JP2003298468A - Path search apparatus and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To generate a proper delay profile to detect a path with high accuracy even when transmission is stopped in the unit of slots. <P>SOLUTION: A summation control section 8 in the path search apparatus 15 controls an in-phase summation section 5 to stop in-phase summation for a transmission stop period on the basis of scheduling information transmitted from a host layer such as a RNC (Radio Network Controller) or the like and notifying of the transmission stop period in advance. Thus, even when the transmission is temporarily stopped, the in-phase summation section 5 uses only a valid correlation value for the in-phase summation and a power summation section 6 generates a more ideal delay profile to enhance the accuracy of path detection in a path control section 9. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a path search device and method in a spread spectrum communication system for detecting a path timing, which is a timing at which spreading is performed on a transmitting side.

[0002]

2. Description of the Related Art In recent years, as a communication system used in a mobile communication system, a CDMA (Code Division Multiple Access: Code) which is a spread spectrum communication system resistant to interference and interference.
Division Multiple Acces
s) The communication method is drawing attention. In this CDMA communication system, the user signal desired to be transmitted is spread and transmitted by a spreading code on the transmitting side, and the original user signal is obtained by despreading using the spreading code of the complex conjugate with the spreading code on the receiving side. It is a communication system. However, this CD
In the MA communication system, despreading cannot be performed unless the transmission side detects the path timing that is the timing at which the spreading is performed. Therefore, the receiving side detects the path timing of the transmission data by detecting the position of the pilot signal included in the received signal.

As an example in which the pilot signal is used, an upstream DPDCH (Dedicated Physical Data Channel) / W (Wideband) -CDMA system is used.
The frame structure of the DPCCH (Dedicated Physical Control Channel) is shown in FIG.

As shown in FIG. 4, in the W-CDMA communication system, data to be transmitted is composed of a unit of a radio frame having T _f = 10 msec. This radio frame has 15 slots # 0 to # 14, respectively.
It consists of Then, each slot is spread over the data of 2560 chips. Here, when a certain slot is the DPCCH, this slot contains a pilot symbol and a TFCI (Transport Format Combination).
Indicator) symbol and FBI (Feedback Informati)
on) symbol and TPC (Transmission Power Control)
l) consists of symbols and. On the receiving side, the path timing can be detected by detecting the position where this pilot symbol is inserted.

In order to detect such path timing, the receiver used in the spread spectrum communication system is equipped with a path search device. Further, the receiver used in the spread spectrum communication system is provided with a finger unit and a RAKE combining unit.

The finger unit performs a process of despreading the received signal converted into a baseband signal. In a normal case, since a plurality of finger units are provided, the RAKE combining unit RAKE combines the despread signals output from the plurality of finger units using the path timing detected by the path search device.

Further, the path search device calculates a delay profile (delay profile) from the received signal, detects a peak effective as a path timing from the obtained delay profile, and outputs the peak to the finger section or the rake combining section. Notify as timing information or effective finger information.

A conventional receiver used in this type of spread spectrum communication system is disclosed in Japanese Patent No. 2853705.
JP-A No. 11-261528 and the like. In Japanese Patent No. 2853705, in order to improve reception characteristics, a target signal is extracted by applying forward protection and backward protection by a path capturing / holding unit based on a search path detected by a path search device and a tracking path tracked. It is shown that the correlation demodulation path selection unit selects the path to be demodulated excluding the path of the signal other than the target signal and then performs the Rake combining.

FIG. 5 shows the configuration of a conventional radio base station apparatus equipped with such a path search apparatus. Here, only the reception function part of the wireless base station device is shown. As shown in FIG. 5, this wireless base station device includes an antenna 1, a high frequency receiver 2, and an A / D (analog / digital) converter 3.
A finger section 14 and a path search section 95.

The high frequency receiver 2 demodulates the signal received by the antenna 1. The A / D converter 3 converts the analog signal demodulated by the high frequency receiver 2 into a digital signal.

The path search device 95 performs processing for detecting path timing from the digital data from the A / D conversion section 3, and includes a code generator 7, a correlation value calculation section 4, an in-phase addition section 5, Power addition unit 6 and path control unit 9
It has and.

The code generator 7 generates a spread code corresponding to the assigned communication channel. Correlation value calculation unit 4
Is an ideal received signal that is spread by multiplying a spreading code generated by the code generator 7 and a predetermined pilot signal, and a pilot signal portion added to the beginning position of each time slot of the input signal. The correlation value of is calculated. The in-phase addition unit 5 is an I (In-phase compone) which is a signal component of the orthogonally demodulated pilot signal that is orthogonal to each other.
nt: in-phase component) signal and Q (Quadrature component:
The in-phase addition “I + I” or “Q + Q” is performed a certain number of times for each of the quadrature component signals. The power addition unit 6
The delay profile is generated by performing power addition “I ² + Q ² ” a fixed number of times on the signal after the in-phase addition unit 5 has performed the in-phase addition. The path control unit 9 detects the path timing based on the delay profile generated by the power addition unit 6 and notifies the despreading unit 11 of the finger unit 14 of the path timing.

