JP2005012276A - Radio receiving device and radio receiving method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent deterioration in reception characteristics and prevent a malfunction of various controls, even if all transmissions by an opposite communication station in a radio communication system employing an IPDL. <P>SOLUTION: Despreading sections 1062-1 to 1062-n applies despreading to an input signal to a demodulating section 106 for each signal of each path. Also, the sections 1062-1 to 1062-n make an inverse spread output in an IPDL section 0 for a path from a base station apparatus of its own cell for executing IPDL among n pieces of cells. Synchronization detecting sections 1064-1 to 1064-n perform synchronization detection using an inverse despread output for each path. Also, if 0 is outputted as an inverse despread output from the corresponding despreading sections 1062-1 to 1062-n, the sections 1064-1 to 1064-n output 0 as a synchronization detection signal too. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a radio reception apparatus and a radio reception method, and more particularly, to a radio reception apparatus and a radio reception method in a radio communication system in which position detection is performed using instantaneous downlink down (IPDL: Idle Period DownLink).
[0002]
[Prior art]
In recent years, mobile communication is required not only for voice and data communication functions but also for service functions that measure the position of a mobile station device and combine it with security and navigation. In a wireless communication system using a CDMA (Code Division Multiple Access) method, various methods such as position detection using a GPS (Global Positioning System) satellite have been proposed. A technique combining a plurality of position detection methods is known.
[0003]
In the CDMA system, the mobile station apparatus can accurately measure the distance from the base station apparatus by performing correlation detection using a spreading code. Then, the mobile station apparatus can measure the distance from the base station apparatus and specify the position of the mobile station apparatus. At this time, in order for the mobile station apparatus to specify the position, it is necessary to measure the distance from at least three base station apparatuses.
[0004]
By the way, in general, in a radio communication system using a CDMA system, spreading codes used by each base station apparatus are different from each other. Therefore, when the mobile station apparatus communicates with the base station apparatus, the spreading code used by the base station apparatus is different from the spreading code used by the surrounding base station apparatus, and the transmission signal from the surrounding base station apparatus is Interference signal. As a result, especially when the mobile station device is located directly below the base station device, the transmission signal from this base station device (hereinafter referred to as “the base station device of its own cell”) becomes an interference signal, It has been difficult to communicate with base station apparatuses, and it has been difficult to measure distances from surrounding base station apparatuses. That is, the mobile station apparatus cannot measure the distance from the three base station apparatuses including the base station apparatus of its own cell, and has a problem that the position cannot be specified.
[0005]
As a method for solving this problem, for example, IPDL described in Chapter 8 of Non-Patent Document 1 and Chapter 9 of Non-Patent Document 2, which are W-CDMA standards, is known. IPDL instantaneously interrupts all transmissions of the base station apparatus for a very short time. Therefore, in the IPDL section of the base station apparatus of the own cell, the interference that the base station apparatus of the own cell gives to the surrounding base station apparatus is 0. Therefore, the mobile station apparatus uses the IPDL section to The distance from the base station apparatus can be measured.
[0006]
The operation of IPDL will be described below with reference to FIG.
[0007]
First, the base station apparatus receives IPDL parameters including timing for performing IPDL from the network, and transmits them to the mobile station apparatus using broadcast information or the like. The mobile station apparatus receives this broadcast information and stores the timing at which IPDL occurs. The base station apparatus performs the IPDL operation at the above timing, that is, instantaneously interrupts all transmissions. The mobile station apparatus measures the distance from the surrounding base station apparatus at the stored IPDL timing and detects the position of the mobile station apparatus.
[0008]
Note that the IPDL section differs for each base station apparatus and is controlled by the network so that the IPDL sections of the base station apparatuses do not overlap. In general, the mobile station apparatus measures the distance from the surrounding base station apparatus using the IPDL section of the base station apparatus of its own cell, but it is also possible to use an IPDL section other than the base station apparatus of its own cell. is there.
[0009]
[Non-Patent Document 1]
3GPP TS 25.214 V4.5.0 (3rd Generation Partnership Project; Technical Specification Group Radio Access Network) (Physical layer processes Re) (FD)
[Non-Patent Document 2]
3GPP TS 25.305 V4.3.0 (3rd Generation Partnership Project) Technical Specification Group Radio Access Network (Stage 2 functional specifier UE)
[0010]
[Problems to be solved by the invention]
However, since all transmissions from the base station apparatus are interrupted in the IPDL section, even if a series of transmission data is error correction encoded, the probability of being correctly decoded due to the instantaneous interruption of the IPDL section decreases. There is a problem in that the reception characteristics of the mobile station apparatus are deteriorated. In addition to the deterioration of reception characteristics, there is a problem that various control malfunctions occur in the mobile station apparatus.
