JP2001217770A - Method and device for controlling transmission power - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent outer loop control from being mismatched before and after performing hand-over connection. SOLUTION: In the transmission power control method for CDMA communication system, at the ordinary connection for a mobile station to communicate only with a single base station, a quality control part in the base station connected with the mobile station performs the transmission power control of an incoming link corresponding to a receiving quality and at the hand-over connection for the mobile station to be connected with plural base stations, a quality control part in a switchboard housing the base station as the object of hand-over performs the transmission power control of the incoming link corresponding to a composite receiving quality.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a transmission power control method and apparatus in a code division multiple access (CDMA) communication system (for example, a personal communication system (PCS) or digital cellular).

[0002]

2. Description of the Related Art The following is a literature showing the prior art.

Reference 1: "CDMA-Principles of Spread Sp
ectrum Communication ”, Andrew J. Viterbi, Addison We
sley, 1995. Literature 2: "A Study on Transmission Power Control Method Following Instantaneous Value Fluctuation in DS-CDMA Downlink Channel", Kikuchi et al., IEICE Technical Report, RCS96.
-162, pp.113-118,1997 Reference 3: “Mobile Station-Base Station Compatibilit
y Standard for Dual-Mode Wideband Spread Spectrum
Cellular System ", IS-95 Literature 1, discloses a basic transmission power control technique. The device of Literature 1 includes an automatic gain control circuit (hereinafter referred to as" AG ").
C circuit ". ), An open-loop power control technique is shown. In this apparatus, closed-loop power control for adjusting transmission power in response to a power control instruction transmitted from a communication destination is shown.
Here, one expression (for example, “0”) of the power control bit transmitted from the base station is referred to as “increase of transmission power”.
, And the remaining expression (for example, “1”) is assigned to the transmission power “decrease” instruction, thereby performing transmission power control of the mobile station.

[0004] Reference 2 discloses a quality control method using an outer loop using a transmission power control technique. That is, in Reference 2, a signal-to-interference power ratio (hereinafter, referred to as “SIR”), which is a target value of transmission power control, is set to a frame error rate (hereinafter, referred to as “FER”), which is a set target quality. 2 shows a procedure for determining the sequence based on the observed frame error sequence. Specifically, the presence or absence of a frame error is determined by a cyclic redundancy check (hereinafter referred to as “CRC”) or the like, and “0” is set when a normal frame is received.
When an error frame is received, an estimated value of FER is calculated by an exponentially weighted average formula of a sequence (frame error sequence) to which "1" is assigned, and the transmission power control target SIR is updated based on a comparison between the estimated value and the set target FER. Is disclosed.

[0005] Reference 3 discloses a handover technique in a CDMA communication system. The mobile station in Literature 3 monitors pilot signals received from a plurality of base stations including the connected base station, and transmits the monitoring result to the connected base station as a report message. On the other hand, the connected base station transmits a report message as a monitoring result to the exchange controlling a plurality of base stations including itself.

[0006] The exchange which has received the message determines one base station to which the mobile station is to be connected, from among a plurality of base stations including the base station being connected. The base station selected as the base station newly connected to the mobile station from the exchange receives the uplink transmission signal emitted from the mobile station and transmits the downlink transmission signal. The switching center issues a connection command to the mobile station via the base station with which the mobile station is communicating, and in response, the mobile station receives a downlink signal from the newly connected base station. Thus, handover is realized.

[0007] The exchange station sends a command to disconnect the communication connection of the base station which does not contribute to the communication quality, depending on the content of the report message as the monitoring result, and releases the handover state of the mobile station.

[0008] For a method of controlling uplink transmission power in a handover state, for example, a plurality of connected base stations are called base station 1, base station 2, ..., base station N, and transmission power control from each of them is performed. When bits are referred to as bit 1, bit 2,..., Bit N, it is disclosed that control is performed such that the transmission power is increased only when all bits indicating the transmission power at a certain time simultaneously issue an instruction to increase the transmission power. Have been.

[0009]

However, in the case of the prior art shown in the above document, when performing handover, the transmission power control of the uplink is not performed by using the reception gain, and each base station is not controlled. The downlink transmission power was only controlled by the outer loop. That is, the configuration has been such that the outer loop control is performed for each base station. For this reason, there is a problem that it is inevitable that the reception quality of each base station becomes unbalanced at the time of executing the handover, and a sufficient reception gain cannot be obtained at the time of the handover.

In the outer loop control shown in the prior art, a method of calculating an estimated value by an exponential weighted estimating method is employed. In calculating the estimated value, the estimation section is in principle continuously continuous without interruption from the control start point. Need to be. For this reason, it is necessary to select whether the control is performed by the base station or the switching center that combines the received frames. However, when the control is performed by the base station, there is the above-described problem. When the control is uniquely performed by the exchange, the control load of the entire system increases, and the control load between the base station and the exchange is increased. There was a problem that the traffic load of the interface also increased at the same time.

The present invention has been made in view of the above problems, and requires only a small control load as a whole system, and does not cause inconsistency in uplink transmission power control before and after execution of handover. The purpose is to propose a control technology that can be completed.

