JP2012178877A - Radio communication system, base station, and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce interference which a transmission timing control signal causes to other channels in its own cell and interference quantity it causes to other cells in a downlink in a radio communication system based on an adaptive transmission timing control method.SOLUTION: In a radio communication system based on an adaptive transmission timing control method, a base station is configured to extract as a valid path electric power paths exceeding a prescribed threshold value from a delay profile of a terminal station, select as a reference path a path having the maximum electric power or a path at the head from valid paths, as well as calculate the time difference between the arrival time of the reference path and the prescribed maximum arrival time, and transmit the calculated time difference as a transmission timing control signal to the terminal station, and the terminal station is configured to adjust transmission timing to the base station according to its time difference. The base station transmits a transmission timing control signal to the terminal station if only it has determined a transmission timing change is necessary in the terminal station.

Description

  The present invention relates to a radio communication system, a base station, and a radio communication method, and particularly to a radio communication system, a base station, and a radio communication method having an adaptive transmission timing control function.

  In a transmission system based on DS-CDMA (Direct Spread-CDMA, direct spreading code division multiple access), a base station can ensure that the base station receives the reference path at the same time by synchronizing the reception timing of the reference path. In this case, the orthogonality between the reference paths is ensured and the frequency utilization efficiency is improved.

  Here, the effective path refers to a path that exceeds a predetermined power threshold, and the reference path refers to the effective path having the maximum power or the head (that is, having the shortest arrival time).

  An adaptive transmission timing control method is known as a method for maintaining reception timing synchronization of a reference path between terminal stations in a base station (Non-Patent Document 1).

  Hereinafter, a case where an adaptive transmission timing control method is applied in a conventional wireless communication system will be described.

  FIG. 5 shows delay profiles before and after applying the adaptive transmission timing control method.

  FIG. 5A shows the result of obtaining the delay profiles for the two terminal stations 1 and 2 in the base station.

The base station, the arrival time difference T _max -T ₁ between the maximum arrival time T _max that is assumed _(fixed value) and the arrival time T ₁ of the reference path of the terminal station 1 calculated for arrival path timing The terminal station 1 is notified as an offset value.

Similarly, the base station, the arrival time difference T _max -T ₂ between the arrival time T ₂ of the reference path of the maximum arrival time T _max and the terminal station 2 is calculated and notified to the terminal station 2 as a timing offset value .

  The terminal stations 1 and 2 add these timing offset values to a predetermined initial value, thereby transmitting the transmission timing with an offset.

At this time, as shown in FIG. 5B, the synchronization of the reference path timing between the terminal stations 1 and 2 is established at the position of the maximum arrival time T _{max in} the base station.

  In the case where no effective path exceeding the threshold is detected in the base station, a method of using the path having the maximum power as the reference path can be considered as an adaptive transmission timing control method.

However, if this path timing is incorrect, if the path is moved to the position of T _max , the true path timing position is greatly deviated from the searchable range (search range). It can happen that the path timing is lost.

  FIG. 6 is a delay profile before and after adaptive transmission timing control when a path is erroneously detected in the conventional wireless communication system.

Here, it is assumed that the transmission timing is delayed so that the reference path arrives at the base station at the arrival time of T _max in FIG.

Since the arrival time _Tmax is the longest arrival time of the expected signal arrival times, it is considered that a time later than this time is not considered as a detectable range (search range) in the design of the wireless communication system. It is done.

  FIG. 6A shows a case where an incorrect path is selected as the reference path.

When this erroneously detected path is moved to the position of T _max , referring to FIG. 6B, the true path is out of the detectable range, and the base station loses sight of the terminal station path.

  As another method of performing adaptive transmission timing control when a path exceeding the threshold is not detected, a method of instructing the terminal station not to change the transmission timing so far is also conceivable (Patent Document 1).

Japanese Patent Application No. 2006-308524

Kawamura and two others, IEICE Technical Report, Radio Communication System (RCS), 2003, 103, 363, p. 13-18

  The following analysis was made by the present inventors.

  However, in the method disclosed in Patent Document 1, when a path exceeding the threshold is not detected for a long time due to shadowing or the like, a wasteful control signal intended only to instruct timing maintenance Will continue to be sent. Such a control signal may be an interference source for other channels in the own cell and an interference source for other cells.

  Therefore, in the radio communication system based on the adaptive transmission timing control method, it is a problem to reduce the amount of interference that the transmission timing control signal gives to other channels in the own cell and the amount of interference given to other cells in the downlink.

