JP2001196974A - Cdma wireless receiver and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a CDMA receiver that can receive a radio wave with high quality. SOLUTION: A path measurement circuit 23 measures the path number of a received radio wave. A mobile speed measurement circuit 22 measures the moving speed of the CDMA wireless receiver. An interference quantity measurement circuit 21 measures the interference quantity of a received radio wave. An averaging time/reception timing changeover period control section 24 decides the averaging time of a delay profile and the switching period of the reception timing in response to the measured path number, moving speed and interference quantity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a CDMA radio receiving apparatus (for example, a mobile radio) and a control method, and more specifically, to averaging a delay profile according to the number of paths of a received radio wave. The present invention relates to a CDMA radio receiving apparatus and a control method for determining a switching period of time and / or reception timing.

[0002]

2. Description of the Related Art In a CDMA radio access system, a transmission signal is spread with an infinite number of long codes at a very long cycle. Different types of long codes have an orthogonal relationship, and the correlation with each long code is small. Further, even in the same long code, those having different phases are in an orthogonal relationship. Therefore, in order to establish wireless communication, the receiver side specifies the type of long code and detects long code timing.

In the CDMA radio access system, when a radio wave transmitted from a transmitter arrives at a receiver through a plurality of paths having different propagation distances, the received power is added by adding the respective propagation paths. Can be increased.

[0004]

In order to keep the reception quality high, it is preferable that the receiver checks and acquires (certifies) the reception timings of all the propagation paths as needed.

FIG. 1 is a diagram for explaining an example of checking and acquiring path reception timing. For example, when the delay profile shown in FIG. 1 is obtained, a certain threshold value P _th
It is conceivable that the delay times τ ₁ , τ _2, and τ ₃ having the above-described peak values of the reception level are regarded as the delay time (reception timing) of the path.

[0006] In order to accurately grasp the reception timing of radio waves, it is preferable to average the measured delay profiles.

FIG. 2 shows an example of a measured delay profile and an averaged delay profile.

[0008] The longer the averaging time, the higher the accuracy. That is, erroneous path recognition (recognition of path reception timing) due to the influence of noise or the like is reduced. However, when the propagation path fluctuates at high speed, if the averaging time is increased, the period for switching the reception timing becomes longer, so that the optimal propagation path cannot always be selected.

[0009] On the other hand, if the averaging time is shortened, the period for switching the reception timing is shortened, but the accuracy is deteriorated.

Therefore, the radio wave propagation environment (for example, the number of paths) around the CDMA radio receiving apparatus, the moving speed of the CDMA radio receiving apparatus, the amount of received interference (the amount of received radio wave interference)
, There is an optimal averaging time and a reception timing switching cycle (switching time). In mobile communications, CDM
The radio wave propagation environment around the A radio receiving apparatus, the moving speed of the CDMA radio receiving apparatus, and the amount of received interference may fluctuate over time.

FIG. 3 is a diagram showing a configuration example of a conventional CDMA radio receiving apparatus. The CDMA radio receiving apparatus shown in FIG. 3 includes an antenna 101, a mixer 102, a reference wave generator 10
3, A / D converter 105, delay profile measurement circuit 1
06, delay profile averaging circuit 107, spreading code generator 108, reception timing control unit 109, RAKE
Combiner 114, and despreading units 115-1, 115-2
Is provided. The despreading units 115-1 and 115-2 respectively include the despreaders 110-1 and 110-2 and the detector 11.
2-1 and 112-2. In the example of FIG. 3, a CDMA radio receiving apparatus including two despreading units 115-1 and 115-2 is shown.

A radio wave received by an antenna 101 is multiplied by a reference wave generated by a reference wave generator 103 in a mixer 102 and converted into a baseband signal. Converted baseband signal (analog signal)
Is converted into a digital signal in the A / D converter 105.

The converted digital signal is supplied to a despreading unit 11.
5-1 and 115-2 despreaders 110-1 and 110-2
, The signals are multiplied by the spreading code generated by the spreading code generator 108, and the detectors 112-1 and 112-
2 and is input to the RAKE combiner 114. RAKE combiner 114 combines signals from despreading units (in the example of FIG. 3, two despreading units 115-1 and 115-2). The synthesized signal is output as user data.

