JP2003143054A - Radio communication device and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication device, in a system where a base station communicates with a plurality of radio communication devices, which can eliminate interference components from received signals. SOLUTION: A signaling parameter memory 101 stores a signaling parameter for identifying a signal of a channel to be removed. Signaling parameter determining parts 102-1 to 102-n determine a signaling parameter to be used an associated base station in charge and output it to associated one of signaling parameter distributing parts 103-1 to 103-n. The signaling parameter distributing parts 103-1 to 103-n extract signaling parameters to be used by the respective base stations from the signaling parameter memory 101, and output the parameters to the associated base stations 200-1 to 200-n.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless communication device and a wireless communication method, and more particularly to TS-CDMA (Time Divisi).
on-code division multiple access: a wireless communication apparatus and a wireless communication method suitable for use in time division code division multiple access communication.

[0002]

2. Description of the Related Art Conventionally, as a method of removing various interferences such as interference due to multipath fading, intersymbol interference, and multiple access interference and extracting a demodulated signal, a joint detection (hereinafter referred to as "JD") is performed. There is an interference signal removal method using. This JD
For more information on “Zero Forcing and Minimum Mean-Squ
are-Error Equalization for Multiuser Detection
in Code -DivisionMultiple-Access Channels ”
(Klein A., Kaleh G. K., Baier P. W., IEEE
Trans. Vehicular Technology, Vol. 45, pp
． 276-287, 1996. ).

For example, TD-CDMA (Time Divisio)
In the n-Code Division Multiple Access (time division code division multiple access) system, one frame has a plurality of frames (for example, 16 frames).
Number of timeslots, and each user has a DPCH (DeDe) for one or more timeslots in each frame.
Signals are transmitted using dedicated physical channels. One or more of the time slots in one frame are downlink P-
CCPCH (Primary-Common Control Physical Channe
l: first common control physical channel). P
-CCPCH is a channel used for transmitting downlink notification information. Hereinafter, the description will be limited to downlink reception.

A known reference signal called a midamble code is inserted between the data parts of the DPCH and P-CCPCH signals. The midamble code is used for channel estimation for each user signal.

A radio communication apparatus using the TD-CDMA and the midamble code will be described. FIG. 7 is a block diagram showing an example of the configuration of a conventional wireless communication device.

Midamble replica code generator 11
Creates a replica of the midamble code of its own cell and outputs it to the midamble correlation unit 12. Here, the own cell indicates a range in which the own cell can communicate with the base station device to which the own cell belongs. The midamble code of the own cell is an area in which the base station device to which the own station belongs covers communication, and indicates a midamble code used when the base station device and the own station communicate with each other.

The midamble correlation section 12 multiplies the received signal by the midamble code of its own cell to create a delay profile showing the correlation between the received signal and the midamble code, and outputs it to the path determination section 13. The midamble code used in each channel is a basic code circulated in delay window width units. Therefore, the midamble correlation unit 12 creates a plurality of delay profiles by shifting the timing of multiplying the received signal and the midamble code for each delay window width unit, and outputs the plurality of delay profiles to the path determination unit 13. .

The path determination unit 13 outputs to the midamble shift determination unit 14 a channel estimation value obtained by selecting only valid paths from the delay profile output from the midamble correlation unit 12. The midamble shift determination unit 14 determines whether or not all input delay profiles are actually multiplexed midamble codes.

The spreading code determining unit 15 determines all channelization codes actually used in communication by the base station device of the own cell, and scrambles the channelization code determined to be used and the own cell. A spreading code is generated from the code and output to the JD demodulation unit 17. The delay unit 16 delays the received signal until the processing timing of the JD demodulation unit 17.

The JD demodulation unit 17 performs joint detection calculation on the received signal using the delay profile and the replica of the spreading code. Specifically, the JD demodulation unit 17
Is a convolution product of a delay profile and a spread code replica to create a system matrix, and the received signal is multiplied by the system matrix to obtain a demodulated received signal.