[0012]

(A) In order to solve this problem, in the first invention, the following processing is performed in a transmission power control method in a CDMA communication system. That is, (1) during normal connection where the mobile station communicates only with a single base station, the quality adjustment unit in the base station connected to the mobile station performs uplink transmission power control according to the reception quality, 2) When a mobile station is connected to a plurality of base stations in a handover connection, a quality adjustment unit in an exchange accommodating the base station to be handed over performs uplink transmission power control according to the combined reception quality. Shall be.

As described above, according to the present invention, the outer loop control during handover is switched from the base station which is the target of the handover to the exchange which accommodates them. Can be corrected so that a reception gain due to handover can be obtained.

(B) In the second invention, the CD
In a transmission power control method in an MA communication system,
The following processing is executed. That is, the reception quality of the received signal received from the partner station to be controlled is observed for each observation section given in a finite period, and only in accordance with the reception quality observed in the single observation section, The target reception power value used as a criterion for the next transmission power control of the partner station to be controlled is increased or decreased.

As described above, the present invention limits the observation interval of reception quality used for transmission power control to a finite period.
Even if an error is included in the observation result, the effect can be limited to a specific period.

(C) In the third invention, the first invention
In addition to the processing of the invention, the reception quality of the reception signal received from the partner station to be controlled is observed for each observation section given in a finite period, and only in accordance with the reception quality observed in the single observation section. Then, a process of increasing / decreasing the target reception power value used as a criterion for the next transmission power control of the partner station to be controlled is executed.

By adopting such processing, in the present invention, it is possible to effectively avoid an increase in control load and an increase in traffic load between the base station and the switching center due to switching of the outer loop control position.

(D) In the fourth aspect, the second aspect
Alternatively, in the processing of the third invention, the observation section is set to a period inversely proportional to the frame error rate.

(E) In the fifth aspect, the second aspect
In any of the fourth to fourth inventions, when a frame error is detected in the observation section, the target received power value used for the criterion is increased, and when no frame error is detected in the observation section, the target reception power value is used for the criterion. Control is performed to lower the target reception power value.

(F) In the sixth aspect, the second aspect
In any one of the fourth to fourth aspects, when a frame error is detected in the observation section, the target reception power value used as a criterion is increased according to the number of detections, and no frame error is detected in the observation section. , So as to reduce the target received power value used for the criterion.

(G) Furthermore, in the seventh invention, C
A transmission power control device mounted on a base station of a DMA communication system includes a quality adjustment unit having the following functions. That is, at the time of the normal connection in which the mobile station communicates only with the base station on which the mobile device is mounted, the mobile station performs uplink transmission power control according to the reception quality observed in the mobile device, and the mobile station mounts the mobile device. At the time of a handover connection that is linked to a plurality of base stations including a base station, a quality adjustment unit that performs uplink transmission power control according to a notification from an exchange that accommodates the base station on which the base station is mounted is provided. .

Thus, the present invention switches the outer loop control during the handover from the base station that is the target of the handover to the exchange that accommodates them, so that the connection state between the base stations during the handover is changed. The imbalance can be corrected so that a reception gain due to handover can be obtained.

(H) In the eighth invention, the CD
A transmission power control device mounted on an exchange of an MA communication system includes a quality adjustment unit having the following functions. That is, at the time of the normal connection in which the mobile station communicates only with the single base station accommodated by the switching station on which the mobile station is mounted, the single base station performs uplink transmission power control, and the mobile station performs its own operation. At the time of a handover connection in connection with a plurality of base stations accommodated by an exchange in which the device is mounted, the own device is provided with a quality adjustment unit for initiatively performing uplink transmission power control.

As described above, according to the present invention, the outer loop control during handover is switched from the base station which is the target of the handover to the exchange which accommodates them, so that the connection state between the base stations during the handover is changed. Can be corrected so that a reception gain due to handover can be obtained.

(I) In the ninth invention, the CD
A transmission power control device mounted on a mobile station, a base station, or an exchange of an MA communication system includes a quality adjustment unit having the following functions. That is, the reception quality of the received signal received from the partner station to be controlled is observed for each observation section given in a finite period, and only in accordance with the reception quality observed in the single observation section, A quality adjustment unit is provided for controlling the increase / decrease of the target reception power value used as a criterion at the time of the next transmission power control of the partner station.

As described above, the present invention limits the observation interval of the reception quality used for transmission power control to a finite period.
Even if an error is included in the observation result, the effect can be limited to a specific period.

(J) In the tenth invention, the following functions are provided to the quality adjusting unit of the ninth invention. That is, the reception quality of the received signal received from the partner station to be controlled is observed for each observation section given in a finite period, and only in accordance with the reception quality observed in the single observation section, And a function of increasing or decreasing a target reception power value used as a criterion at the time of the next transmission power control of the partner station to be controlled.

By adopting such a processing function, in the present invention, it is possible to effectively avoid an increase in control load and an increase in traffic load between the base station and the exchange station due to the switching of the outer loop control position.

(K) In the eleventh invention, in the ninth or tenth invention, the observation section is set to a period inversely proportional to the frame error rate.

(L) In the twelfth aspect, in any one of the ninth to eleventh aspects, when a frame error is detected in the observation section, the target received power value used as a criterion is increased. When no frame error is detected in the observation section, control is performed so as to lower the target received power value used as a criterion.

(M) In the thirteenth aspect, in any one of the ninth to eleventh aspects, when a frame error is detected in the observation section, the frame error is used as a criterion according to the detected number. Control is performed so as to increase the target received power value and to reduce the target received power value used as a criterion when no frame error is detected in the observation section.