The digital signal converted by the A / D converter 105 is supplied to a delay profile measuring circuit 106.
And the delay profile is measured. The measured delay profile is the delay profile averaging circuit 1
07 and the reception timing control unit 109
Is input to The reception timing control unit 109 determines the reception timing of the radio wave (the reception timing for each of the despreaders 110-1 and 110-2 in the example of FIG. 3) based on the averaged delay profile, and determines the determined reception timing. Instruct the spreading code generator 108. Spreading code generator 108 outputs a spreading code to despreaders 110-1 and 110-2 at the designated reception timing.

As described above, in the conventional CDMA radio receiving apparatus, even if the surrounding radio wave propagation environment, the moving speed of the CDMA radio receiving apparatus, and the amount of interference fluctuate with time, the averaging time of the delay profile and the reception timing are not changed. Since the switching period (switching time) is constant, high-quality reception cannot be performed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a high quality CDMA radio receiver by determining a delay profile averaging time and / or a reception timing switching cycle in accordance with the number of paths of a received radio wave. Is to be able to perform a proper reception.

[0017] In addition, by determining the averaging time of the delay profile and / or the switching cycle of the reception timing according to the moving speed of the apparatus that performs the CDMA radio reception, high-quality reception can be performed. It is to be.

Further, according to the amount of interference of the received radio waves,
An object of the present invention is to enable high-quality reception by determining a delay profile averaging time and / or a switching cycle of a reception timing.

[0019]

According to an aspect of the present invention, there is provided a CDMA radio receiving apparatus, comprising: a delay profile measuring unit for measuring a delay profile of a received radio wave; Delay profile averaging means for averaging a delay profile measured by the delay profile measuring means, reception timing control means for determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging means, and the delay profile A path number measuring means for measuring the number of radio wave paths based on the delay profile averaged by the averaging means, and an averaging time by the delay profile averaging means according to the number of paths measured by the path number measuring means, And / or a reception timing by the reception timing control means. Averaging time / reception timing switching cycle control means for determining a switching cycle of the packet, and the delay profile averaging means performs averaging with the averaging time determined by the averaging time / reception timing switching cycle control means. The reception timing control means determines the reception timing based on the switching cycle determined by the averaging time / reception timing switching cycle control means.

According to a second aspect of the present invention, there is provided a CDMA radio receiving apparatus, comprising: a delay profile measuring means for measuring a delay profile of a received radio wave; and a delay for averaging the delay profiles measured by the delay profile measuring means. Profile averaging means, reception timing control means for determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging means, and the CDMA radio receiving apparatus based on a temporal change in the reception level of the received radio wave. A moving speed measuring means for measuring the moving speed of the moving object, and an averaging time by the delay profile averaging means and / or a receiving timing by the receiving timing controlling means according to the moving speed measured by the moving speed measuring means. Averaging time and reception to determine switching cycle And a timing switching period control unit, said delay profile averaging unit, the averaging time and reception timing switching period control means performs an averaging in averaging time was determined, the reception timing control means,
The reception timing is determined based on the switching period determined by the averaging time / reception timing switching period control means.

According to a third aspect of the present invention, there is provided a CDMA radio receiving apparatus, wherein a delay profile measuring means for measuring a delay profile of a received radio wave, and a delay for averaging the delay profiles measured by the delay profile measuring means. Profile averaging means, reception timing control means for determining the reception timing of radio waves based on the delay profile averaged by the delay profile averaging means, interference amount measurement means for measuring the amount of interference of the received radio waves, Averaging time / reception timing switching cycle control for determining the averaging time by the delay profile averaging means and / or the reception timing switching cycle by the reception timing control means according to the amount of interference measured by the quantity measuring means. Means, said delay profile averaging means. , The performs averaging in the averaging time and the reception timing switching period control means averaging time is determined, the reception timing control means, the averaging time,
The reception timing is determined based on the switching cycle determined by the reception timing switching cycle control means.

According to a fourth aspect of the present invention, there is provided a control method for CDMA radio reception, comprising: a delay profile measuring step of measuring a delay profile of a received radio wave;
A delay profile averaging step of averaging a delay profile measured by the delay profile measuring step; a reception timing control step of determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging step; A path number measuring step of measuring the number of radio wave paths based on the delay profile averaged by the profile averaging step, and an averaging time in the delay profile averaging step according to the path number measured by the path number measuring step. And / or an averaging time / reception timing switching cycle control step for determining a switching cycle of the reception timing in the reception timing control step, wherein the delay profile averaging step includes: Averaging is performed with the averaging time determined in the timing switching cycle control step, and the reception timing control step determines a reception timing with the switching cycle determined in the averaging time / reception timing switching cycle control step. I do.

