB or more, the bit sequence is set to “11”. If the value is 0 dB or more and less than 1 dB, the bit sequence is set to “10”, and −1 dB or more and 0 dB.
If the value is less than “1”, the bit sequence is “00”. If the value is less than −1 dB, the bit sequence is “01”.

As another embodiment, it is possible to use an error correction code.

The transmission power control bits determined by control bit determining section 126 are supplied to frame generating section 130. Frame generating section 130 inserts this transmission power control bit into an upstream frame sent to base station 200.

Next, the mobile station transmitter blocks 130 to 14
0 will be described. The frame generator 130 receives the transmission power control bits, information data, pilot data, and the like, generates an uplink signal frame, and
Output to 2.

The frame generation unit 130 executes a process of determining the number of transmission power control bits determined by the control bit determination unit 126 according to the optimum power amount (E ₀ ) determined by the optimum power amount determination unit 131. Is done.

Here, the “optimum power (E ₀ )” means that the required transmission power of the entire dedicated channel is minimized when SIR measurement for transmission power control is performed using only control bits. Means the power amount of the control bits. The number of bits is determined such that the power amount of the control bits becomes E ₀ . That is, equal data bit portion and power when placing control bits, by adjusting by increasing or decreasing the number of bits, assigning the desired electric energy E _0.

The optimum power amount determining section 131 may store the optimum power amount (E ₀ ) in a memory or the like in advance.

In the spreading section 132, the spreading code generating section 134
The spectrum of the input signal is spread with the pseudo noise (PN) code generated in step (1). The signal spread by the spreading unit 132 is
After being adjusted by the amplitude adjustment unit 135 based on the instantaneous transmission power control information determined by the transmission power determination unit 120, the modulator 13
6 is subjected to quadrature modulation, etc.
The signal is input to a power amplifier 140 via 38, and the power amplifier 140 amplifies the input signal and transmits an output signal.

Further, the amplitude adjusting unit 135 allocates the control bit power amount to E ₀ according to the optimum power amount (E ₀ ) determined by the optimum power amount determining unit 131.

In the present embodiment, the “reception quality” and “required quality” are determined based on the desired signal reception signal power to interference power ratio (SI
R) has been described as an example, but as another embodiment, the reception power, the bit error rate (BER: Bit)
Error Rate), frame error rate (FER:
“Received quality” and “required quality” may be determined using Frame Error Rate or the like.

FIG. 6 is a block diagram showing an example of the configuration of a CDMA base station according to the present invention.

In FIG. 6, the blocks denoted by the same reference numerals as those in FIG. 5 have the same functions, and thus the description is omitted.

The base station is basically composed of the same blocks as the mobile station. However, in the case of the base station, since it is necessary to receive the channels of a plurality of users (mobile stations) at the same time, the amplitude from the despreading section 108 is There are a plurality of adjustment units 135.
Also, in the mobile station, spreading is performed only by spreading section 132, but in the base station, spreading is performed separately in first spreading for separating channels and second spreading for identifying cells. , A first diffusion unit 202 and a second diffusion unit 204. Since the second spreading in the second spreading section 204 is for cell division and it is necessary to perform spreading once for all the channels, the adder 206 coupled to the amplitude adjusting section 135 uses the channel for a plurality of users. , The second spreading is performed.

(Embodiment 1) FIG. 7 is a diagram showing a configuration of a frame according to Embodiment 1 of the present invention.

The frame 700 includes a control bit portion 702 and a data bit portion 704. Frame 7
00 is, for example, a transmission power control transmission medium transmitted from the transmitting station to the receiving station, that is, a transmission power control transmission signal.

In FIG. 7, the vertical axis represents the amount of transmission power, and the horizontal axis represents the number of bits.

E _{0 in} FIG. 7 is S ₀ for transmission power control.
When the IR measurement is performed using only the control bits, it indicates the power amount of the control bits that minimizes the required transmission power of the entire dedicated channel, and E ₁ is the power that satisfies the required quality of the control bits themselves. Indicates the amount.

[0089] Each of the absolute value or magnitude of E ₀ and E ₁ varies due transmission rate of a dedicated channel, E ₀
If There like it is larger than E _1, as in FIG. 7,
Assigning as the amount of power control bits becomes E _0. Further, as shown in FIG. 7, when arranging the control bits, the power is made equal to the data bit portion, and the number of bits is adjusted to allocate a desired amount of power E ₀ .

FIG. 8 is a flowchart showing a method of creating a frame according to the first embodiment of the present invention.

[0091] First, in step S801, to determine the optimum point E ₀ of the amount of power control bits such that the minimum required transmission power of the dedicated channel.