  A wireless communication system according to a first aspect of the present invention includes a base station and a terminal station, and the base station uses a path of power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path. And selecting the maximum power path or the leading path from among the effective paths as a reference path, and obtaining a time difference between the arrival time of the reference path and a predetermined maximum arrival time to transmit to the terminal station The wireless communication system is configured to transmit as a control signal, and the terminal station is configured to adjust transmission timing to the base station according to the time difference, and the base station includes the reference path The transmission timing control signal is transmitted only when the signal is detected.

  A radio communication system according to a second aspect of the present invention includes a base station and a terminal station, and the base station uses an effective path for a power path exceeding a predetermined threshold from the delay profile of the terminal station. And selecting the maximum power path or the leading path from among the effective paths as a reference path, and obtaining a time difference between the arrival time of the reference path and a predetermined maximum arrival time to transmit to the terminal station It is configured to transmit as a control signal, and the terminal station is a wireless communication system configured to adjust transmission timing to the base station according to the time difference, wherein the base station is configured to transmit the terminal station The transmission timing control signal is transmitted only when it is determined that the transmission timing needs to be changed.

  The base station according to the third aspect of the present invention extracts a path with power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path, and selects the path with the maximum power or the head from the effective path. And a base station configured to obtain a time difference between the arrival time of the reference path and a predetermined maximum arrival time and transmit it as a transmission timing control signal to the terminal station, The transmission timing control signal is transmitted only when the reference path is detected.

  The base station according to the fourth aspect of the present invention extracts a path with power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path, and selects the path with the maximum power or the head from the effective path. And a base station configured to obtain a time difference between the arrival time of the reference path and a predetermined maximum arrival time and transmit it as a transmission timing control signal to the terminal station, The terminal station is configured to transmit the transmission timing control signal only when the terminal station determines that the transmission timing needs to be changed.

  The wireless communication method according to the fifth aspect of the present invention includes: (a) extracting a power path exceeding a predetermined threshold from a delay profile of a terminal station as an effective path at a base station; and (b) The base station selects a maximum power path or a leading path from the effective paths as a reference path, and (c) arrival of the reference path only when the reference path is detected. Obtaining a time difference between the time and a predetermined maximum arrival time and transmitting it as a transmission timing control signal from the base station to the terminal station; and (d) transmitting the transmission timing to the base station according to the time difference. And a step of adjusting.

  A wireless communication method according to a sixth aspect of the present invention includes: (a) extracting a power path exceeding a predetermined threshold from a delay profile of a terminal station as an effective path at a base station; (b) The base station selects a maximum power path or a leading path from the effective paths as a reference path at the base station, and (c) determines whether or not transmission timing needs to be changed at the terminal station. And (d) determining a time difference between the arrival time of the reference path and a predetermined maximum arrival time only when it is determined that the transmission timing needs to be changed in the determination step. Transmitting to the terminal station as a transmission timing control signal from the base station to the terminal station, and (e) the terminal station sets the transmission timing to the base station to the time difference. Flip characterized in that it comprises a, and adjusting at said terminal station.

  A wireless communication method according to a seventh aspect of the present invention includes: (a) extracting a power path exceeding a predetermined threshold value from a delay profile of a terminal station as an effective path at a base station; and (b) The base station selects a maximum power path or a leading path from the effective paths as a reference path, and (c) arrival of the reference path only when the reference path is detected. A step of obtaining a time difference between the time and a predetermined maximum arrival time and transmitting the time difference as a transmission timing control signal from the base station to the terminal station.

  The wireless communication method according to the eighth aspect of the present invention includes: (a) a step of extracting a power path exceeding a predetermined threshold value from a delay profile of a terminal station as an effective path at a base station; The base station selects a maximum power path or a leading path from the effective paths as a reference path at the base station, and (c) determines whether or not transmission timing needs to be changed at the terminal station. And (d) determining a time difference between the arrival time of the reference path and a predetermined maximum arrival time only when it is determined that the transmission timing needs to be changed in the determination step. And transmitting to the terminal station as a transmission timing control signal from the base station to the terminal station.

  In the radio communication system according to the first deployment mode, the base station changes the transmission timing in the terminal station when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold value. It is preferably configured to determine that it is not necessary.

  In a radio communication system according to a second deployment mode, the base station has a time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station equal to or less than a predetermined threshold value. In some cases, it is preferable that the transmission timings of both the terminal stations are determined not to be changed.

  In the wireless communication system according to the third development form, the predetermined threshold may be a CP (Cyclic Prefix) length.