(N) Further, in the fourteenth invention,
The transmission power control device according to any one of the seventh, ninth to thirteenth aspects is mounted on a base station device that uses a CDMA communication system for communication with a mobile station. As a result, a base station capable of realizing a handover connection with appropriate quality can be realized.

(O) In the fifteenth invention, the C
Switching apparatuses accommodating a plurality of base station apparatuses that communicate with mobile stations using the DMA communication system are provided with eighth to thirteenth stations.
The transmission power control device according to any one of the above. As a result, a base station capable of realizing a handover connection with appropriate quality can be realized.

(P) In the sixteenth invention, the transmission power control device according to any one of the ninth to thirteenth aspects is provided in a mobile station device using a CDMA communication system for communication with a base station. Mount. As a result, a base station capable of realizing a handover connection with appropriate quality can be realized.

[0035]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (A) Configuration of Embodiment Hereinafter, embodiments of a transmission power control method and apparatus according to the present invention will be described. FIG. 1 functionally shows a typical station configuration of a CDMA communication system related to the present invention. FIG. 1 shows that the mobile station 130 has two base stations 110.
And 120 are in a handover connection state. Also, a plurality of base stations including the two base stations in handover connection are accommodated in the exchange 140, which is an upper station.

(A-1) Configuration of Base Station First, the functional block configuration of the base stations 110 and 120 will be described. The configurations of base stations 110 and 120 are the same. Therefore, only the configuration of base station 110 will be described below. The base station 110 includes a timing generator 110
1, channel encoder 1102, channel multiplexing section 110
3. Spreading modulator 1104, variable gain transmission amplifier 110
5. Transmission radio section 1106, quality adjustment section 1107, transmission power control section 1108, TPC (Transmit Power Control)
Gain calculator 1109, channel decoder 1110, rake receiver 1111, received AGC (Auto Gain Control)
It comprises an amplifier 1112, a radio reception unit 1113, and a pilot signal transmission unit 1114.

Here, the timing generator 1101 is means for generating an operation clock and a reference clock used in the base station. The channel coder 1102 is
This is means for encoding user data (for example, audio data) included in the downlink from 0 for each channel. The channel multiplexing unit 1103 is means for multiplexing a transmission power control bit required for the mobile station 130 connected to the own station to a downlink data signal. Spreading modulation section 1104 applies PN (Pseudorandom Noise) to downlink channel data.
This is means for multiplying a sequence and performing spread modulation.

The variable gain transmission amplifier 1105 is means for controlling the transmission power of the spread modulated signal for each slot in accordance with an instruction from the TPC gain calculation unit 1109. The transmission radio section 1106 is means for inputting a pilot signal provided from the pilot signal transmission section 1114 into each slot data and radiating it into space as a radio frequency band signal.
FIG. 2 shows the relationship between each slot and a frame for reference.
One frame is composed of 16 slots, and one slot is composed of 4 pilot symbols and 36 symbols of data.

The quality adjustment unit 1107 is means for determining the uplink reception quality of each of the mobile stations 130 connected to the own station. The determination operation in the quality adjustment unit 1107 is one of the features of the control method proposed in the present specification. Although details will be described later, the quality adjustment unit 1107 compares the current communication quality and the target quality for each of the mobile stations 130 to be determined, and determines whether the current communication quality is excessive or inferior to the target quality. Is determined. Then, the quality adjustment unit 1107 determines,
If it is determined that the quality is excessive, it is instructed to lower the target SIR of the transmission power control unit 1103 by a fixed value Δ [dB], and if it is determined that the quality is poor, the transmission power control unit The target SIR of 1103 is set to a constant value Δ [dB].
Give instructions to raise only.

It should be noted that the quality judgment processing in the quality adjustment section 1107 is performed for each observation section T that is inversely proportional to the target FER, and the error information to be considered in the judgment is limited to information detected in the observation section. Shall be. In this way, it differs from the prior art in that only information within a finite period is targeted.

Transmission power control section 1108 is a means for comparing the target SIR with the reception SIR to calculate transmission power control bits (ie, increase / decrease, step width, etc.). Note that the transmission power control unit 1108 includes a rake receiver 1111
Calculate the received SIR from the desired signal power and interference power measured at. Here, the calculation of the reception SIR is performed for each time interval at which the transmission power control bit is updated. The calculated transmission power control bits are output to channel multiplexing section 1103 and channel decoder 1110. Incidentally, the notification to the channel decoder 1110 only needs to include the increase / decrease information (that is, the information of “increase” or “decrease”).

TPC gain calculation section 1109 receives reception AG
It is required to transmit data to each mobile station 130 based on the input level before control and the output level after control given from the C amplifier 1112, and the uplink transmission power control bit given from the rake receiver 1111. This is means for calculating the transmission power for each mobile station (that is, for each slot). Note that an existing method is applied to this calculation method, and a description thereof in the specification of the present application will be omitted.

The channel decoder 1110 is a means for inputting output data of the rake receiver 1111 for error correction, and for outputting the decoded data to the exchange 140, which is an upper station. The channel decoder 1110 outputs to the quality adjustment unit 1107 the presence or absence of a frame error detected as a result of error correction by the redundancy check (CRC).