Next, in step S802, the transmission power of the control bits so that E _0, to determine the number of bit control bits.

When E ₀ is larger than E ₁ ,
By assigning power of E ₀ to the control bits, while the quality of the control bits themselves and the required quality or can reduce the required transmission power of the dedicated channel, it is possible to increase channel capacity.

Further, when allocating the power amount of E ₀ to the control bits, the power of the control bits and the power of the data bits are made equal, and the number of control bits is adjusted so that the transmission power is kept constant over time. In addition, uniformity of interference and high efficiency of the transmission amplifier can be realized.

(Embodiment 2) FIG. 9 is a diagram showing a frame configuration according to Embodiment 2 of the present invention.

The frame 900 includes a control bit portion 902 and a data bit portion 904. Frame 9
00 is, for example, a transmission power control transmission medium transmitted from the transmitting station to the receiving station, that is, a transmission power control transmission signal.

In FIG. 9, the vertical axis represents the amount of transmission power, and the horizontal axis represents the number of bits.

E ₀ and E _{1 in} FIG. 9 are power amounts according to the first embodiment.

As in the first embodiment, when E ₀ is larger than E ₁ , the control bits are allocated such that the power amount becomes E ₀ . In the present embodiment,
As shown in FIG. 9, when arranging the control bits, a desired amount of power E ₀ is allocated by giving an offset between the power of the control bit portion and the power of the data bit portion.

FIG. 10 is a flowchart showing a method of creating a frame according to the second embodiment of the present invention.

[0102] First, in step S1001, the determining an optimal point E ₀ of the amount of power control bits such that the minimum required transmission power of the dedicated channel.

Next, in step S1002, the control bit offset is determined such that the control bit transmission power amount becomes E _0, and the desired power amount E ₀ is allocated.

When E ₀ is larger than E _1, E
By allocating a power amount of ₀ to the control bits, the required transmission power of the dedicated channel can be reduced and the channel capacity can be increased, while maintaining the quality of the control bits themselves at or above the required quality.

Further, when the power amount of E ₀ is allocated to the control bits, the power of the control bits is offset from the power of the data bits, so that a flexible bit arrangement can be realized. Unlike the adjustment by the number, since the value can be set to a continuous value, the power amount of the control bits can be more strictly optimized in terms of capacity.

Next, the transmission power control procedure according to the present invention will be described.
This will be described with reference to FIGS.

(Embodiment 3) FIG.11 is a flowchart showing a transmission power control procedure according to Embodiment 3 of the present invention.

In step S1102, the first wireless station measures the reception quality of the signal transmitted by the second wireless station. Here, the “reception quality” refers to the ratio of the received signal power to the interference power (SIR), the received power, the bit error rate (BE)
R: Bit Error Rate (FER) and frame error rate (FER: Frame Error Rate).

Next, in step S1104, the reception quality is compared with the required quality. Here, “required quality” refers to reception quality that can satisfy a predetermined standard.

Next, in step S1106, a bit sequence corresponding to the comparison result is generated. The bit sequence is generated by one of the following methods, for example.

1) The magnitude relationship between the reception quality and the required quality is indicated by one bit. For example, when the reception quality is higher than the required quality, the bit sequence is set to “1”, and when the reception quality is lower than the required quality, the bit sequence is set to “0”.

2) The magnitude relationship between the reception quality and the required quality is indicated by one bit, and the information of the one bit is repeated. For example,
If the reception quality is higher than the required quality, the bit sequence is set to “11111”. If the reception quality is lower than the required quality, the bit sequence is set to “00000”.

3) Gray code is used. For example, if the value obtained by subtracting the required quality from the reception quality is 1 dB or more, the bit sequence is “11”; if it is 0 dB or more and less than 1 dB, the bit sequence is “10”; The sequence is set to “00”, and if less than −1 dB, the bit sequence is set to “01”.

As another embodiment, it is possible to use an error correction code.

Next, in step S1108, control bits including the generated bit sequence are generated.

Next, in step S1110, a frame including control bits is formed.

The frame configuration procedure described in the first embodiment (see FIGS. 7 and 8)
Frame) according to the frame configuration procedure described in the second embodiment (see FIG. 9 and FIG. 10).

Next, in step S1112, the frame is transmitted to the second wireless station.

Next, in step S1114, the second
Wireless stations receive the frame.

Next, in step S1116, the transmission power is adjusted based on the bit sequence included in the frame. Adjustment of the transmission power is performed, for example, by any of the following methods.