[0011]
Specifically, for example, a mobile station apparatus using a CDMA system can perform despreading processing and detection processing by separating a signal for each of a plurality of paths included in a received signal. However, in the IPDL section of the base station apparatus of the own cell, the path signal from the base station apparatus of the own cell is despread as an invalid signal on which interference signals from other cells and thermal noise are superimposed. . Then, this despreading result is used to detect an invalid signal and RAKE is synthesized as noise. That is, noise is included in the RAKE synthesis result, which causes a reduction in the probability of correct decoding. Further, based on the detection result of the invalid signal, RF (Radio Frequency) control such as AFC (Auto Frequency Control) and AGC (Auto Gain Control) is performed, or self-control is performed. Since a transmission power control command is generated for a cell base station apparatus, a malfunction may be caused.
[0012]
Further, a malfunction in the mobile station apparatus will be described with reference to FIG. 6 taking a random access in W-CDMA as an example.
[0013]
During random access in W-CDMA, an uplink RACH (Random Access Channel) and a downlink AICH (Acquisition Indication Channel) are used.
[0014]
First, the base station apparatus notifies the mobile station apparatus of the power ratio of the AICH transmission power to CPICH (Common Pilot Channel) with constant transmission power as broadcast information in advance. When there is RACH data to be transmitted, the mobile station apparatus transmits a signal called RACH preamble to the base station apparatus. The RACH preamble is a short-term signal including only the identifier of the mobile station apparatus. The mobile station apparatus first transmits a RACH preamble with a predetermined low transmission power, and when neither Ack nor Nack for the RACH preamble can be received from the base station apparatus, the RACH preamble has not reached the base station apparatus. Judgment is made, the transmission power is increased by a predetermined amount, and the RACH preamble is transmitted again (in FIG. 6, the RACH preamble arrives at the base station apparatus for the third time).
[0015]
When receiving the RACH preamble, the base station apparatus transmits Ack / Nack using AICH to the mobile station apparatus that has transmitted the RACH preamble. Specifically, Ack is transmitted to allow the mobile station apparatus that has transmitted the RACH preamble to transmit RACH data (see FIG. 6A), and Nack is transmitted to reject transmission of RACH data (see FIG. 6A). (Refer FIG.6 (b)).
[0016]
Then, the mobile station apparatus determines whether or not the AICH data has been received. If the Ack is received, the mobile station apparatus transmits the RACH data (see FIG. 6A). If the NACK is received, the mobile station apparatus transmits the RACH preamble. After the transmission power is reset to the initial state, RACH preamble transmission is started again (see FIG. 6B). In the mobile station apparatus, the transmission timing of the RACH preamble and the reception timing of Ack / Nack that is AICH data have a specific relationship, and the mobile station apparatus can determine which RACH preamble is the Ack / Nack. it can.
[0017]
Here, since transmission of all channels including AICH is interrupted in the IPDL section, if the transmission timing of Ack / Nack for the RACH preamble transmitted by the mobile station apparatus overlaps with the IPDL section, this Ack / Nack is There is a possibility that an error may occur in the determination whether or not the AICH data is received in the mobile station apparatus without being transmitted. Further, when determining whether or not the mobile station apparatus has received AICH data, a power ratio with respect to CPICH is used. However, since CPICH is also momentarily interrupted in the IPDL section, it is not possible to correctly determine whether to receive AICH data.
[0018]
The present invention has been made in view of the above points, and in a wireless communication system employing IPDL, even when all transmissions by a communication partner station are momentarily interrupted, the reception characteristics are prevented from being deteriorated, and various types of control are performed. An object of the present invention is to provide a wireless reception device and a wireless reception method that can prevent malfunction.
[0019]
[Means for Solving the Problems]
The radio receiving apparatus of the present invention controls a receiving operation by excluding a signal corresponding to a path from a communication partner station at the IPDL timing, detecting means for detecting an IPDL timing at which the communication partner station instantaneously interrupts all transmissions And a receiving operation control means.
[0020]
According to this configuration, when the transmission from the communication partner station is interrupted, the reception operation is controlled without using the signal corresponding to the path from the communication partner station, so that only the interference component and the noise component are present. The included path signals can be ignored, the reception characteristics can be prevented from deteriorating, and various control malfunctions can be prevented.