[0011]

In a system in which a base station apparatus communicates with a plurality of wireless communication apparatuses, a delay profile (channel estimation) used for joint detection calculation when interference components are removed using the wireless communication apparatus. Value) and the information necessary to identify the code are not available, which may be difficult to implement. Further, when estimating and detecting the information necessary for identifying the code, there is also a problem that the detection processing increases the amount of calculation processing of the entire apparatus.

The present invention has been made in view of the above points, and a wireless communication device capable of removing an interference component from a received signal in a wireless communication device of a system in which a base station device communicates with a plurality of wireless communication devices. And a wireless communication method.

[0013]

The control station device of the present invention comprises:
A signaling parameter storage unit that stores a signaling parameter that is information necessary for identifying an interference component when removing the interference component from a received signal in a wireless communication device, and a signaling parameter that extracts and outputs the signaling parameter from the signaling parameter storage unit. And a distribution means.

In the control station apparatus of the present invention, the signaling parameter is any one of the midamble allocation mode, the maximum number of midamble shifts, the midamble shift, the channelization code, and the information on the correspondence relationship between the channelization code and the midamble shift. The signaling parameter storage means stores the signaling parameter used in the base station device with which the control station device communicates, and the signaling parameter distribution means has a configuration to output the signaling parameter of the base station device.

In the control station apparatus of the present invention, the interference component is
The configuration is a signal of a channel used for communication between a base station device to which the own station belongs and a wireless communication device other than the own station.

According to these configurations, the control station device transmits the information necessary for specifying the interference component, so that the base station device communicates with the plurality of radio communication devices, and the received signal is received by the radio communication device. Interference component can be removed.

The base station apparatus of the present invention comprises a receiving means for receiving a signaling parameter, which is information necessary for specifying an interference component when removing the interference component from a received signal in a wireless communication apparatus, and the signaling parameter as a radio signal. Wireless transmission means for transmitting as.

According to this configuration, by transmitting the information necessary for specifying the interference component transmitted from the control station device to the wireless communication device, the base station device communicates with the plurality of wireless communication devices by the wireless communication system. The interference component can be removed from the received signal in the communication device.

The radio communication apparatus of the present invention comprises a signaling acquisition unit for extracting a signaling parameter, which is information necessary for specifying an interference component, from a received signal, and a correlation for creating a delay profile of a channel to be removed using the signaling parameter. And a joint detection calculation means for performing a joint detection calculation using the delay profile created by the correlation means to remove an interference component of the received radio signal.

In the wireless communication apparatus of the present invention, the path determination means creates a channel estimation value based on the signaling parameter, and the joint detection calculation means:
A configuration is adopted in which joint detection calculation is performed using the channel estimation value.

According to these configurations, the delay profile of the channel to be removed is created by using the information necessary for specifying the interference component, the joint detection operation is performed using this delay profile, and the interference component of the received radio signal is obtained. By removing the, the interference component can be removed from the received signal in the wireless communication device of the system in which the base station device communicates with the plurality of wireless communication devices.

In the radio communication apparatus of the present invention, the signaling parameter is any one of the midamble allocation mode, the maximum number of midamble shifts, the midamble shift, the channelization code, and the information on the correspondence relationship between the channelization code and the midamble shift. Take a configuration that includes.

In the wireless communication apparatus of the present invention, the removal target channel is a channel used for communication between a base station apparatus to which the own station belongs and a wireless communication apparatus other than the own station.

According to these configurations, signals of other channels can be removed as interference components.

In the radio communication method of the present invention, the control station device outputs a signaling parameter which is information necessary for identifying the interference component when removing the interference component from the received signal, and the radio communication device uses the signaling parameter. Is used to create a delay profile of the channel to be removed, and joint detection calculation is performed using the delay profile to remove the interference component of the received radio signal.

According to this method, in the control station device,
The information necessary for specifying the interference component is transmitted, and in the wireless communication device, a delay profile of the channel to be removed is created using this information, and a joint detection operation is performed using this delay profile to interfere with the received wireless signal. By removing the component, the interference component can be removed from the received signal in the wireless communication device of the system in which the base station device communicates with the plurality of wireless communication devices.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION When a joint detection operation is used to remove an interference component from a received radio signal, there is information necessary for distinguishing signals multiplexed in the radio signal. These required information differ depending on the mode of the midamble used, that is, the midamble allocation mode.