  The base station according to the fourth embodiment determines that the terminal station does not need to change the transmission timing when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold value. It is preferable to be configured as described above.

  The base station according to the fifth mode of deployment, when the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is equal to or less than a predetermined threshold, It is preferably configured to determine that there is no need to change the station transmission timing.

  In the base station of the sixth development form, the predetermined threshold may be a CP (Cyclic Prefix) length.

  In the wireless communication method according to the seventh development mode, in the determination step (c), when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold, the transmission timing is transmitted at the terminal station. It is preferable to determine that there is no need to change the value.

  In the radio communication method according to the eighth embodiment, in the determination step (c), the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is a predetermined threshold. When the value is less than or equal to the value, it is preferable to determine that it is not necessary to change the transmission timings of the two terminal stations.

  In the wireless communication method according to the ninth development mode, the predetermined threshold value in the determination step (c) may be a CP (Cyclic Prefix) length.

  In the radio communication method according to the tenth development mode, in the determination step (c), when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold value, transmission timing is transmitted at the terminal station. It is preferable to determine that there is no need to change the value.

  In the wireless communication method according to the eleventh embodiment, in the determination step (c), a time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is a predetermined threshold. When the value is less than or equal to the value, it is preferable to determine that it is not necessary to change the transmission timings of the two terminal stations.

  In the radio communication method according to the twelfth development mode, the predetermined threshold value in the determination step (c) may be a CP (Cyclic Prefix) length.

  In the wireless communication system according to the present invention, when a path exceeding the threshold is not detected in the base station, the base station determines that it is not necessary to change the timing of the transmission signal of the terminal station. The transmission timing control signal is not transmitted to the station.

  Thereby, in the downlink, the transmission timing control signal can prevent interference with other channels in the own cell and interference with other cells.

It is a block diagram of the base station in the radio | wireless communications system based on the Example of this invention. It is a block diagram of the terminal station in the radio | wireless communications system based on the Example of this invention. It is a flowchart of operation | movement of the transmission timing control signal synthetic | combination determination part with which the base station in the radio | wireless communications system which concerns on the Example of this invention was equipped. It is a sequence diagram of adaptive transmission timing control in the wireless communication system according to an embodiment of the present invention. It is a delay profile before and after adaptive transmission timing control in the conventional radio | wireless communications system. It is a delay profile before and after adaptive transmission timing control when a path is erroneously detected in a conventional wireless communication system.

  The adaptive transmission timing system according to the present invention does not transmit a transmission timing control signal from the base station 10 to the terminal station 30 when the base station 10 does not detect the reference path of the terminal station 30. Since the terminal station 30 cannot detect the transmission timing control signal, the terminal station 30 determines to maintain the current transmission timing.

  When the base station 10 determines that the adaptive transmission timing control is in a converged state and there is no need to change the timing of the transmission signal of the terminal station 30, the base station 10 transmits a transmission timing control signal to the terminal station 30. I will not do it. Since the terminal station 30 cannot detect the transmission timing control signal, the terminal station 30 determines to maintain the current transmission timing.

  In any of these cases, the transmission timing control signal is not transmitted from the base station 10 to the terminal station 30 to prevent interference of the transmission timing control signal on other channels and other cells in the own cell in the downlink. Can do.

  Next, the present invention will be described with reference to the drawings.

  FIG. 1 is a configuration diagram of a base station 10 in a wireless communication system according to an embodiment of the present invention.

  The base station 10 includes an antenna 11, a DUP (duplexer) 12, a receiving unit 13, a data demodulating unit 14, a delay profile calculating unit 15, a path detecting unit 16, a transmission timing control signal creating unit 17, a transmission timing control signal. A synthesis determination unit 18, a signal synthesis unit 19, and a transmission unit 20 are provided.

  The receiving unit 13 receives a signal from the terminal station 30 via the antenna 11 and the DUP 12 and transmits the signal to the data demodulating unit 14 and the delay profile calculating unit 15.

  The delay profile calculation unit 15 calculates a delay profile using the pilot signal.

  The path detection unit 16 detects an incoming path exceeding a threshold value from the delay profile.

  The data demodulator 14 demodulates the received data using the arrival path timing.

  Furthermore, the path detection unit 16 selects the maximum power among the incoming paths as the reference path.

The transmission timing control signal creation unit 17 calculates the arrival time difference between the maximum arrival time T _max of the reference path and the arrival path in the base station 10, creates a transmission timing control signal including this information, and determines transmission timing control signal synthesis determination Transmit to unit 18.