1) If the bit sequence included in the received transmission power control bits is “1”, instantaneous transmission power control information is created so that the transmission power is reduced by 1 dB, and the bit sequence is “0”. In this case, instantaneous transmission power control information is created so as to increase the transmission power by 1 dB.

2) If the bit sequence included in the received transmission power control bits contains many “1” s, instantaneous transmission power control information is created so as to lower the transmission power by 0.5 dB, and “ If a large number of “0” s are included, instantaneous transmission power control information is created so as to increase the transmission power by 0.5 dB.

3) When the bit sequence included in the received transmission power control bits is “11”, the transmission power is set to 1.5
Create instantaneous transmission power control information to lower dB,
When the bit sequence is "10", the transmission power is 0.5d
B, the instantaneous transmission power control information is created so that the bit sequence included in the received transmission power control bits is
In the case of “00”, instantaneous transmission power control information is created so as to increase the transmission power by 0.5 dB, and the bit sequence is
In the case of "01", instantaneous transmission power control information is created so as to increase transmission power by 1.5 dB.

According to the above procedure, the first radio station can
The transmission power on the line to the wireless station is controlled.

(Embodiment 4) FIG.12 is a flowchart showing a transmission power control procedure according to Embodiment 4 of the present invention.

First, in step S1202, the first wireless station configures a frame including control bits.

The frame configuration procedure described in the first embodiment (FIGS. 7 and 8)
Frame) according to the frame configuration procedure described in the second embodiment (see FIG. 9 and FIG. 10).

Next, in step S1204, the frame is transmitted to the second wireless station.

Next, in step S1206, the second
Wireless stations receive the frame.

Next, in step S1208, the first
Measure the reception quality of the signal transmitted by the wireless station. Here, the measurement of the reception quality may be measured using at least a part of the control bits transmitted by the first wireless station (that is, a part or all of the control bits), or at least a part of the control bits. And at least some of the data bits (ie, some or all of the control bits and data bits).

Next, in step S1210, the reception quality is compared with the required quality.

Next, in step S1212, a bit sequence corresponding to the comparison result is generated.

Next, in step S1214, the bit sequence is transmitted to the first wireless station.

Next, in step S1216, the first
Wireless station receives the bit sequence transmitted by the second wireless station.

Next, in step S1218, the transmission power is adjusted based on the bit sequence.

According to the above procedure, the first wireless station transmits the second
The transmission power on the line to the wireless station is controlled.

[0136]

As described above, according to the present invention, allocates power of E ₀ to the control bits, by the control bits and data bits to the optimum amount of power distribution, required quality the quality of the control bits themselves As described above, the required transmission power of the individual channel can be reduced, and the channel capacity can be increased.

When allocating the power amount of E ₀ to the control bits, the power of the control bits and the power of the data bits are made equal, and the number of control bits is adjusted.
The transmission power can be made constant over time, and the interference can be made uniform and the transmission amplifier can be made more efficient.

Further, when the power amount of E ₀ is allocated to the control bits, the power of the control bits is offset from the power of the data bits, so that a flexible bit arrangement can be realized. Unlike the adjustment by the number, since the value can be set to a continuous value, the power amount of the control bits can be more strictly optimized in terms of capacity.

[Brief description of the drawings]

FIG. 1 is a diagram showing interference from another mobile station on an uplink in a conventional example.

FIG. 2 is a diagram illustrating an example of an individual channel configuration of a CDMA mobile communication system according to the related art.

FIG. 3 is a graph showing the relationship between the amount of control bit power per slot and the bit error rate in a conventional CDMA mobile communication system.

FIG. 4 is a graph showing the relationship between the amount of control bit power per slot and the required transmission power of the entire dedicated channel when SIR measurement of transmission power control is performed using only control bits according to the present invention.

FIG. 5 is a block diagram illustrating an example of a configuration of a CDMA mobile station according to the present invention.

FIG. 6 is a block diagram showing an example of a configuration of a CDMA base station according to the present invention.

FIG. 7 is a diagram showing a configuration of a frame according to the first embodiment of the present invention.

FIG. 8 is a flowchart showing a method of creating a frame according to the first embodiment of the present invention.

FIG. 9 is a diagram showing a configuration of a frame according to the second embodiment of the present invention.

FIG. 10 is a flowchart showing a method of creating a frame according to Embodiment 2 of the present invention.

FIG. 11 is a flowchart showing a transmission power control procedure according to Embodiment 3 of the present invention.

FIG. 12 is a flowchart showing a transmission power control procedure according to Embodiment 4 of the present invention.