The rake receiver 1111 is a means that includes finger circuits corresponding to each of the multipath signals included in the received data, and combines and outputs the data despread in each. The rake receiver 111
1 supplies the measured desired signal power and interference power to the transmission power control unit 1108. Also, this rake receiver 11
In 11, the transmission power control bits are separated from the data after the multipath combining and supplied to the TPC gain calculation section 1109.

The reception AGC amplifier 1112 adjusts the signal level of the received signal to a predetermined level suitable for signal processing, and A / D converts the signal to perform a subsequent rake reception.
11 means for outputting. The receiving AGC amplifier 1
112 outputs the input level before control and the input level after control to the TPC gain calculator 1109.

The receiving radio section 1113 is means for demodulating a signal received via a radio channel and outputting the demodulated signal as received data. Pilot signal transmitting section 1114 is a means for generating a pilot signal and providing this to transmitting radio section 1106. In the above description, the configuration example in the case of employing the direct spread system as the system for generating the spread spectrum signal has been described.However, in the case of employing the frequency hopping system, the spread modulation section is provided at a different position. Become. The same applies to the mobile station 130.

(A-2) Configuration of Mobile Station Next, a functional block configuration of the mobile station 130 will be described.
The mobile station 130 includes a timing generation section 1301, a channel encoder 1302, a channel multiplexing section 1303, a spread modulation section 1304, a variable gain transmission amplifier 1305, a transmission radio section 1306, a quality adjustment section 1307, and a transmission power control section 13.
08, TPC gain calculator 1309, channel decoder 1
310, rake receiver 1311, reception AGC amplifier 13
12, a receiving radio unit 1313. As is clear from FIG. 1, the configuration of the mobile station 130 is basically the same as the configuration of the base stations 110 and 120.

That is, these units constituting the mobile station 130 also receive the signal strength (SI) of the signal received from the currently connected base station similarly to the case of the base stations 110 and 120.
R) and the communication quality (FER) are detected, and the function of instructing to increase or decrease the transmission power of the base station as the communication partner is the same.

The difference is that, in the case of the mobile station 130, in addition to the function of calculating the reception strength (SIR) of the signal received from the connected base station, the reception strength (SIR) of the signal received from other neighboring base stations is also considered. SIR) is different in that a function for calculating in preparation for handover is provided, and a function for notifying the switching center 140 of the detection result on the uplink is provided.

Here, regarding the reception strength (SIR) of a signal received from a peripheral base station including a connected base station,
It is calculated by the transmission power control unit 1308 and notified to a processing circuit or the like as an upper layer via a path (not shown).
Also, information on the reception strength (SIR) of a signal received from a peripheral base station including a connected base station is embedded in data by a processing circuit (not shown) or the like as a part of uplink data, , And is input to the converter 1302.

(A-3) Configuration of Switching Center Finally, a functional block configuration of the switching center 140 will be described.
The exchange 140 includes an uplink selection / synthesis unit 1401, an overall quality adjustment unit 1402, and an exchange control unit 1403.

Here, uplink selection / combination section 1401
Performs a transfer to a higher layer of a signal transmitted from a connected base station at the time of a normal connection (at the time of connection other than the handover), and at the time of a handover, 2
This is means for combining signals sent from two base stations and transferring the combined signal to an upper layer. The uplink selection / synthesis unit 1
401 indicates that the execution of handover is performed by the exchange control unit 1403.
Then, frame selection and synthesis are performed for each frame based on the CRC result, the received SIR per frame, and the like.

The overall quality adjustment unit 1402 is means for instructing the base station to stop the quality adjustment operation performed at the time of executing the handover, and taking over and executing the quality adjustment operation itself. That is, the overall quality adjustment unit 1402
This is a means for changing the position of the outer loop control from the base station to the exchange when the handover is performed. Note that, when executing the handover, the overall quality adjustment unit 1402 determines a target SIR based on information provided from the uplink selection / synthesis unit 1401, and transmits the value through the quality adjustment unit of each base station related to the handover. The power control unit 1108 is configured to be notified.

The exchange control unit 1403 monitors the reception status of each mobile station 130 notified from the upper layer, that is, information on the reception strength of the signal received from each base station around the mobile station, and executes handover. Alternatively, it is means for determining stop. The exchange control unit 1403 determines whether the execution or stop of the determined handover is performed by the uplink selection combining unit 14.
01 and the overall quality adjustment unit 1402.

(B) Communication Operation Hereinafter, the contents of the communication operation executed in the CDMA communication system having the system configuration shown in FIG. 1 will be described. Note that, among the communication operations described below, each of the quality adjustment units 1107, 1207, and 130 of the base station and the mobile station.
7 and the switching operation of the outer loop control position performed at the time of handover, that is, the switching operation of the outer loop control position from the base station to the exchange is a unique operation corresponding to the present invention. . First, the normal operation will be described in order.

(B-1) Location Registration Operation Base stations 110 and 12 constituting a CDMA communication system
0, pilot signals that define the connection area of each base station are transmitted by pilot signal transmitting units 1114 and 1214.
It is generated at 14 and radiated into space under constant transmission power (see FIG. 2).

Immediately after the power is turned on, one mobile station 130 searches for a pilot signal transmitted from each base station, and transmits an access packet to the base station having the highest received power. Then, the location of the own station is registered. This location registration data is registered in the database on the base station side.