  Here, if a path exceeding the threshold is not detected, information indicating that a path exceeding the threshold is not detected is also transmitted to the transmission timing control signal synthesis determination unit 18.

  The transmission timing control signal synthesis determination unit 18 determines whether or not to synthesize the transmission timing control signal with other signals, and transmits the transmission timing control signal to the signal synthesis unit 19 when it is determined to synthesize.

  The transmission timing control signal synthesis determination unit 18 determines that the transmission timing control signal is not synthesized when a path exceeding the threshold is not detected. In this case, the transmission timing control signal is not transmitted from the base station 10 to the terminal station 30.

  The signal synthesizer 19 code-multiplexes the transmission timing control signal, pilot signal, and data signal using different orthogonal codes.

  The signal synthesis unit 19 transmits the synthesized signal to the terminal station 30 via the transmission unit 20, the DUP 12, and the antenna 11.

  FIG. 2 is a configuration diagram of the terminal station 30 in the wireless communication system according to the embodiment of the present invention.

  Referring to FIG. 2, the terminal station 30 includes an antenna 31, a DUP 32, a reception unit 33, a signal separation unit 34, a channel estimation unit 35, a transmission timing control signal demodulation unit 36, a signal synthesis unit 37, a transmission timing control unit 38, and a transmission. The unit 39 is provided.

  The reception unit 33 receives a signal from the base station 10 via the antenna 31 and the DUP 32 and transmits the signal to the signal separation unit 34.

  The signal separation unit 34 separates the data signal, the pilot signal, and the transmission timing control signal, and transmits the pilot signal to the channel estimation unit 35 and the transmission timing control signal to the transmission timing control signal demodulation unit 36.

  The channel estimation unit 35 calculates a channel estimation value based on the pilot signal and transmits it to the transmission timing control signal demodulation unit 36.

  The transmission timing control signal demodulator 36 demodulates the transmission timing control signal using the channel estimation value, and transmits the transmission timing offset amount in the demodulated data to the transmission timing controller 38.

  Here, when demodulation of the transmission timing control signal fails, the previous transmission timing is transmitted to the transmission timing control unit 38.

  The signal synthesizer 37 synthesizes the data signal and the pilot signal and transmits them to the transmission timing controller 38.

  The transmission timing control unit 38 delays the transmitted signal according to the transmission timing offset amount, and then transmits the signal to the base station 10 via the transmission unit 39, the DUP 32, and the antenna 31.

  Below, operation | movement of the transmission timing control signal synthetic | combination determination part 18 with which the base station 10 was equipped is demonstrated in detail.

  FIG. 3 is a flowchart of the operation of the transmission timing control signal synthesis determination unit 18 provided in the base station in the wireless communication system according to the embodiment of the present invention.

  The transmission timing control signal synthesis determination unit 18 does not synthesize a transmission timing control signal when a path exceeding the threshold is not detected and it is determined that a reference path is not detected (No in step S11).

  In this case, the transmission timing control signal is not transmitted from the base station 10 to the terminal station 30, and the terminal station 30 cannot detect the transmission timing control signal, so the current transmission timing is maintained.

  By not transmitting the transmission timing control signal from the base station 10 to the terminal station 30, it is possible to reduce interference that the transmission timing control signal gives to other channels in the own cell and interference to other cells in the downlink.

  In addition, in a system in which a cyclic prefix (CP) is inserted in the transmission signal, if the propagation delay difference of the reference path between the terminal stations is within the CP length, the terminal stations in the multiple access by uplink FDMA Is ensured.

Therefore, when the arrival time difference between the reference path and T _max is equal to or shorter than the CP length and the transmission timing control signal synthesis determination unit 18 determines that the reference path has converged (No in step S12), the transmission signal of the terminal station 30 Since it is not necessary to change the transmission timing, the transmission timing control signal may not be synthesized.

  FIG. 4 is a sequence diagram of adaptive transmission timing control in the wireless communication system according to the embodiment of the present invention.

  When it is determined that the time difference between the arrival times of the reference paths of the terminal stations 30a and 30b is equal to or less than the CP length (No in step S13), the transmission timing control signal synthesis determination unit 18 transmits the transmission signal between the terminal stations 30a and 30b. Since there is no need to change the transmission timing, the transmission timing control signal may not be synthesized.

  Also in this case, interference that the transmission timing control signal gives to other channels in the own cell and interference to other cells in the downlink can be suppressed.

  The transmission timing control signal synthesis determination unit 18 determines that the reference path is detected, the reference path has not yet converged, and the arrival time of the reference path between the terminal stations 30a and 30b is equal to or greater than the threshold value. Only in the case where the transmission timing control signal is combined (step S14), the transmission timing control signal is determined to be combined (step S14).