According to a fifth aspect of the present invention, there is provided a control method for CDMA wireless reception, comprising: a step of measuring a delay profile of a received radio wave;
A delay profile averaging step for averaging the delay profile measured by the delay profile measurement step; a reception timing control step of determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging step; A moving speed measuring step of measuring a moving speed of a device that performs CDMA radio reception based on a temporal change in a reception level of a radio wave, and an average in the delay profile averaging step according to the moving speed measured in the moving speed measuring step. And / or an averaging time / reception timing switching cycle control step of determining a reception timing switching cycle in the reception timing control step, wherein the delay profile averaging step comprises: Averaging is performed with the averaging time determined in the timing switching cycle control step, and the reception timing control step determines a reception timing with the switching cycle determined in the averaging time / reception timing switching cycle control step. I do.

According to a sixth aspect of the present invention, there is provided a control method for CDMA radio reception, comprising: a step of measuring a delay profile of a received radio wave;
A delay profile averaging step for averaging the delay profile measured by the delay profile measurement step; a reception timing control step of determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging step; An interference amount measuring step of measuring the amount of radio wave interference, and an averaging time in the delay profile averaging step and / or a reception timing in the reception timing control step according to the amount of interference measured in the interference amount measuring step. Averaging time / reception timing switching cycle control step of determining a switching cycle of the delay profile averaging step,
Averaging is performed with the averaging time determined in the reception timing switching cycle control step, and the reception timing control step determines the reception timing with the switching cycle determined in the averaging time / reception timing switching cycle control step. And

According to the above configuration, in CDMA radio reception, the averaging time of the delay profile and / or the switching cycle of the reception timing are determined in accordance with the number of paths of the received radio wave, thereby achieving high quality. Reception can be performed.

In addition, high-quality reception can be performed by determining the averaging time of the delay profile and / or the switching cycle of the reception timing in accordance with the moving speed of the apparatus that performs CDMA wireless reception.

Further, according to the amount of interference of the received radio waves,
By determining the averaging time of the delay profile and / or the switching cycle of the reception timing, high-quality reception can be performed.

[0028]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 4 shows a CDMA according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating a configuration example of a wireless reception device. CD shown in FIG.
The MA radio receiving apparatus includes an antenna 1, a mixer 2, a reference wave generator 3, an A / D converter 5, a delay profile measuring circuit 6, a delay profile averaging circuit 7, a spreading code generator 8, a reception timing control unit 9, It includes a RAKE combiner 14, despreading units 15-1 and 15-2, an interference amount measuring circuit 21, a moving speed measuring circuit 22, a path number measuring circuit 23, and an averaging time / reception timing switching cycle control unit 24. The parts other than the antenna 1 are hardware or DSP (D
digital signal processor) or the like.

The despreading units 15-1 and 15-2 respectively include despreaders 10-1 and 10-2 and a detector 12-1,
12-2. In the example of FIG. 4, two systems of despreading units 1
Although a CDMA wireless receiving apparatus including 15-1 and 115-2 is shown, a CDMA wireless receiving apparatus including one or three or more despreading units may be used.

As in the conventional CDMA radio receiving apparatus of FIG. 3, the radio wave received by the antenna 1 is multiplied by the reference wave generated by the reference wave generator 3 in the mixer 2 and converted into a baseband signal. . The converted baseband signal (analog signal) is converted to a digital signal in the A / D converter 5.

The converted digital signal is supplied to a despreading unit 15.
-1 and 15-2 despreaders 10-1 and 10-2 are multiplied by the spreading code generated by the spreading code generator 8 and detected by the detectors 12-1 and 12-2 to obtain a RAKE combiner. 14 is input. In the RAKE combiner 14, the despreading unit (in the example of FIG. 4, two despreading units 1
5-1 and 15-2) are combined. The synthesized signal is output as user data.

The digital signal converted by the A / D converter 5 is input to a delay profile measuring circuit 6, where the delay profile is measured. The measured delay profile is averaged in the delay profile averaging circuit 7 and input to the reception timing control unit 9. The reception timing control unit 9 determines the reception timing of the radio wave (reception timing for each of the despreaders 10-1 and 10-2 in the example of FIG. 4) based on the averaged delay profile, and determines the determined reception timing. Instruct the spreading code generator 8. The spreading code generator 8 outputs a spreading code to the despreaders 10-1 and 10-2 at the designated reception timing.