[0021]
In the radio reception apparatus of the present invention, the reception operation control means includes: a despreading unit that outputs 0 as a despread output of a signal corresponding to a path from the communication partner station at the IPDL timing; and a despread output including 0 A configuration having a synchronous detection unit that performs synchronous detection and a RAKE combining unit that performs RAKE combining of synchronous detection results is adopted.
[0022]
According to this configuration, since the despread output of the signal corresponding to the path from the communication partner station at the IPDL timing is set to 0, the synchronous detection and the RAKE synthesis are performed. For example, when handover is performed from the base station apparatus of the own cell in the IPDL to the base station apparatus of the other cell, it is equivalent to RAKE combining only the path signals from the base station apparatus of the other cell. Processing can be performed.
[0023]
In the radio reception apparatus of the present invention, the reception operation control means includes a demodulation unit that demodulates a reception signal, a radio control unit that performs radio control using a demodulation result, and transmission control information in a communication partner station based on the demodulation result The radio control unit performs radio control using a demodulation result before the IPDL timing in the IPDL timing, and the transmission control information generation unit includes the IPDL timing. Is configured to generate transmission control information based on a demodulation result before the IPDL timing.
[0024]
According to this configuration, since the radio control and transmission control information is generated using the demodulation result before the IPDL timing without using the demodulation result at the IPDL timing, the demodulation is performed even in the IPDL section where the demodulation is not performed correctly. The operation using the result can be performed normally.
[0025]
The wireless receiver of the present invention includes a detecting unit that detects an IPDL timing at which a communication counterpart station instantaneously interrupts all transmissions, and a transmission timing control unit that controls so that a transmission timing of the communication counterpart station does not occur at the IPDL timing. The structure which has these is taken.
[0026]
According to this configuration, when transmission from a communication partner station is interrupted, control is performed so that transmission timing does not occur in the communication partner station, so the number of lines in which transmission is instantaneously interrupted during IPDL is minimized. It is possible to limit the number of requests to the limit, and it is possible to reduce unnecessary retransmission requests.
[0027]
In the radio reception apparatus of the present invention, the transmission timing control means permits a preamble transmission unit that transmits a preamble requesting reception confirmation from a communication partner station prior to data transmission, and permits transmission of data to the preamble. And a data transmission unit that transmits data when a reception confirmation to the effect is received from the communication partner station. The preamble transmission unit stops transmitting the preamble at the IPDL timing.
[0028]
According to this configuration, since the transmission of the preamble requesting reception confirmation from the communication partner station is stopped at the IPDL timing, the communication partner station does not generate a reception confirmation transmission timing during IPDL, and wireless reception Since the reception confirmation is not received, the apparatus does not needlessly retransmit the preamble, and can prevent a decrease in throughput.
[0029]
In the radio reception apparatus of the present invention, the detection means compares the timing generated by the timing generation unit that always generates a fixed timing and the time measured by the timing generation unit with a predetermined IPDL timing. Thus, an IPDL section determination unit that detects that the IPDL timing is approaching is adopted.
[0030]
According to this configuration, since the approach of the IPDL timing is detected by comparing the measured time with a predetermined IPDL timing, the IPDL timing can be reliably detected and the IPDL timing is changed. Even in this case, the IPDL timing can be detected with a minimum circuit change.
[0031]
The radio reception method of the present invention controls a reception operation by detecting an IPDL timing at which a communication partner station instantaneously interrupts all transmissions, and eliminating a signal corresponding to a path from the communication partner station at the IPDL timing. Steps.
[0032]
According to this method, when transmission from the communication partner station is interrupted, the reception operation is controlled without using a signal corresponding to the path from the communication partner station, so that only interference components and noise components are present. The included path signals can be ignored, the reception characteristics can be prevented from deteriorating, and various control malfunctions can be prevented.
[0033]
The wireless reception method of the present invention includes a step of detecting an IPDL timing at which a communication counterpart station instantaneously interrupts all transmissions, and a step of controlling so that a transmission timing of the communication counterpart station does not occur at the IPDL timing. I made it.
[0034]
According to this method, when transmission from a communication partner station is interrupted, control is performed so that transmission timing does not occur in the communication partner station. It is possible to limit the number of requests to the limit, and it is possible to reduce unnecessary retransmission requests.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
The gist of the present invention is that the timing of IPDL is detected, and a signal corresponding to the detected timing is not received or is not considered in various controls even if it is received.
[0036]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0037]
(Embodiment 1)
FIG. 1 is a block diagram showing a main configuration of the mobile station apparatus according to Embodiment 1 of the present invention. 1 includes an RF (Radio Frequency) receiver 102, an A / D converter 104, a demodulator 106, a timing generator 108, an IPDL section determiner 110, an error controller 112, and a data reception determiner 114. , An RF control unit 116, a transmission control information generation unit 118, a modulation unit 120, a D / A conversion unit 122, and an RF transmission unit 124.