10 Base station 11, 31 Antenna 12, 32 DUP (Transmission / reception duplexer)
13, 33 Reception unit 14 Data demodulation unit 15 Delay profile calculation unit 16 Path detection unit 17 Transmission timing control signal creation unit 18 Transmission timing control signal synthesis determination unit 19, 37 Signal synthesis unit 20, 39 Transmission unit 30, 30a, 30b Terminal Station 34 Signal separation unit 35 Channel estimation unit 36 Transmission timing control signal demodulation unit 38 Transmission timing control unit

Claims (16)

A base station and a terminal station,
The base station extracts a path with power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path, and selects the path with the maximum power or the first path from the effective paths as a reference path. And obtaining a time difference between the arrival time of the reference path and a predetermined maximum arrival time and transmitting it as a transmission timing control signal to the terminal station,
The terminal station is a wireless communication system that adjusts transmission timing to the base station according to the time difference,
A wireless communication system in which the base station transmits the transmission timing control signal only when it is determined that the transmission timing needs to be changed in the terminal station.   The base station determines that it is not necessary to change transmission timing in the terminal station when a time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold value. The wireless communication system described.   If the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is equal to or less than a predetermined threshold, the base station determines the transmission timing of the both terminal stations. The wireless communication system according to claim 1, wherein it is determined that there is no need to change.   The wireless communication system according to claim 2 or 3, wherein the predetermined threshold value is a CP (Cyclic Prefix) length. A path with power exceeding a predetermined threshold is extracted as an effective path from the delay profile of the terminal station, and a path with maximum power or a leading path is selected as the reference path from the effective paths, and the reference path A base station that obtains a time difference between the arrival time of and a predetermined maximum arrival time as a transmission timing control signal to the terminal station,
A base station that transmits the transmission timing control signal only when the terminal station determines that the transmission timing needs to be changed.   The base station according to claim 5, wherein when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold, the terminal station determines that there is no need to change transmission timing.   When the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is equal to or smaller than a predetermined threshold, there is no need to change the transmission timing of the both terminal stations. The base station according to claim 5, wherein   The base station according to claim 6 or 7, wherein the predetermined threshold value is a CP (Cyclic Prefix) length. (A) extracting a path of power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path at the base station;
(B) selecting a maximum power path or a leading path from the effective paths as a reference path in the base station;
(C) determining whether the transmission timing needs to be changed at the terminal station at the base station,
Only when it is determined that the transmission timing needs to be changed in the determination step,
(D) calculating a time difference between the arrival time of the reference path and a predetermined maximum arrival time and transmitting the time difference from the base station to the terminal station as a transmission timing control signal;
(E) The terminal station includes a step of adjusting a transmission timing to the base station in the terminal station according to the time difference.   In the determination step (c), when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold, it is determined that it is not necessary to change the transmission timing in the terminal station. Item 10. The wireless communication method according to Item 9.   In the determination step (c), if the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is less than or equal to a predetermined threshold value, the both terminal stations The wireless communication method according to claim 9, wherein it is determined that there is no need to change the transmission timing.   The wireless communication method according to claim 10 or 11, wherein the predetermined threshold value in the determination step (c) is a CP (Cyclic Prefix) length. (A) extracting a path of power exceeding a predetermined threshold from the delay profile of the terminal station as an effective path at the base station;
(B) selecting a maximum power path or a leading path from the effective paths as a reference path in the base station;
(C) determining whether the transmission timing needs to be changed at the terminal station at the base station,
Only when it is determined that the transmission timing needs to be changed in the determination step,
(D) A wireless communication method including a step of obtaining a time difference between an arrival time of the reference path and a predetermined maximum arrival time and transmitting the difference from the base station to the terminal station as a transmission timing control signal.   In the determination step (c), when the time difference between the arrival time of the reference path and the maximum arrival time is equal to or less than a predetermined threshold, it is determined that it is not necessary to change the transmission timing in the terminal station. Item 14. A wireless communication method according to Item 13.   In the determination step (c), if the time difference between the arrival time of the reference path for the first terminal station and the arrival time of the reference path for the second terminal station is less than or equal to a predetermined threshold value, the both terminal stations The wireless communication method according to claim 13, wherein it is determined that there is no need to change the transmission timing.   The wireless communication method according to claim 14 or 15, wherein the predetermined threshold value in the determination step (c) is a CP (Cyclic Prefix) length.

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