(B-2) Downlink Communication Operation (b-2-1) Operation of Base Station Next, downlink communication operation will be described. First, data provided from a public network or the like is transmitted from an exchange to a base station in an area where a mobile station is registered. Here, it is assumed that base station 110 is currently connected to mobile station 130.

[0059] Downlink transmission data sent to base station 110 is error-correction-coded in channel encoder 1102, and then output to channel multiplexing section 1103.
When the downlink transmission data is input, channel multiplexing section 1103 performs time division multiplexing on the transmission power control bits (transmission power control information of the mobile station) given from transmission power control section 1108 and outputs the multiplexed data.

The data multiplexed in channel multiplexing section 1103 is spread-modulated in spreading modulation section 1104. The transmission gain of the spread-modulated data is adjusted by a variable gain transmission amplifier 1105, and the transmission radio unit 1
The signal is converted into a signal in a wireless band by 106 and radiated to a mobile station 130 located in its own area.

(B-2-2) Operation of mobile station (1) Decoding operation The mobile station 130 supplies its received signal including the signal radiated from the base station 110 to the reception radio section 1313,
The received signal is demodulated from a radio band to a signal in a spread band. The demodulated signal is input to a reception AGC amplifier 1312, where the gain is adjusted to match a predetermined signal level, and then A / D converted and digitized.

The rake receiver 1311 extracts a signal addressed to itself by despreading processing, and thereafter performs multipath synthesis of the same signal arriving at itself via different propagation paths. The data multi-pass-combined in the rake receiver 1311 is input to a channel decoder 1310, error-corrected, and decoded into user data (downlink received data).

(2) Downlink Transmission Power Control Operation At the same time as the decoding operation, the mobile station 130 performs the following downlink transmission power control operation. First, desired signal power and interference power measured by rake receiver 1311 are provided from rake receiver 1311 to transmission power control section 1308, and the current reception SIR is calculated.

On the other hand, the presence or absence of a frame error due to the CRC monitored by the channel decoder 1310 is determined by the quality adjustment unit 13.
07, which is used to determine whether the current communication state is excessive or degraded with respect to the target quality. This determination algorithm is a control operation unique to the present invention. However, since the contents of this operation are used in the same way in the operation in the uplink (base station or exchange), the description will be given later. Now, the determination result in the quality adjustment unit 1307 is provided to the transmission power control unit 1308.

The transmission power control section 1308 uses the determination result of the quality adjustment section 1307 for calculating downlink transmission power control bits. That is, if the communication quality is excessive, the target SIR held in the transmission power control unit 1308 is lowered, and if the communication quality is deteriorated, the target SIR is raised.
The transmission power control bit is calculated by comparing the target SIR with the reception SIR. Channel multiplexing section 1303 multiplexes the downlink transmission power control bits calculated by transmission power control section 1308 in the uplink data signal, and notifies connected base station 110.

(3) Uplink Transmission Power Control Operation In the mobile station 130, the following uplink transmission power control operation is performed. First, the reception AGC amplifier 1
The input power level before control and the output level after control from 312, and the uplink transmission power control bit separated from the rake receiver 1311 are used by the TPC gain calculator 130.
9 is input. The TPC gain calculator 1309 calculates the TPC gain from these values, gives the value to the variable gain transmission amplifier 1305, and uses it for control of the uplink transmission power.

(B-3) Uplink Communication Operation (b-3-1) Operation of Mobile Station Next, an uplink communication operation will be described. Also in this case, it is assumed that the mobile station 130 connects to the nearest base station 110 as in the case of the downlink. Now, data from the user is transmitted to the channel encoder 13 in the mobile station 130.
02, and the channel multiplexing unit 13
03. In channel multiplexing section 13003, transmission power control bits input from transmission power control section 1308 are time-division multiplexed with user data, and provided to spreading modulation section 1304 at the subsequent stage.

In spreading modulator 1304, the data multiplexed in channel multiplexing unit 1303 is spread-modulated and output. The transmission gain of the spread-modulated data is adjusted by a variable gain transmission amplifier 1305, and transmitted as a signal in a radio band from a transmission radio section 1306 to a radio channel.

(B-3-2) Operation of base station (1) Decoding operation The signal transmitted from transmission radio section 1306 is received by reception radio section 1113 of each base station via a radio propagation path. Each received data is received by an AGC amplifier 1112
After that, the signal is adjusted to a predetermined level, A / D converted, and input to the rake receiver 1111.

In rake receiver 1111, this signal is despread, and further multipath-combined. The data after multipath combining is then provided to a channel decoder 1110, where the data is corrected for errors, decoded, and
Sent to

(2) Uplink Transmission Power Control Operation At the same time as the decoding operation, the base station 110 performs the following uplink transmission power control operation. First, desired signal power and interference power measured by rake receiver 1111 are provided to transmission power control section 1108, and reception SIR is calculated at each time interval at which transmission power control is updated.

The reception SIR calculated by transmission power control section 1108 is then converted by channel decoder 1110
Are converted into reception SIRs in frame units by the channel decoder 1110, and become reception information of decoded uplink data.

On the other hand, the presence or absence of a frame error due to the CRC monitored by the channel decoder 1110 is determined by the quality adjustment unit 11.
07, which is used to determine whether the current communication state is excessive or degraded with respect to the target quality. This determination algorithm is a control operation unique to the present invention.