[0038]
The RF receiving unit 102 receives a signal via an antenna, performs down-conversion of the received signal, and outputs a baseband signal. Further, the RF receiving unit 102 performs predetermined wireless reception processing according to the control of the RF control unit 116. Specifically, the RF receiver 102 performs processing such as AFC (Auto Gain Control) and AGC (Auto Gain Control).
[0039]
The A / D conversion unit 104 performs A / D conversion on the baseband signal and outputs a digital signal.
[0040]
The demodulator 106 demodulates the digital signal by performing despreading processing and synchronous detection. Here, demodulating section 106 performs different demodulation processing in the IPDL section and other than the IPDL section in accordance with the IPDL timing instruction from IPDL section determining section 110. The demodulation processing of the demodulator 106 will be described in detail later.
[0041]
The timing generation unit 108 includes, for example, a crystal oscillator and a clock counter, and measures time or time.
[0042]
The IPDL section determination unit 110 holds the IPDL timing notified from the base station apparatus in advance, compares the time or time measured by the timing generation unit 108 with the IPDL timing, and when the IPDL timing approaches, The IPDL timing is instructed to the demodulation unit 106.
[0043]
Error control section 112 performs error correction decoding on the demodulated signal and outputs received data.
[0044]
The data reception determination unit 114 determines whether data is received using the demodulated signal, and outputs a determination result. The data reception determination unit 114 determines whether or not an Ack / Nack transmitted using, for example, AICH is received.
[0045]
The RF control unit 116 controls the RF reception unit 102 and the RF transmission unit 124 using a synchronous detection signal obtained by performing synchronous detection by the demodulation unit 106. Specifically, for example, the RF reception unit 102 is controlled to cancel the frequency offset detected using the synchronous detection signal and AFC is performed, or the RF transmission unit 124 is controlled to transmit the signal included in the synchronous detection signal. Perform transmission power control according to the power control command.
[0046]
The transmission control information generation unit 118 generates transmission control information for controlling transmission in the base station apparatus using the synchronous detection signal. Specifically, the transmission control information generation unit 118 generates a transmission power control command and transmission diversity control information for the base station apparatus.
[0047]
Modulation section 120 multiplexes and modulates transmission data and transmission control information, and outputs a modulated digital signal.
[0048]
The D / A converter 122 D / A converts the modulated digital signal and outputs an analog signal.
[0049]
The RF transmission unit 124 performs predetermined wireless transmission processing according to the control of the RF control unit 116. Specifically, the RF transmission unit 124 performs processing such as transmission power control, for example. In addition, the RF transmission unit 124 performs up-conversion of the signal after the wireless transmission processing and transmits the signal via the antenna.
[0050]
Next, the internal configuration of the demodulation unit 106 will be described with reference to FIG.
[0051]
The demodulating unit 106 includes despreading units 1062-1 to 1062-n (n is an integer equal to or greater than 1), synchronous detection units 1064-1 to 1064-n, and a RAKE combining unit 1066. Despreading sections 1062-1 to 1062-n and synchronous detection sections 1064-1 to 1064-n are provided corresponding to signals of n paths included in the received signal. In the following description, the mobile station apparatus is performing a handover, for example, and among the n paths, a path from a base station apparatus that performs IPDL (here, a base station apparatus of its own cell), and Both paths from base station apparatuses in cells other than the cell are included.
[0052]
The despreading units 1062-1 to 1062-n despread the input signal to the demodulation unit 106 for each signal of each path. In addition, despreading sections 1062-1 to 1062-n receive an IPDL timing instruction from IPDL section determination section 110, and for the paths from the base station apparatus of the own cell that performs IPDL among n paths, IPDL sections The despread output at is set to zero.
[0053]
As a result, conventionally, in the IPDL section, the signal is despread from the signal of the path in which only the interference signal from the base station apparatus of other cells and the thermal noise are superimposed (that is, the path from the base station apparatus of the own cell in the IPDL section) While a noise component is output as an output, in the present embodiment, 0 is output as a despread output, and a signal component that is unnecessary for synthesis or the like is not output.
[0054]
The synchronous detectors 1064-1 to 1064-n perform synchronous detection using the despread output for each path. Synchronous detection units 1064-1 to 1064-n output synchronous detection signals including channel estimation results obtained by synchronous detection to RF control unit 116 and transmission control information 118. Further, when 0 is output as the despread output from the corresponding despreading units 1062-1 to 1062-n, the synchronous detection units 1064-1 to 1064-n output 0 as the synchronous detection signal.