The finger unit 14 performs a process of despreading the digital data from the A / D conversion unit 3 using the path timing notified by the path search device 95, and the code generator 10 and The despreading unit 11, the detection unit 12, and the Rake combining unit 13 that combines the detected signals are provided.

The code generator 10 generates a spreading code corresponding to the assigned communication channel. Despreader 11
Despreads the data from the A / D converter 3 using a spreading code generated by the code generator 10 by extracting a specific path corresponding to the delay time notified from the path search device 95. The detector 12 performs channel estimation to remove the influence of fading. The rake combiner 13 includes the detector 1
Demodulated data is generated by combining the signals detected by 2.

Next, the operation of the radio base station apparatus equipped with this conventional path search apparatus 95 will be described with reference to the drawings.

From the mobile terminal (not shown) on the transmission side, a framed transmission signal having a plurality of time slots is transmitted. A pilot signal, which is a fixed pattern known in advance on both transmitting and receiving sides, is added to the head position of each time slot in advance, and quadrature modulation is performed with the transmission data. After quadrature modulation, spread spectrum is performed using a spread code unique to each communication channel. In antenna 1, this C
A transmission signal spread by using a spreading code unique to each of the DMA systems is received. An analog signal received from the antenna 1 by the high frequency receiving unit 2 is converted into digital data by the A / D conversion unit 3. This digital data is input to the path search device 95 and the finger unit 14.

In the path search device 95, the correlation value calculation unit 4
And a pilot signal portion added to the head position of each time slot of the digital data from the A / D converter 3,
The correlation value between the spread code generated by the code generator 7 and the ideal received signal spread by multiplying the predetermined pilot signal is calculated. The in-phase addition unit 5 performs in-phase addition using the correlation value calculated by the correlation value calculation unit 4. Then, in the power addition unit 9, power addition is performed using the value after the in-phase addition is performed, and the delay profile is generated. Then, the path control unit 9 performs path detection based on this delay profile.

The finger unit 14 extracts the specific path corresponding to the delay time notified from the path search device 95 from the digital data from the A / D conversion unit 3, and the code generator 1
The despreading unit 11 despreads using the spreading code generated by 0. After that, the detection unit 12 estimates the channel to remove the influence of fading, and the RAKE combining unit 13 RAKE combines the detected signals to generate demodulated data.

In the conventional path search device 95 as described above, the path search is performed using a search window in which a wide area search is time-divided. Then, the correlation values calculated by the correlation value calculation unit 4 are added by the in-phase addition unit 5 to calculate a plurality of correlation values for one timing to remove the influence of fading or the like.

However, on the transmitter side, the transmission is not always continuously performed, and the transmission may be temporarily stopped. For example, in the W-CDMA system, signal power of another carrier frequency (CPICH (Common
It is necessary to measure the received power (Pilot Channel) (carrier sensing), and the data compression mode (Compressed M
ode) is specified. In this data compression mode, there is a slot section where information data is not transmitted,
At the receiver, the idle frequency (transmission gap) is used to change the transmission frequency of the frequency synthesizer to measure the received power of CPICH channels in different carrier frequency bands, the initial synchronization of control channels of other systems and other carriers, and the actual handover process. Is done.

However, in the conventional path search device 95 as shown in FIG. 5, even when the transmission stop in the slot unit occurs, the transmission stop section is used as it is for the generation of the delay profile. Detection will increase. That is, in the conventional path search device 95, in-phase addition is always performed in the in-phase addition unit 5 even if transmission is stopped, so that the search window to be added is displaced. Therefore, the correlation value at a certain timing is added as the correlation value at another timing, and an inaccurate delay profile is generated. If path detection is performed using this inaccurate delay profile, an erroneous path may be detected in some cases.

[0022]

In the above-described conventional path search device, when transmission stop in slot units occurs, a delay profile is generated without considering the transmission stop, and thus false detection of paths increases. There was a problem that it did.

The object of the present invention is to enable accurate path detection without increasing false detection of paths by generating an appropriate delay profile even when transmission is stopped in units of slots. The purpose is to provide a path search device.