As shown in FIG. 3B, the quality adjustment unit 1107 controls the observation section T in inverse proportion to the set target FER.
During this period, a frame error sequence is observed, and if at least one error is observed, the target SIR is raised by an appropriate constant value Δ [dB]. If no error is observed, the target SIR is raised by Δ [dB].
The control is performed to lower only the value.

That is, in the case of the present invention, the update interval of the target SIR is also T. This algorithm is limited to a finite section corresponding to the target FER in which the observation section of the frame error sequence is set, and there is no need to use past observation results for future control. As a function of the base station alone,
It is easily possible to actively switch whether to implement the function as a function of the exchange, which is the upper station.

On the other hand, in the case of the conventional algorithm for calculating the estimated FER by the weighted averaging method, FIG.
As shown in (A), since the estimated FER at the time of switching is used as a parameter in the calculation of the estimated FER at the subsequent stage, strict time synchronization is required for the transfer.

Further, in the case of the conventional method, if there is an error in the communication data, the effect is prolonged. However, in the case of the present invention, such an effect is limited to a finite section of the minimum unit. The effect of being limited is also expected.

The quality adjustment section 1107 employs an algorithm for controlling the target SIR based on the presence or absence of an error in the update section, but the number of errors N_e
An algorithm for changing the update value Δ [dB] of the target SIR according to rr may be employed. By employing this algorithm, the convergence time until the outer loop control becomes stable can be shortened.

FIG. 4 shows a simulation result of the control accuracy when the above-mentioned algorithm is adopted and a simulation result of the control accuracy when the conventional algorithm is adopted. FIG. 4 shows the F measured every 50,000 frames when the above-described algorithm is used for setting the target FER in both the mobile station 130 and the base station 110.
This is a graph in which 50 samples of ER were collected, and the standard deviation thereof was graphed within a range of FER maximum 4 [%].

As shown in FIG. 4, in the conventional algorithm, the control error increases as the target FER decreases, but in the algorithm of the present invention, the control error can be made substantially constant irrespective of the size of the target FER to be set. Is recognized.

Now, the result of the determination is transmitted to the quality adjusting unit 11.
07 to the transmission power control section 1108, which is used as data for calculating uplink transmission power control bits. That is, if the communication quality is excessive,
The target SIR held in the transmission power control unit 1108 is lowered, and if the state is deteriorated, the target SIR is raised.
The transmission power control bit is calculated by comparing the received SIR with the IR. Channel multiplexing section 1103 multiplexes the uplink transmission power control bits calculated in transmission power control section 1108 into a downlink data signal, and notifies connected mobile station 130.

(3) Downlink Transmission Power Control Operation The base station 110 performs the following downlink transmission power control operation. First, the reception AGC amplifier 1
The input power level before control and the output level after control from 112 and the uplink transmission power control bit separated from the rake receiver 1111 are converted by the TPC gain calculator 110.
9 is input. The TPC gain calculation section 1109 calculates a TPC gain from these values, gives the value to the variable gain transmission amplifier 1105, and uses it for controlling downlink transmission power.

(B-3) Communication Operation at Handover The above operation was a communication operation in a situation where no handover was performed. Hereinafter, a communication operation performed at the time of handover will be described.

(B-3-1) Operation of Mobile Station At the time of handover, the mobile station 130 performs synthesis of downlinks coming from a plurality of base stations (in FIG. 1, base stations 110 and 120) by using a rake receiver. 1311.

Here, rake receiver 1311 performs despreading of the received signal using a spreading code unique to each of base station 1 and base station 2, and then performs channel decoding on the synthesized signal of the obtained correlation signal. Output to the device 1310. Since the processing in the channel decoder 1310 is the same as that in the normal operation, the description is omitted here.

Next, a description will be given of an uplink transmission power control operation performed by the mobile station 130 at the time of handover. At the time of handover, the mobile station 130 is notified of the individually calculated uplink transmission power control bits from the base stations 110 and 120 involved in the handover. However, considering the gain in the handover state, the communication quality per base station can be reduced, so the quality reported at this time is sufficient to maintain the quality required in the handover state. .

Here, mobile station 130 performs an operation of increasing the transmission power only when the transmission power control bits given from base stations 110 and 120 both indicate that the transmission power is to be increased. . On the other hand, if the transmission power control bit of any one of the stations includes the content indicating that the transmission power is to be “decreased”, the mobile station 130 transmits the signal with the transmission power lowered. I do.

(B-3-2) Operations of Base Station and Exchange Station On the other hand, uplink combining at the time of handover is performed in the exchange station 140. That is, the decoded uplink data received and decoded at each of the base stations 110 and 120 involved in the handover is:
It is input to uplink selection / combination section 1401 of exchange 140. The uplink selection / synthesis unit 1401 selects higher-quality data from the two decoded data, and uses this as decoded uplink decoded data. Here, the selection of the decoded data is performed for each frame using the result of the error correction by the CRC, the observed value of the received SIR in the frame section, and the like. It should be noted that the selected decoded data is then provided to an upper layer signal processing unit through an uplink selection / combination unit 1401.

Finally, the procedure for changing the outer loop control position at the time of handover will be described. This changing procedure corresponds to another control operation unique to the present invention. FIG. 5 shows a conceptual diagram thereof. The outer loop control at the time of handover is executed by the overall quality adjustment unit 1402 in the exchange 140, as shown in FIG. Incidentally, during normal communication (when not in the handover state), as shown in FIG. 5A, the quality adjustment unit of the connected base station, for example, the quality adjustment unit 1107 of the base station 110 performs the configuration. . That is, the change of the outer loop control position is a change of the control position between the base station and the exchange.