The midamble allocation mode includes a code individual mode, a user common mode, and a user individual mode. FIG. 1 is a diagram showing an example of a midamble code. In FIG. 1, the horizontal axis represents time and the vertical axis represents code multiplexing.

FIG. 1A shows a code individual midamble which is a midamble code in the code individual mode. The code dedicated mode is a mode in which channels multiplexed in the same slot use different midamble codes. As shown in FIG. 1A, code 1,
Different midamble codes m ^(x) , m ^(y), ..., ^{M (z)} are assigned to the channels multiplexed with the spreading codes of code 2 and code n, respectively.

FIG. 1B shows a user common midamble which is a midamble code in the user common mode. The user common mode is a mode in which one code is commonly used as a midamble code in channels multiplexed in the same slot. As shown in FIG. 1 (b), code
A common midamble code m ^(y) is allocated to channels multiplexed with spreading codes of 1, code 2, ..., Code n.

FIG. 1 (c) shows a user-specific midamble which is a midamble code in the user-specific mode. In the user-dedicated mode, among the channels multiplexed in the same slot, one midamble code is commonly used for each user. Figure 1 (c)
The channels multiplexed with the spreading codes of code 1 and code 2 as shown in FIG.
, Which is a channel used by a common midamble code m ^(x) . Further, the channel multiplexed with the spreading code of code n is a channel used by a user user m different from user 1, and m
^A midamble code m ^(y) different from ^(x) is assigned.

The parameters required in each mode shown in FIG. 1 will be described below. FIG. 2 is a diagram showing an example of a table of parameters required for interference removal using joint detection calculation. In FIG. 2, the parameters used when the radio communication device cancels interference with the radio signal transmitted from the base station are shown for each midamble allocation mode. In FIG. 2, “∘” indicates a required parameter, and “x” indicates an acquisition unnecessary parameter.

As shown in FIG. 2, when a signal addressed to the user (own station) is distinguished from the radio signal transmitted from the base station apparatus and extracted, the maximum number of midamble shifts of the signal addressed to the own station and the midamble shift. , And a channelization code are required. These parameters are required for any of the above modes.

When the base station apparatus to which the own station belongs (own cell) distinguishes and takes out the signals of other users with whom communication is performed and removes them as interference components, the midamble shift and channelization code of other users are required. Become.
These parameters are also required for any of the above modes.

When the base station apparatus to which the own station belongs distinguishes and extracts the signal transmitted in common in the cell and removes it as an interference component, information on the correspondence relationship between the channelization code and the midamble shift is required. In the code individual mode and the user common mode, this information is uniquely determined from the channelization code, so it is not necessary to acquire it again.

When a base station apparatus to which the own station does not belong (another cell) distinguishes a signal of a user who is communicating and removes it as an interference component, the maximum of the midamble code transmitted by the base station apparatus in another cell The number of midamble shifts, the midamble shifts of other cell users, and the channelization code are required. These parameters are also required for any of the above modes. Similar to the own cell, the information on the correspondence relationship between the channelization code and the midamble shift does not need to be newly acquired because it is uniquely determined from the channelization code in the code individual mode and the user common mode.

As described above, when the interference component is removed from the received radio signal by using the joint detection calculation, the above parameters are required.

On the other hand, the information notified from the control station device to the wireless communication device is a part of the above parameters. Figure 3
FIG. 4 is a diagram showing an example of a table of parameters notified from a control station device to a wireless communication device. As shown in FIG. 3, the parameters notified from the control station device to the wireless communication device differ depending on the type of user.

As parameters relating to the signal addressed to the wireless communication device (own station), the midamble allocation mode, the maximum number of midamble shifts, the midamble shift, and the channelization code are notified. Further, the information on the correspondence between the channelization code and the midamble shift is not notified.