[0055]
Therefore, in the control and the generation of control information using the synchronous detection signal by the RF control unit 116 and the transmission control information generation unit 118, the path from the base station apparatus of the own cell in the IPDL section is not considered, and malfunctions occur. Can be prevented.
[0056]
The RAKE combining unit 1066 performs RAKE combining on the synchronous detection result and outputs a demodulated signal. Also in this case, the synchronous detection result corresponding to the path from the base station apparatus of the own cell in the IPDL section is 0, and the synchronization corresponding to the path from the base station apparatus of another cell is performed in the IPDL section of the base station apparatus of the own cell. This is equivalent to RAKE combining only the detection result.
[0057]
Next, the operation of the mobile station apparatus configured as described above will be described.
[0058]
First, in a normal state that is not an IPDL section, a signal is received by the RF receiving unit 102 via an antenna. This received signal includes a path signal from the base station apparatus of the own cell and other cells.
[0059]
The received signal is down-converted by the RF receiving unit 102 and subjected to wireless reception processing such as AFC and AGC. The baseband signal obtained by the radio reception process is A / D converted by the A / D converter 104, despreaded and synchronously detected by the demodulator 106, and error-corrected and decoded by the error controller 112. Received data is obtained. If the received signal includes, for example, Ack / Nack transmitted using AICH, the data reception determination unit 114 determines whether or not AICH data has been received.
[0060]
Furthermore, the synchronous detection signal obtained by the synchronous detection processing by the demodulation unit 106 is used, and RF control such as AFC is performed by the RF control unit 116 and the transmission control information generation unit 118, respectively, and transmission of a transmission power control command or the like is performed. Control information is generated.
[0061]
On the other hand, even in such a normal state, the timing generation unit 108 performs a timing operation, and the IPDL interval determination unit 110 compares the IPDL timing of the base station apparatus of the own cell with the time of the timing generation unit 108. ing.
[0062]
When IPDL section determination section 110 determines that the IPDL timing of the base station apparatus of the own cell has arrived, it notifies that to despreading sections 1062-1 to 1062-n in demodulation section 106. At this time, when a processing delay occurs until the received signal reaches the demodulation unit 106 after being received via the antenna, the IPDL section determination unit 110 instructs the IPDL timing taking the processing delay into consideration. Like that. That is, for example, when a time of 3 slots is required for the received signal to reach the demodulator 106 from the antenna, the timing delayed by the time of 3 slots from the actual IPDL timing is despreader 1062-1-. 1062-n is notified.
[0063]
When the IPDL timing is notified to the despreading units 1062-1 to 1062-n, among the despreading units 1062-1 to 1062-n, the despreading unit corresponding to the path from the base station apparatus of the own cell The despread output of the input signal received during the interval is set to zero. Then, the despread outputs are input to the corresponding synchronous detection units 1064-1 to 1064-n, respectively, and channel estimation and synchronous detection are performed. The synchronous detection signal, which is the result of channel estimation and synchronous detection, is output to the RF control unit 116 and the transmission control information generation unit 118 and is RAKE combined by the RAKE combining unit 1066.
[0064]
Here, the synchronous detection unit corresponding to the despreading unit that outputs 0 as the despread output outputs 0 as the synchronous detection signal. Therefore, when RAKE combining is performed by the RAKE combining unit 1066, a signal corresponding to the path of the base station apparatus of the own cell in the IPDL section (that is, an interference component and a thermal noise component of the base station apparatus of another cell) is included. Therefore, it is possible to prevent the accuracy of RAKE synthesis from being lowered.
[0065]
Further, the error correction capability of the error control unit 112 is high when the likelihood of each bit of the signal after RAKE combining, that is, the reliability is accurately expressed. In this embodiment, since the despread output corresponding to the base station apparatus of the own cell in the IPDL section is 0, the reliability of the bit corresponding to this despread output is the lowest 0, and the IPDL section It is most accurately expressed that the reliability of the own cell is low, and the error correction capability of the error control unit 112 is maximized.
[0066]
Further, when determining whether or not AICH data (Ack / Nack) has been received, for example, the data reception determination unit 114 performs power comparison between the synchronous detection signal and the CPICH signal. Since the power of the synchronous detection signal corresponding to the station apparatus is 0, it is determined as not transmitted. Accordingly, although the RACH preamble is retransmitted, the IPDL section is very short (for example, within one slot in the case of W-CDMA), and therefore, only one retransmission is required, which contributes to the throughput of the wireless communication system. The impact can be minimized.