The switching from the normal connection to the handover connection is performed by the exchange control unit 1403. The exchange control unit 1403 constantly monitors pilot signal reception information (reception SIR information) of each base station in the mobile station 130, which is notified as an uplink upper layer message, and receives the reception signal from the connected base station. When the received power of the pilot signal to be transmitted falls below a predetermined level, execution of a handover and a target base station are determined.

The contents of this decision are determined by the exchange control unit 1403 by the uplink selection / combination unit 1401 and the overall quality adjustment unit 1
402 is notified. In each unit receiving the notification, the operation mode is switched from the normal communication mode to the handover mode. That is, the exchange control unit 1403 controls the uplink selection / combination unit 1401
CRC result for each frame and received SIR per frame
An instruction is issued to execute frame selection synthesis based on the above, and an instruction is issued to the overall quality control unit 1402 to change the outer loop control position.

Upon receiving the instruction, the overall quality control unit 14
02 is the quality adjustment units 1107 and 12 of the base stations (the base stations 110 and 120 in this example) related to the handover.
07, the target SIR value determined by the outer loop control performed by the base station (here, the base station 110) immediately before the handover is set. Further, the overall quality control unit 1402 includes the quality adjustment units 1107 and 1207.
Is stopped, and thereafter, an instruction is given to determine the transmission power control according to the target SIR set by itself.

Upon receiving the combined frame error sequence from uplink selection / combination section 1401, overall quality control section 1402 determines whether to increase or decrease the target SIR according to the above-described determination algorithm (that is, the observation section inversely proportional to target FER). The target SIR is determined to be raised or lowered according to the observation result of T), and the value is set to the quality adjustment units 1107 and 1 of each base station.
Notify 207.

At this time, the switching center 140 sends the target SI
Quality adjustment units 1107 and 1 that have been notified of R increase / decrease
Reference numeral 207 denotes a transmission power control unit 1108 with the notification content as it is.
And 1208. Subsequent transmission power control operations are the same as in the above-described normal operation.

When the end of the handover connection is determined by the exchange control section 1403, the exchange control section 1403 instructs the uplink selection / combination section 1401 to stop the frame selection / combination, and the mobile station A process is performed in which received data from the base station determined to maintain the connection with 130 is used as uplink data.

On the other hand, switching center control section 1403 instructs overall quality control section 1402 to shift the control position of the outer loop to the base station side determined to maintain the connection with the mobile station. put out. Upon receiving this notification, the overall quality control unit 1402 instructs the quality adjustment unit 1207 of the base station determined to maintain the connection with the mobile station 130, for example, the base station 120, to perform the outer loop control operation. Send.

After that, the quality adjustment unit 12 of the base station 120
At 07, the outer loop control is continued using the target SIR value immediately before receiving the command. As described above, in the present embodiment, the overall quality adjustment unit 1402 sets the target S before and after switching between the handover connection and the normal connection.
Since the IR is managed and the quality is comprehensively controlled, continuity of communication quality is guaranteed before and after the handover connection.

(C) Effects of the Embodiment As described above, in the CDMA communication system according to the present embodiment, the quality adjustment units are installed in both the exchange and the base station, and the mobile station connects to a plurality of base stations. By switching the position of the outer loop control between handover and normal communication in which the mobile station connects only to a single base station, the connection state between the base stations at the time of handover while obtaining the reception gain by handover. Imbalance can be eliminated.

In addition, by applying a determination algorithm for limiting an observation section to the quality adjustment unit of each station (exchange station, base station, mobile station), the above-described switching of the outer loop control position can be realized, The outer loop control error can be reduced as compared with the exponential weighted FER estimation algorithm which is a technique.

(D) Other Embodiments In the above embodiment, no specific description of a mobile station has been given, but the present invention can be applied to a portable cellular phone, a portable information terminal, a car phone, and the like. .

In the above embodiment, the case where the target FER is controlled based on only the error information observed within a single observation section when the quality adjustment is performed by the quality adjustment unit has been described. The target FER may be controlled in consideration of information of several sections past the section.

Further, the control of the target FER based on only the error information observed in a single observation section may be executed only immediately after the switching, and may be controlled in consideration of past observation results in other sections. .

Also, a case has been described in which a period is set in the observation section that is inversely proportional to the target FER. However, the observation section can be fixed and can be dealt with by changing the determination criteria.

[0104]

As described above, according to the present invention, the reception by handover is performed by switching the control position of the outer loop of the uplink between the base station side and the exchange side between the handover connection and the other cases. Gain can be obtained, and imbalance in the connection state between base stations at the time of handover can be corrected.

Also, according to the present invention, only in accordance with the reception quality observed within a single observation period which is a finite period,
By increasing or decreasing the target reception power value used as a criterion at the time of the next transmission power control of the partner station to be controlled,
The control error can be made uniform as compared with the conventional method.

[Brief description of the drawings]

FIG. 1 illustrates an example embodiment of a CDMA communication system.

FIG. 2 is a diagram illustrating an example of a frame configuration.

FIG. 3 is a diagram showing a conceptual configuration of a determination algorithm in the present invention.

FIG. 4 is a diagram showing an error characteristic of a measured FER with respect to a target FER.