[Explanation of symbols]

100 mobile station 102 RF unit / down converter 10
4 AGC amplifier 106 Quadrature detector 108 Despreader 110 Demodulator / Rake combiner 114 Timing generator 116 Desired signal power detector 120 Transmission power determiner 122 Interference signal power detector 123 Required SIR determiner 124 Received SIR calculator 125 SIR determining unit 126 control bit determining unit 130 frame generating unit 131 optimal power amount determining unit 132 spreading unit 134 spreading code generating unit 136 modulator 138 RF unit / upconverter 140 power amplifier 200 base station 202 first spreading unit 204 second Diffusion unit 206 Adder

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoshihiro Ishikawa 2-10-1 Toranomon, Minato-ku, Tokyo NTT Mobile Communications Network Co., Ltd. F-term (reference) 5K022 EE02 EE21 EE31 5K060 BB07 CC04 FF06 HH06 LL01 5K067 AA13 AA43 BB03 BB04 CC10 DD27 DD45 EE02 EE10 EE63 EE64 GG08 GG11 HH22

Claims (27)

[Claims] 1. A method for configuring a frame in a CDMA mobile communication system, comprising the steps of: determining an optimum amount of power to be allocated to a control bit; and making the transmission power of the control bit equal to the transmission power of a data bit. By adjusting the number of control bits,
Setting the transmission power amount of the control bits to the optimum power amount. 2. A method for configuring a frame in a CDMA mobile communication system, comprising: determining an optimum amount of power to be allocated to a control bit; and transmitting an offset to a transmission power of a data bit to transmit the control bit. Setting a power amount to the optimum power amount. 3. The frame configuration method according to claim 1, wherein the optimum power amount of the control bits is a power amount that minimizes required transmission power of the entire dedicated channel. Frame construction method. 4. A frame configuration device in a CDMA mobile communication system, comprising: means for determining an optimum amount of power to be allocated to control bits; means for making transmission power of the control bits equal to transmission power of data bits; Means for adjusting the number of control bits to set the transmission power of the control bits to the optimum power. 5. A frame configuration device in a CDMA mobile communication system, comprising: means for determining an optimum amount of power to be allocated to control bits, and transmission of the control bits by giving an offset to transmission power of data bits. Means for setting the amount of electric power to the optimum amount of electric power. 6. The frame configuration device according to claim 4, wherein the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. Frame construction device. 7. A transmission medium in a CDMA mobile communication system, comprising: a data bit having a transmission power equal to a transmission power of a control bit; and the control bit, the number of bits of which is adjusted so as to have an optimal power amount. A transmission medium characterized by comprising: 8. A transmission medium in a CDMA mobile communication system, comprising: a control bit in which a transmission power amount is optimized by giving an offset to a transmission power of a data bit. Transmission medium. 9. The transmission medium according to claim 7, wherein the optimum power amount of the control bits is a power amount that minimizes required transmission power of the entire dedicated channel. Medium. 10. The transmission medium according to claim 7, wherein the control bits include a bit sequence corresponding to a result of comparison between reception quality and required quality. 11. The transmission medium according to claim 7, wherein the transmission medium is a transmission signal. 12. A transmission power control method, wherein a first radio station measures the reception quality of a signal transmitted by a second radio station, and the reception quality measured by the measuring step is a required quality. And a step of generating a bit sequence corresponding to a comparison result of the comparing step; a step of generating a control bit including the bit sequence generated by the step of generating the bit sequence; and Determining the optimum amount of power to be allocated to, the step of equalizing the transmission power of the control bits to the transmission power of the data bits, and adjusting the number of bits of the control bits to reduce the amount of transmission power of the control bits The step of setting the optimum power amount; and the step of setting the optimum power amount Composing a frame including control bits, transmitting the frame to the second wireless station, and wherein the second wireless station comprises:
Receiving the frame transmitted by the transmitting step; and adjusting transmission power based on the bit sequence included in the frame received by the receiving step. Control method. 13. A transmission power control method, wherein a first radio station measures the reception quality of a signal transmitted by a second radio station, and measures the reception quality measured by the measuring step to a required quality. And a step of generating a bit sequence corresponding to a comparison result of the comparing step; a step of generating a control bit including the bit sequence generated by the step of generating the bit sequence; and Determining the optimum amount of power to be allocated to the control bits, and setting the transmission power amount of the control bits to the optimum power amount by giving an offset to the transmission power of the data bits. Constructing a frame containing the control bits determined to be the optimal amount of power by: Transmitting to the second wireless station, and receiving, at the second wireless station, the frame transmitted by the transmitting step; and being included in the frame received by the receiving step Adjusting the transmission power based on the bit sequence. 14. The transmission power control method according to claim 12, wherein the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. Transmission power control method to perform. 