The midamble allocation mode and the maximum number of midamble shifts are known as parameters related to signals addressed to other users of the own cell other than the own station because they are common parameters in the same cell. However, the information on the midamble shift, the channelization code, and the correspondence relationship between the channelization code and the midamble shift is not notified.

Then, as parameters relating to signals addressed to users of other cells, information on the midamble allocation mode, the maximum number of midamble shifts, the midamble shift, the channelization code, and the correspondence relationship between the channelization code and the midamble shift is: Neither is notified.

The present inventor applies information for distinguishing and extracting each multiplexed signal, for example, midamble allocation, when applying interference cancellation using joint detection calculation in a wireless communication apparatus that communicates with a base station. The present invention has been accomplished by finding that information on the mode, the maximum number of midamble shifts, the midamble shift, the channelization code, and the correspondence relationship between the channelization code and the midamble shift is required.

That is, the gist of the present invention is that the control station device or the base station device transmits information necessary for specifying the interference component, and the wireless communication device uses this information to create a delay profile of the channel to be removed. Then, a joint detection operation is performed using this delay profile to remove the interference component of the received radio signal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 4 is a block diagram showing the configuration of the control station apparatus according to the embodiment of the present invention. The control station device 100 includes a signaling parameter storage unit 10
1 and signaling parameter determination units 102-1 to 10
2-n and signaling parameter distribution unit 103-1 to
103-n and the like. Then, the control station device 100 communicates with the base station devices 200-1 to 200-n.

The signaling parameter storage unit 101 is
Signaling parameters that identify the signal of the channel to be removed, eg, midamble allocation mode,
Maximum number of midamble shifts, midamble shifts,
The information on the channelization code and the correspondence between the channelization code and the midamble shift is stored.

Signaling parameter determination unit 102-1
102-n determine the signaling parameters used by the respective base station devices and output them to the signaling parameter distribution units 103-1 to 103-n.

Signaling parameter distribution unit 103-1
˜103-n are signaling parameter storage units 101
From each of the base station devices 200-1 to 200-
output to n. Also, the signaling parameter distribution unit 1
03-1 to 103-n store the signaling parameters output from the signaling parameter determination units 102-1 to 102-n in the signaling parameter storage unit 101.

Next, the base station apparatus according to this embodiment will be explained. FIG. 5 is a block diagram showing the configuration of the base station apparatus according to this embodiment. The base station device 20 of FIG.
0 is the base station devices 200-1 to 200-n in FIG. The base station device 200 includes the signaling data generation unit 2
01, a transmission data generation unit 202, an encoding / multiplexing unit 203, a spread modulation unit 204, and a wireless transmission unit 205.

Signaling data generating section 201 receives the signaling parameter transmitted from control station apparatus 100, creates signaling data including this signaling parameter, and outputs it to coding / multiplexing section 203.

The transmission data generating section 202 generates data to be transmitted and outputs it to the encoding / multiplexing section 203. In this embodiment, the transmission data is created by the base station device 200, but this transmission data is generated by the control station device 1.
The transmission data may be transmitted from 00.

The coding / multiplexing section 203 codes and multiplexes the signaling data and the transmission data, and outputs it as a transmission signal to the spreading modulation section. Spreading modulation section 204 multiplies the transmission signal by a code, performs spreading processing, performs modulation processing, and outputs the result to radio transmission section 205. The wireless transmission unit 205
The transmission signal is converted into a radio frequency and transmitted to the radio communication device 300.

Next, the radio communication apparatus according to this embodiment will be explained. FIG. 6 is a block diagram showing the configuration of the wireless communication apparatus according to this embodiment. The wireless communication device 300 of FIG. 6 includes a signaling acquisition unit 301, a signaling storage unit 302, a signaling distribution unit 303, a wireless unit 304, a delay unit 305, a midamble replica code generation unit 306, and a midamble correlation unit. 307
And a path determination unit 308, a JD demodulation unit 309, and a decoding unit 310.