FIG. 5 is a diagram showing a conceptual configuration of an outer loop control position switching operation according to the present invention.

[Explanation of symbols]

110, 120: base station, 130: mobile station, 140: exchange station, 1107, 1207, 1307: quality adjustment unit, 1
108, 1208, 1308 ... transmission power control section, 140
1. Uplink selection / synthesis unit, 1402 General quality adjustment unit, 1403 Switching center control unit.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5K022 EE01 5K060 BB07 CC00 CC04 DD04 FF00 HH06 LL01 5K067 AA23 BB02 CC10 DD13 DD27 EE02 EE10 EE22 EE24 GG08 GG09 HH05 JJ36

Claims (16)

[Claims] In a transmission power control method in a CDMA communication system, during a normal connection in which a mobile station communicates only with a single base station, a quality adjustment unit in a base station connected to the mobile station performs an uplink according to reception quality. When the mobile station performs handover connection in which the mobile station is connected to a plurality of base stations, the quality adjustment unit in the exchange accommodating the base station targeted for handover performs uplink power control according to the combined reception quality. A transmission power control method comprising: 2. A transmission power control method in a CDMA communication system, comprising: observing reception quality of a received signal received from a partner station to be controlled for each observation section given in a finite period; A transmission power control method characterized by increasing or decreasing a target reception power value used as a criterion in a next transmission power control of a partner station to be controlled, only in accordance with observed reception quality. 3. The transmission power control method according to claim 1, wherein the reception quality of a reception signal received from a partner station to be controlled is observed for each observation section given in a finite period, and the single observation section is used. A transmission power control method characterized in that a target reception power value used as a criterion for the next transmission power control of a partner station to be controlled is increased or decreased only in accordance with the reception quality observed in the transmission power. 4. The transmission power control method according to claim 2, wherein the observation section is set to a period inversely proportional to a frame error rate. 5. The transmission power control method according to claim 2, wherein when a frame error is detected in the observation section, a target reception power value used as a criterion is increased.
A transmission power control method, characterized in that when a frame error is not detected in the observation section, control is performed to reduce a target reception power value used as a criterion. 6. The transmission power control method according to claim 2, wherein when a frame error is detected in the observation section, a target reception power value used as a criterion according to the number of detections. A transmission power control method, wherein when a frame error is not detected in the observation section, the target reception power value used as a criterion is reduced. 7. A transmission power control device mounted on a base station of a CDMA communication system, wherein during a normal connection in which a mobile station communicates only with a base station on which the mobile device is mounted, according to reception quality observed in the own device. When the mobile station performs a handover connection in which the mobile station is connected to a plurality of base stations including the base station on which the mobile device is mounted, the mobile station transmits a notification from the exchange station accommodating the base station on which the mobile device is mounted. A transmission power control apparatus, comprising: a quality adjustment unit that performs uplink transmission power control in response to the request. 8. A transmission power control apparatus mounted on an exchange of a CDMA communication system, wherein the mobile station performs the above-mentioned simple operation at the time of a normal connection in which the mobile station communicates only with a single base station accommodated by the exchange on which the mobile apparatus is installed. When one base station performs uplink transmission power control, and the mobile station performs handover connection in which the mobile station is connected to a plurality of base stations accommodated by the exchange where the own device is mounted, the own device takes the initiative in uplink transmission. A transmission power control device comprising a quality adjustment unit that performs power control. 9. A transmission power control device mounted on a mobile station, a base station, or a switching station of a CDMA communication system, wherein an observation section in which reception quality of a reception signal received from a partner station to be controlled is given in a finite period. Quality to control increase / decrease of the target reception power value used as a criterion for the next transmission power control of the partner station to be controlled, based on only the reception quality observed within the single observation section A transmission power control device comprising an adjustment unit. 10. The transmission power control device according to claim 9, wherein the quality adjustment unit observes reception quality of a reception signal received from a partner station to be controlled for each observation section given in a finite period, According to only the reception quality observed in the single observation section, the target reception power value used as a criterion at the time of the next transmission power control of the partner station to be controlled is increased or decreased. Transmission power control device. 11. The transmission power control device according to claim 9, wherein the observation section is set to a period inversely proportional to a frame error rate. 12. The transmission power control apparatus according to claim 9, wherein when a frame error is detected in the observation section, a target reception power value used as a criterion is increased, and the transmission power control apparatus increases the target reception power value. A transmission power control apparatus for controlling a target reception power value used as a criterion to be reduced when no frame error is detected in the transmission power control. 13. The transmission power control apparatus according to claim 9, wherein when a frame error is detected in said observation section, a target reception power value used as a criterion according to the number of detections. A transmission power control apparatus, wherein when a frame error is not detected in the observation section, control is performed so as to reduce a target reception power value used as a criterion. 14. CDMA for communication with a mobile station
A base station apparatus using a communication method, wherein the base station apparatus uses a communication method.
A base station device comprising the transmission power control device according to any one of claims 1 to 13. 15. An exchange apparatus accommodating a plurality of base station apparatuses that communicate with a mobile station using a CDMA communication system, wherein the transmission power control according to claim 8 is performed. An exchange device comprising the device. 16. CDMA for communication with a base station
A mobile station device using a communication system, wherein the mobile station device comprises:
3. A mobile station device comprising the transmission power control device according to any one of 3.