15. A radio station, comprising: means for measuring the reception quality of a received signal; means for comparing the reception quality measured by the measurement means with required quality; and corresponding to a comparison result of the comparison means. Means for generating a bit sequence to be executed, means for generating a control bit including the bit sequence generated by the means for generating the bit sequence, means for determining an optimal amount of power to be allocated to the control bit, Means for making the transmission power equal to the transmission power of the data bits, and adjusting the number of bits of the control bits so that the transmission power amount of the control bits is the optimum power amount; and Means for composing a frame including the control bit set to the optimal power amount by means for performing the operation, and means for transmitting the frame. Radio station to do. 16. A radio station, comprising: means for measuring reception quality of a received signal; means for comparing reception quality measured by said measuring means with required quality; Means for generating a bit sequence to be transmitted, means for generating a control bit including the bit sequence generated by the means for generating the bit sequence, means for determining an optimal amount of power to be allocated to the control bit, and transmission of data bits. By giving an offset to the power, the transmission power amount of the control bits is changed to the optimum power amount, and the frame including the control bits set to the optimum power amount by the optimum power amount is transmitted. A radio station comprising: means for configuring; and means for transmitting the frame. 17. The radio station according to claim 15, wherein the optimal power amount of the control bit is:
A radio station having a power amount that minimizes required transmission power of an entire individual channel. 18. A wireless station, wherein the wireless station according to claim 15 receives the frame transmitted by the frame transmitting means, and receives the frame. Means for adjusting transmission power based on the bit sequence included in the frame received by the means. 19. A transmission power control method, comprising: determining, in a first wireless station, an optimum amount of power to be allocated to control bits; and making the transmission power of the control bits equal to the transmission power of data bits. Adjusting the number of bits of the control bits to set the transmission power amount of the control bits to the optimum power amount; and setting the control bits to the optimum power amount by the step of setting the optimum power amount. Constructing a frame including: transmitting the frame to a second wireless station; and measuring, at the second wireless station, the reception quality of the signal transmitted by the first wireless station; Comparing the reception quality measured by the measuring step with required quality; and a bit sequence corresponding to a comparison result of the comparing step. Generating the bit sequence, transmitting the bit sequence generated by the step of generating the bit sequence to the first wireless station, and transmitting the bit sequence generated by the second wireless station in the first wireless station. A transmission power control method, comprising: receiving the bit sequence; and adjusting transmission power based on the bit sequence received in the receiving step. 20. A transmission power control method, comprising: determining, in a first wireless station, an optimum amount of power to be allocated to a control bit; Setting the transmission power amount to the optimum power amount; forming a frame including the control bits determined to be the optimum power amount by the step of setting the optimum power amount; and transmitting the frame to a second wireless station. Transmitting to the second radio station, measuring the reception quality of the signal transmitted by the first radio station, and comparing the reception quality measured by the measuring step with a required quality. Generating a bit sequence corresponding to the comparison result of the comparing step, and generating the bit sequence. Transmitting the generated bit sequence to the first wireless station; receiving, by the first wireless station, the bit sequence transmitted by the second wireless station; Adjusting the transmission power based on the bit sequence thus performed. 21. The transmission power control method according to claim 19, wherein the step of measuring the reception quality is performed by using at least a part of the control bits transmitted by the first wireless station. A transmission power control method. 22. The transmission power control method according to claim 19, wherein the step of measuring the reception quality comprises at least a part of the control bits transmitted by the first radio station and the first Transmission power control method, wherein the measurement is performed using at least a part of the data bits transmitted by the wireless station. 23. The transmission power control method according to claim 19, wherein the optimum power amount of the control bit is a power amount that minimizes required transmission power of the entire dedicated channel. Transmission power control method characterized by the above-mentioned. 24. A radio station, comprising: the frame configuration device according to claim 4; and means for transmitting a frame configured by said frame configuration device. Bureau. 25. A wireless station, comprising: means for receiving the frame transmitted by the means for transmitting the frame by the wireless station according to claim 24; and receiving quality of the frame received by the means for receiving the frame. Means for measuring, means for comparing the reception quality measured by the measuring means with required quality, means for generating a bit sequence corresponding to the comparison result of the comparing means, and means for generating the bit sequence Means for transmitting said bit sequence. 26. The radio station according to claim 25,
The radio station, wherein the means for measuring the reception quality measures the reception quality using at least a part of the control bits transmitted by the first radio station. 27. The radio station according to claim 25,
The means for measuring the reception quality includes at least a part of the control bits transmitted by the first radio station and the first
The radio station performs measurement using at least a part of data bits transmitted by the radio station.