Signaling acquisition section 301 acquires the signaling parameter included in the DCCH of the received signal and outputs it to signaling storage section 302. Here, the signaling parameter is a parameter used by the base station with which the wireless communication device 300 is communicating and other base station devices for communication. Specifically, the signaling parameter indicates information on the midamble allocation mode, the maximum number of midamble shifts, the midamble shift, the channelization code, and the correspondence relationship between the channelization code and the midamble shift. The midamble allocation mode can be user-specific, user-specific, or code-specific.

The signaling storage unit 302 stores signaling parameters and outputs the signaling parameters in response to a request from the signaling distribution unit 303.

The signaling distribution unit 303 outputs the maximum number of midamble shifts and the information of the midamble shifts to the path determination unit 308, and the information about the correspondence between the midamble allocation mode, the channelization code and the channelization code and the midamble shift. Is output to the JD demodulation unit 309.

Radio section 304 receives a radio signal, amplifies the received radio signal, performs frequency conversion, and outputs the obtained baseband received signal to delay section 305 and midamble correlation section 307. The delay unit 305 delays the received signal until the processing timing of the JD demodulation unit 309.

Midamble replica code generator 30
6 creates a replica of the midamble basic code from the known midamble basic code of its own cell and outputs the replica to the midamble correlation unit 307. Here, the own cell indicates a range in which the own cell can communicate with the base station device to which the own cell belongs. The midamble basic code of the own cell is an area in which the base station device to which the own station belongs covers communication, and indicates a midamble basic code used when the base station device and the own station communicate with each other.

The midamble correlator 307 multiplies the midamble part of the received signal by the midamble replica code of its own cell to create a delay profile showing the correlation between the midamble part of the received signal and the midamble replica code, It outputs to the path determination unit 308. The midamble replica code used in each channel is a basic code circulated in delay window width units. Specifically, the midamble correlation unit 307 creates a plurality of delay profiles by shifting the timing of multiplying the received signal by the midamble code for each delay window width unit,
The plurality of delay profiles are output to the path determination unit 308.

The path determination unit 308, in accordance with the maximum number of midamble shifts and the information of the midamble shifts output from the signaling distribution unit 303, of the delay profile output from the midamble correlation unit 307, the range of the midamble shifts. To the JD demodulation unit 309, which outputs a channel estimation value obtained by selecting only valid paths from

The JD demodulation section 309 creates a spreading code from the information of the midamble allocation mode and the channelization code output from the signaling distribution section 303 and the information of the correspondence between the midamble shift and the channelization code, and the path determination section. Joint detection calculation is performed on the received signal using the channel estimation value output from 308 and the replica of the spreading code, and the obtained received signal is output to decoding section 310. Specifically, the JD demodulation unit 309 convolutionally multiplies the delay profile and the spread code replica to create a system matrix, and multiplies the received signal by the system matrix to obtain the demodulated received signal.

Decoding section 310 decodes the demodulated received signal to obtain received data. Then, decoding section 310 outputs the received signal to signaling acquisition section 301.

As described above, the control station apparatus of the present embodiment,
According to the base station device and the wireless communication device, the control station device or the base station device transmits information necessary for specifying the interference component, and uses this information to create a delay profile of the channel to be removed, and the delay By performing joint detection calculation using the profile and removing the interference component of the received wireless signal, the interference component is removed from the received signal in the wireless communication device of the system in which the base station device communicates with a plurality of wireless communication devices. be able to.

In the description of the present embodiment, an example in which the signal of another user in the own cell is removed as an interference component has been described, but the present invention is not limited to this, and the base station to which the wireless communication device does not belong It is also possible to remove the signal transmitted by the device as an interference component. In this case, the signaling parameters used by the base station apparatus to which the wireless communication apparatus does not belong to transmit radio signals are midamble allocation mode, maximum midamble shift number, midamble shift, channelization code, and channelization code. This can be realized by transmitting the information on the correspondence relationship between and the midamble shift from the control station device to the wireless communication device.

In the description of this embodiment, the DCCH
Although the signaling parameter is notified by using, the present invention is not limited to this, and the channel is not particularly limited as long as the channel can be notified from the control station device to the wireless communication device.