[0067]
The synchronous detection signal input to the RF control unit 116 is used for AFC, transmission power control, and the like. However, since the synchronous detection signal corresponding to the base station apparatus of the own cell in the IPDL section is 0, the reliability is high. It is judged that it is low, and AFC and transmission power control are not performed in the IPDL section. As a result, no malfunction occurs. Similarly, transmission control information generation section 118 also generates control information for controlling the transmission of the base station apparatus when a synchronous detection signal in the IPDL section is input (that is, when 0 is input as the synchronous detection signal). Without transmitting, the transmission of the base station apparatus can be stably controlled by transmitting the control information generated last time as it is.
[0068]
The operations of the RF control unit 116 and the transmission control information generation unit 118 described above are the same when the received signal does not include a path signal from the base station device of another cell. In the case of the IPDL section, the RF control unit 116 and the transmission control information generation unit 118 do not operate.
[0069]
Then, the control information generated by the transmission control information generation unit 118 or the control information generated last time is modulated by the modulation unit 120 after being multiplexed with the transmission data, and is D / A converted by the D / A conversion unit 122. Is done.
[0070]
The obtained analog signal is subjected to predetermined radio transmission processing such as transmission power control by the RF transmission unit 124, up-converted, and transmitted via the antenna.
[0071]
Thus, according to the present embodiment, the IPDL section of the base station apparatus of the own cell is detected, and the despread output is set to 0 for the signal corresponding to the path from the base station apparatus of the own cell in this IPDL section. Therefore, the interference detection component and the thermal noise component from the base station apparatus of other cells do not affect the synchronous detection result and the RAKE combining result, so that the reception characteristics can be prevented from deteriorating and various control malfunctions can be prevented. it can.
[0072]
(Embodiment 2)
A feature of Embodiment 2 of the present invention is that, when a signal in the IPDL section is received, malfunctions of various controls are prevented by performing the same control as before without using the signal.
[0073]
FIG. 3 is a block diagram showing a main configuration of the mobile station apparatus according to Embodiment 2. In FIG. In the figure, the same parts as those in FIG. The mobile station apparatus shown in FIG. 3 includes an RF reception unit 102, an A / D conversion unit 104, a demodulation unit 106, a timing generation unit 108, an IPDL section determination unit 110, a reception timing control unit 202, an error control unit 112, and a data reception determination. Unit 114, RF control unit 204, transmission control information generation unit 206, modulation unit 120, D / A conversion unit 122, and RF transmission unit 124.
[0074]
The reception timing control unit 202 includes, for example, a matched filter, detects a reception timing from a desired base station apparatus, and notifies the demodulation unit 106 of the detected reception timing. When the reception timing control unit 202 notifies the demodulation unit 106 of the reception timing, the demodulation unit 106 can perform stable demodulation processing. In addition, the reception timing control unit 202 does not detect the reception timing from the base station apparatus of the own cell in the IPDL section of the base station apparatus of the own cell, and notifies the demodulation unit 106 of the reception timing detected last time as it is. .
[0075]
The RF control unit 204 controls the RF reception unit 102 and the RF transmission unit 124 using a synchronous detection signal obtained by performing synchronous detection by the demodulation unit 106. In addition, the RF control unit 204 does not perform RF control using the synchronous detection signal in the IPDL section of the base station apparatus of the own cell, and continuously performs RF control based on the synchronous detection signal obtained last time.
[0076]
The transmission control information generation unit 206 generates transmission control information for controlling transmission in the base station apparatus using the synchronous detection signal. In addition, the transmission control information generation unit 206 does not generate transmission control information using the synchronous detection signal in the IPDL section of the base station apparatus of the own cell, and transmits transmission control information based on the synchronous detection signal obtained last time. The data is output to the modulation unit 120 as it is.
[0077]
Next, the operation of the mobile station apparatus configured as described above will be described.
[0078]
First, the operation in a normal state that is not in the IPDL section is the same as that in the first embodiment, and thus description thereof is omitted.
[0079]
When it is determined by the IPDL section determination unit 110 that the IPDL timing of the base station apparatus of the own cell has arrived, this is notified to the reception timing control unit 202, the RF control unit 204, and the transmission control information generation unit 206. . At this time, as in the first embodiment, when a processing delay occurs, an IPDL timing taking the processing delay into consideration is notified.