[0024]

In order to achieve the above object, a path search device of the present invention is a path search device for detecting a path timing which is a timing at which spreading is performed on a transmitting side. Code generation means for generating a spreading code corresponding to the assigned communication channel, an ideal received signal spread by multiplying the spreading code generated by the code generation means with a predetermined pilot signal, and input A correlation value calculation unit that calculates a correlation value with a pilot signal portion added to the head position of each time slot of the signal, an I signal (in-phase component) that is a signal component of the quadrature-demodulated pilot signal that is orthogonal to each other, and In-phase addition means for performing a fixed number of in-phase additions for each Q signal (quadrature component) and in-phase addition by the in-phase addition means were performed. Power addition means for generating a delay profile by performing power addition a fixed number of times on the signal of, and path control means for detecting path timing based on the delay profile generated by the power addition means, And an addition control unit that controls to stop the in-phase addition in the in-phase addition unit in the transmission stop period based on the scheduling information that notifies the transmission stop period transmitted from the upper layer in advance.

According to the present invention, when the transmission is temporarily stopped, the addition control means stops the in-phase addition of the in-phase addition means in the transmission stop section based on the scheduling information. Therefore, since the in-phase addition means uses only the effective correlation value for the in-phase addition, a more ideal delay profile is generated in the power addition section, and the path detection accuracy in the path control means is improved.

Further, according to another path search device of the present invention, instead of stopping the in-phase addition in the in-phase addition means based on the scheduling information which is transmitted in advance from the upper layer and which notifies the transmission stop period, the power addition is performed. You may make it control to stop the electric power addition in a means.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION Next, embodiments of the present invention will be described in detail with reference to the drawings.

(First Embodiment) FIG. 1 is a block diagram showing the configuration of a base station apparatus including a path search apparatus 15 according to the first embodiment of the present invention. In FIG. 1, the same components as those in FIG. 5 are designated by the same reference numerals, and the description thereof will be omitted.

The path search device 15 of this embodiment is shown in FIG.
In addition to the conventional path search device 95 shown in FIG.

The addition controller 8 controls the RNC (Radio Network).
Controller) and the like, based on the scheduling information that notifies the transmission stop period transmitted from the upper layer in advance, control is performed to stop the in-phase addition in the in-phase addition unit 5 in the transmission stop period. That is, the addition control unit 8 controls the in-phase addition unit 5 to perform a fixed number of in-phase additions only in a section other than the transmission suspension section using the scheduling information.

In the path search device 15 of the present embodiment, by using the scheduling information from the upper layer to stop the in-phase addition in the transmission stop period, the processing shown in FIG.
Even if the transmission is temporarily stopped as shown in (1), the in-phase addition section 5 uses only the effective correlation value for in-phase addition, and the power addition section 9 produces a more ideal delay profile. As a result, the accuracy of path detection in the path control unit 9 is improved.

That is, the path search device 15 of this embodiment.
Then, the addition control unit 8 controls whether the in-phase addition unit 5 adopts the correlation value calculated by the correlation value calculation unit 4 for delay profile generation, thereby realizing in-phase addition stop only in the transmission stop section. To do. This makes it possible to generate a more ideal delay profile and improve the accuracy of path detection.

According to the path search device 15 of the present embodiment, in a path search device that performs a wide area search by using a time-divided search window, an appropriate delay profile is obtained even when transmission is temporarily stopped. Since it is possible to generate, the false detection of the path is reduced and the accuracy of the path detection is improved. Further, even in a narrow area search, the influence of noise can be reduced and a more ideal delay profile can be generated, so that the accuracy of path detection is improved. Further, since in-phase addition is not performed while transmission is stopped, processing can be reduced and power consumption can be reduced as compared with the related art.

(Second Embodiment) Next, a path search device according to a second embodiment of the present invention will be described. Figure 3
It is a block diagram which shows the structure of the base station apparatus containing the path search apparatus 25 of the 2nd Embodiment of this invention. In FIG. 3, the same components as those in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted.

As shown in FIG. 3, the radio base station apparatus according to this embodiment has a path search apparatus 25 in place of the path search 15 in the radio base station apparatus according to the first embodiment shown in FIG. It is composed.

The path search device 25 of this embodiment is shown in FIG.
The addition control unit 8 is replaced with the addition control unit 18 in the path search device 15 shown in FIG.

The addition control unit 18 controls the power addition unit 6 to stop the power addition in the transmission stop period based on the scheduling information transmitted from the upper layer such as the RNC. That is, the addition control unit 18 controls the power addition unit 6 so that the power addition is performed a fixed number of times only in a section other than the transmission suspension section using the scheduling information.

The path search device 15 of the first embodiment.
In the above, the in-phase addition in the transmission suspension period is stopped by using the scheduling information. However, the path search device 25 of the present embodiment uses the scheduling information to stop the power addition in the transmission suspension period. It tries to generate a more accurate delay profile.

However, when controlling the power addition unit 6 as shown in FIG. 3, since the data to be discarded becomes an in-phase addition unit, there is more waste than in the embodiment of FIG. Instead, according to the path search device of the present embodiment, as compared with the first path search device described above, the validity / invalidity judgment of the received data may be judged not by the slot interval but by the in-phase addition cycle. The load can be reduced accordingly.