[0065]

As described above, according to the wireless communication device and the wireless communication method of the present invention, the control station device or the base station device transmits the information necessary for specifying the interference component and uses this information. A system in which a base station device communicates with a plurality of wireless communication devices by creating a delay profile of a channel to be removed by performing a joint detection calculation using this delay profile and removing an interference component of a received wireless signal. In the wireless communication device, the interference component can be removed from the received signal.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a midamble code.

FIG. 2 is a diagram showing an example of a table of parameters required for interference removal using joint detection calculation.

FIG. 3 is a diagram showing an example of a table of parameters notified from a control station device to a wireless communication device.

FIG. 4 is a block diagram showing a configuration of a control station device according to an embodiment of the present invention.

FIG. 5 is a block diagram showing the configuration of the base station apparatus according to the above embodiment.

FIG. 6 is a block diagram showing a configuration of a wireless communication device according to the above embodiment.

FIG. 7 is a block diagram showing an example of a configuration of a conventional wireless communication device.

[Explanation of symbols]

101 Signaling parameter storage unit 102 Signaling parameter determination unit 103 Signaling parameter distribution unit 201 Signaling data generator 205 wireless transmitter 301 Signaling acquisition unit 302 signaling storage unit 303 Signaling distribution unit 306 Midamble replica code generator 307 Midamble correlation section 308 Path determination unit 309 JD demodulator

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor ▲ Taka ▼ Hideyuki Hashi             3-1, Tsunashima-Higashi 4-chome, Kohoku-ku, Yokohama-shi, Kanagawa             Matsushita Communication Industry Co., Ltd. F-term (reference) 5K022 EE01 EE11 EE35                 5K046 AA09 BA00 EE42 EE50 EE56                       YY00                 5K067 AA03 BB02 CC10 DD42 EE02                       EE10 EE16 HH23

Claims (9)

[Claims] 1. A signaling parameter storage means for storing a signaling parameter, which is information necessary for identifying an interference component when removing the interference component from a received signal in a wireless communication device, and the signaling parameter is retrieved from the signaling parameter storage means. And a signaling parameter distribution unit that outputs the control station apparatus. 2. The signaling parameter includes any of a midamble allocation mode, a maximum number of midamble shifts, a midamble shift, a channelization code, and information on a correspondence relationship between the channelization code and the midamble shift, and the signaling parameter storage The means for storing the signaling parameter used in the base station device with which the control station device communicates, and the signaling parameter distribution means outputs the signaling parameter of the base station device. Control station equipment. 3. The signal according to claim 1, wherein the interference component is a signal of a channel used for communication between a base station device to which the own station belongs and a wireless communication device other than the own station. Control station equipment. 4. A receiving means for receiving a signaling parameter, which is information necessary for identifying an interference component when removing the interference component from a received signal in a wireless communication device, and a wireless transmitting means for transmitting the signaling parameter as a wireless signal. A base station apparatus comprising: 5. A signaling acquisition unit for extracting a signaling parameter, which is information necessary for specifying an interference component, from a received signal, a correlation unit for creating a delay profile of a channel to be removed using the signaling parameter, and the correlation unit. And a joint detection calculation means for removing an interference component of a received wireless signal by performing a joint detection calculation using the delay profile created in (3). 6. The path determination means creates a channel estimation value based on the signaling parameter, and the joint detection calculation means performs a joint detection calculation using the channel estimation value. 5. The wireless communication device according to item 5. 7. The signaling parameter includes any one of a midamble allocation mode, a maximum number of midamble shifts, a midamble shift, a channelization code, and information on a correspondence relationship between the channelization code and the midamble shift. The wireless communication device according to claim 5 or 6, wherein 8. The removal target channel is a channel used for communication between a base station device to which the own station belongs and a wireless communication device other than the own station, according to any one of claims 5 to 7. The wireless communication device according to. 9. The control station device outputs a signaling parameter, which is information necessary for identifying an interference component when removing the interference component from a received signal, and a wireless communication device uses the signaling parameter to remove a channel to be removed. The wireless communication method is characterized in that a delay profile is created, and a joint detection operation is performed using the delay profile to remove an interference component of a received wireless signal.