[0080]
When the IPDL timing is notified, at this IPDL timing, the reception timing control unit 202, the RF control unit 204, and the transmission control information generation unit 206 perform operations of detection of reception timing, RF control, and transmission control information, respectively. Stop. The reception timing control unit 202, the RF control unit 204, and the transmission control information generation unit 206 perform various controls using the control values before the IPDL section as they are.
[0081]
As a result, the control based on the signal from the base station apparatus of the own cell is not performed even though the signal is not transmitted from the base station apparatus of the own cell, and malfunction can be prevented.
[0082]
When the IPDL period ends, the reception timing control unit 202, the RF control unit 204, and the transmission control information generation unit 206 again start normal operation.
[0083]
Thus, according to this embodiment, the IPDL section of the base station apparatus of the own cell is detected, the control based on the signal in this IPDL section is stopped, and the previous signal before the IPDL section is used as the basis. Since the control is performed, malfunctions of various controls in the IPDL section can be prevented.
[0084]
Note that the reception timing control unit 202, the RF control unit 204, and the transmission control information generation unit 206 in this embodiment operate independently of each other, and control is performed without using the signal in the IPDL section in each processing unit. By doing so, it is possible to individually prevent malfunctions corresponding to the respective processing units.
[0085]
(Embodiment 3)
The feature of Embodiment 3 of the present invention is that the transmission of RACH preamble is controlled so that the transmission timing of Ack / Nack transmitted using AICH at the time of random access does not overlap the IPDL section.
[0086]
FIG. 4 is a block diagram showing a main configuration of the mobile station apparatus according to Embodiment 3. In FIG. In the figure, the same parts as those in FIG. 4 includes an RF reception unit 102, an A / D conversion unit 104, a demodulation unit 106, a timing generation unit 108, an IPDL section determination unit 110, an error control unit 112, an AICH reception determination unit 114a, and a RACH preamble transmission. Unit 302, RACH transmission unit 304, switch 306, modulation unit 120, D / A conversion unit 122, and RF transmission unit 124.
[0087]
As with the data reception determination unit 114 of the first embodiment, the AICH reception determination unit 114a determines whether or not AICH data (Ack / Nack) has been received using the demodulated signal. The AICH reception determination unit 114 a outputs the reception determination result of AICH data to the switch 306.
[0088]
The RACH preamble transmission unit 302 transmits the RACH preamble while increasing the transmission power by a predetermined amount until receiving Ack / Nack from the base station apparatus. Further, RACH preamble transmission section 302 stops RACH preamble transmission during the IPDL period so that the Ack / Nack transmission timing does not overlap during the IPDL period of the base station apparatus of the own cell.
[0089]
The RACH transmission unit 304 transmits transmission data using the RACH when an Ack for the RACH preamble is returned.
[0090]
The switch 306 switches to the RACH transmission unit 304 side when the AICH reception determination unit 114a determines that Ack has been received. Further, the switch 306 is connected to the RACH preamble transmission unit 302 side when neither Ack / Nack is received or when it is determined that Nack is received.
[0091]
Next, the operation of the mobile station apparatus configured as described above will be described.
[0092]
First, in a normal state that is not an IPDL section, the RACH preamble transmission unit 302 transmits the RACH preamble as in the conventional case. That is, the RACH preamble is transmitted while the transmission power is increased by a predetermined amount until it is determined that Ack is received in the AICH reception determination by the AICH reception determination unit 114a.
[0093]
When the AICH reception determination unit 114a determines that an Ack for the RACH preamble has been received, the switch 306 is notified to that effect, and the switch 306 is switched to the RACH transmission unit 304 side.
[0094]
As a result, the RACH transmission unit 304 transmits the transmission data using the RACH. The transmission data is modulated by the modulation unit 120, D / A converted by the D / A conversion unit 122, subjected to a predetermined wireless transmission process by the RF transmission unit 124, and then transmitted via the antenna.
[0095]
On the other hand, even in such a normal state, the timing generation unit 108 performs a timing operation, and the IPDL interval determination unit 110 compares the IPDL timing of the base station apparatus of the own cell with the time of the timing generation unit 108. ing.
[0096]
Then, when it is determined by the IPDL section determination unit 110 that the IPDL timing of the base station apparatus of the own cell has arrived, the RACH preamble transmission unit 302 is notified to that effect.
[0097]
When the IPDL timing is notified to the RACH preamble transmission unit 302, the RACH preamble transmission unit 302 stops transmission of the RACH preamble. Thereby, when the base station apparatus of the own cell is in the IPDL section, the RACH preamble is not received in the base station apparatus of the own cell, and the transmission timing of Ack / Nack using AICH during the IPDL section. Do not overlap.