[0040]

As described above, according to the present invention,
Even when transmission is stopped in slot units, it is possible to obtain an effect that highly accurate path detection can be performed without increasing erroneous path detection by generating an appropriate delay profile.

[Brief description of drawings]

FIG. 1 is a path search device 15 according to a first embodiment of this invention.
It is a block diagram which shows the structure of the base station apparatus containing.

2 is a timing chart showing the operation of the path search device 15 shown in FIG.

FIG. 3 is a path search device 25 according to a second embodiment of the present invention.
It is a block diagram which shows the structure of the base station apparatus containing.

FIG. 4 is a diagram showing a frame structure of an uplink DPDCH / DPCCH.

FIG. 5 is a block diagram showing a configuration of a base station device including a conventional path search device 95.

[Explanation of symbols] 1 antenna 2 High frequency receiver 3 A / D converter 4 Correlation value calculator 5 In-phase adder 6 Power addition section 7 Code generator 8 addition control unit 9 Path control section 10 Code generator 12 Detection unit 13 Lake Synthesis Department 14 Finger part 15 Path search device 18 Addition control unit 25 path search device 95 Path Search Device

Claims (4)

[Claims] 1. A path search device for detecting a path timing, which is a timing at which spreading is performed on a transmitting side, and code generation means for generating a spreading code corresponding to an assigned communication channel, and the code. The correlation value between the ideal received signal spread by multiplying the spreading code generated by the generating means and the predetermined pilot signal and the pilot signal portion added to the head position of each time slot of the input signal A correlation value calculation unit for calculating, and an in-phase addition means for performing a fixed number of in-phase additions on each of the I signal (in-phase component) and the Q signal (quadrature component) which are signal components orthogonal to each other of the orthogonally demodulated pilot signal, , The delay profile is calculated by performing power addition a fixed number of times on the signals after the in-phase addition is performed by the in-phase addition means. Power addition means for generating a route, a path control means for detecting a path timing based on the delay profile generated by the power addition means, and scheduling information for notifying beforehand a transmission suspension period transmitted from an upper layer. Based on the in-phase addition means, the addition control means for controlling to stop the in-phase addition in the in-phase addition means in the transmission stop section. 2. A path search device for detecting a path timing, which is a timing at which spreading is performed on the transmitting side, and code generation means for generating a spreading code corresponding to an assigned communication channel, and the code. The correlation value between the ideal received signal spread by multiplying the spreading code generated by the generating means and the predetermined pilot signal and the pilot signal portion added to the head position of each time slot of the input signal A correlation value calculation unit for calculating, and an in-phase addition means for performing a fixed number of in-phase additions on each of the I signal (in-phase component) and the Q signal (quadrature component) which are signal components orthogonal to each other of the orthogonally demodulated pilot signal, , The delay profile is calculated by performing power addition a fixed number of times on the signals after the in-phase addition is performed by the in-phase addition means. Power addition means for generating a route, a path control means for detecting a path timing based on the delay profile generated by the power addition means, and scheduling information for notifying beforehand a transmission suspension period transmitted from an upper layer. Based on the above, addition control means for performing control to stop the power addition in the power addition means in the transmission stop section, the path search device. 3. A path search method for detecting a path timing, which is a timing at which spreading is performed on a transmitting side, wherein a spreading code generated corresponding to an assigned communication channel and a predetermined pilot. The step of calculating the correlation value between the ideal received signal obtained by multiplying the signals and spreading, and the pilot signal part added to the beginning position of each time slot of the input signal, and the orthogonal demodulated pilot signal Transmission of a fixed number of in-phase additions for each of the I signal (in-phase component) and the Q signal (quadrature component) that are orthogonal signal components, using scheduling information that notifies in advance of the transmission suspension period transmitted from the upper layer. Steps to be performed only in a section other than the stop section, and for the signal after the in-phase addition is performed, a fixed number of power A path search method comprising: a step of generating a delay profile by performing addition; and a step of detecting a path timing based on the generated delay profile. 4. A path search method for detecting a path timing, which is a timing at which spreading is performed on a transmitting side, wherein a spreading code generated corresponding to an assigned communication channel and a predetermined pilot. The step of calculating the correlation value between the ideal received signal obtained by multiplying the signals and spreading, and the pilot signal part added to the beginning position of each time slot of the input signal, and the orthogonal demodulated pilot signal A step of performing a fixed number of in-phase additions for each of the I signal (in-phase component) and the Q signal (quadrature component) that are orthogonal signal components; and a fixed number of power additions to the signals after the in-phase addition is performed. , In the sections other than the transmission suspension section, by using the scheduling information that notifies the transmission suspension section transmitted from the upper layer in advance. A path search method comprising: a step of generating a delay profile by performing only the above; and a step of detecting a path timing based on the generated delay profile.