[0098]
When IPDL timing is notified from the IPDL section determination unit 110 to the RACH preamble transmission unit 302, the RACH preamble is transmitted from the mobile station apparatus and received by the base station apparatus, and which of Ack / Nack is transmitted. A timing that takes into account the time taken to be judged is indicated. That is, for example, when a time of 5 slots is required from the transmission of the RACH preamble to the transmission determination of Ack / Nack, the RACH preamble transmission unit 302 is notified of a timing earlier by 5 slots than the actual IPDL timing. The
[0099]
When the IPDL period ends, the IPDL period determination unit 110 notifies the RACH preamble transmission unit 302 to that effect, and the RACH preamble transmission is resumed.
[0100]
As described above, according to the present embodiment, the RACH preamble is detected so that the IPDL section of the base station apparatus of the own cell is detected and Ack / Nack transmission is not required from the base station apparatus in this IPDL section. Since the RACH preamble is transmitted with the transmission power required to reach the base station apparatus, neither Ack / Nack is received, and malfunction can be prevented. It is possible to prevent the RACH preamble from being transmitted unnecessarily during the IPDL interval.
[0101]
【The invention's effect】
As described above, according to the present invention, in a wireless communication system employing IPDL, even when all transmissions by a communication partner station are momentarily interrupted, deterioration of reception characteristics is prevented and malfunction of various controls is prevented. can do.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a main configuration of a mobile station apparatus according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing an internal configuration of a demodulation unit according to the first embodiment.
FIG. 3 is a block diagram showing a main configuration of a mobile station apparatus according to a second embodiment of the present invention.
FIG. 4 is a block diagram showing a main configuration of a mobile station apparatus according to a third embodiment of the present invention.
FIG. 5 is a sequence diagram showing an example of IPDL operation.
FIG. 6 is a sequence diagram illustrating an example of operation during random access.
[Explanation of symbols]
106 Demodulator
108 Timing generator
110 IPDL section determination unit
112 Error control unit
114 Data reception determination unit
114a AICH reception determination unit
116, 204 RF controller
118, 206 Transmission control information generator
202 Reception timing control unit
302 RACH preamble transmitter
304 RACH transmitter
306 switch

Claims (8)

Detecting means for detecting an IPDL timing at which a communication partner station instantaneously interrupts all transmissions;
A reception operation control means for controlling a reception operation by eliminating a signal corresponding to a path from a communication partner station at the IPDL timing;
A wireless receiver characterized by comprising: The reception operation control means includes
A despreading unit that outputs 0 as a despread output of a signal corresponding to the path from the communication partner station at the IPDL timing;
A synchronous detection unit for performing synchronous detection from a despread output including zero,
A RAKE combining unit for RAKE combining the synchronous detection results;
The radio reception apparatus according to claim 1, further comprising: The reception operation control means includes
A demodulator that demodulates the received signal;
A radio control unit that performs radio control using the demodulation result; and
A transmission control information generating unit that generates transmission control information in the communication partner station based on the demodulation result;
The wireless control unit
In the IPDL timing, radio control is performed using the demodulation result before the IPDL timing,
The transmission control information generation unit
The radio reception apparatus according to claim 1, wherein, in the IPDL timing, transmission control information is generated based on a demodulation result before the IPDL timing. Detecting means for detecting an IPDL timing at which a communication partner station instantaneously interrupts all transmissions;
A transmission timing control means for controlling so that the transmission timing of the communication partner station does not occur in the IPDL timing;
A wireless receiver characterized by comprising: The transmission timing control means includes
A preamble transmission unit that transmits a preamble requesting reception confirmation from a communication partner station prior to data transmission;
A data transmission unit that transmits data when a reception confirmation indicating that transmission of data is permitted to the preamble is received from a communication partner station, and
The preamble transmitter is
The radio reception apparatus according to claim 4, wherein preamble transmission is stopped at the IPDL timing. The detection means includes
A timing generator that always generates a constant timing and counts time,
An IPDL section determination unit for detecting that the IPDL timing is approached by comparing the IPDL timing determined in advance with the time measured by the timing generation unit;
The wireless receiver according to claim 1, further comprising: A step of detecting an IPDL timing at which a communication partner station interrupts all transmissions;
Controlling a reception operation by eliminating a signal corresponding to a path from a communication partner station at the IPDL timing;
A wireless reception method comprising: A step of detecting an IPDL timing at which a communication partner station interrupts all transmissions;
Controlling so that the transmission timing of the communication partner station does not occur in the IPDL timing;
A wireless reception method comprising:

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