FIG. 5 is a diagram showing a configuration example of the delay profile measuring circuit 6 according to the present embodiment. The delay profile measurement circuit 6 shown in FIG. 5 includes a shift register 31, a code setting unit 32, multiplication units 33-1 to 33-n, and an addition unit 3.
4 and a memory 35.

The digital signals output from the A / D converter 5 are sequentially stored in the shift register 31. The digital signal stored in the shift register 31 is supplied to the multiplication unit 33-
In steps 1 to 33-n, the signal is multiplied by the spread code (for example, search code, scramble code, short code) output from the code setting unit 32. The result of the multiplication is added in the adder 34 and stored in the memory 35. The above process is repeated by shifting the digital signal (data) in the shift register 31 to measure (generate) a delay profile.

The CDMA radio receiving apparatus according to the present embodiment determines the averaging time of the delay profile and the switching period of the reception timing according to the number of paths of the received radio wave.

The path number measuring circuit 23 measures the number of paths of radio waves (delayed radio waves) based on the delay profile averaged by the delay profile averaging circuit 7. For example,
As shown in FIG. 1, when three delay times τ ₁ , τ ₂ and τ ₃ are determined (certified) as the reception timing of the path,
The number of passes is three.

The averaging time / reception timing switching cycle control unit 24 determines the averaging time of the delay profile and the switching cycle of the reception timing according to the number of paths measured by the path number measurement circuit 23. Then, the determined averaging time of the delay profile is specified to the delay profile averaging circuit 7, and the determined reception timing switching cycle is specified to the reception timing control unit 9. The delay profile averaging circuit 7 averages the delay profiles at the specified averaging time, and the reception timing control unit 9 determines (switches) the reception timing at the specified switching cycle.

In the present embodiment, the averaging time / reception timing switching cycle control section 24 increases the averaging time of the delay profile as the number of paths increases.
If the number of paths is large, the S / N (S / N ratio) of each path deteriorates, so that the averaging time is lengthened and path assignment (path recognition) with higher accuracy is performed.

The averaging time / reception timing switching cycle control unit 24 prevents the switching cycle of the reception timing from being longer than the averaging time of the delay profile.

The CDMA radio receiving apparatus according to the present embodiment determines the averaging time of the delay profile and the switching cycle of the reception timing according to the number of paths of the received radio wave. , Or only one of the switching periods of the reception timing may be determined.

The CDMA radio receiving apparatus according to the present embodiment determines the averaging time of the delay profile and / or the switching cycle of the receiving timing according to its own moving speed.

The moving speed measuring circuit 22 measures the moving speed of the CDMA radio receiving apparatus based on a temporal change in the reception level of the received radio wave.

FIG. 6 is a diagram showing a configuration example of the moving speed measuring circuit 22 according to the present embodiment. The moving speed measuring circuit 22 shown in FIG. 6 includes an average level measuring unit 41, a crossing frequency counter 42, a moving speed estimating unit 43, and a level crossing frequency characteristic database 44.

The average level measuring section 41 focuses on any one path (delay time) of the delay profile measured by the delay profile measuring circuit 6, and calculates the average value A of the reception level of the path for a certain period. . The number-of-intersections counter 42 counts, during a certain period, the number of times N _{A at} which the rapidly changing reception level of the path of interest crosses the average value A of the reception levels measured by the average level measurement unit 41. The moving speed estimating unit 43 estimates the moving speed by accessing the level crossing frequency characteristic database 44 based on the number of crossings counted by the crossing frequency counter 42. The relationship between the number of crossings and the moving speed is stored in the level crossing frequency characteristic database 44.

In the case of an ideal Rayleigh fading, the following relationship exists (supervised by Okumura and Shinji: "Basics of mobile communication")
(IEICE, page 70).

[0047]

(Equation 1)

[0048]

(Equation 2)

N _max : maximum number of level crossings v: moving speed c: light speed f: carrier frequency Accordingly, the following relationship is obtained.

[0050]

(Equation 3)

Therefore, according to this equation, the carrier frequency f
Is determined in advance, and the moving speed v can be known by measuring the maximum number of level crossings. In the present embodiment, the maximum level crossing frequency N _max is approximated to the frequency N _A at which the reception level of the path of interest crosses the average value A of the reception levels measured by the average level measurement unit 41, and The moving speed v is calculated using (3).

The averaging time / reception timing switching cycle control unit 24 determines the averaging time of the delay profile and the switching cycle of the reception timing according to the moving speed measured by the moving speed measuring circuit 22. Then, the determined averaging time of the delay profile is specified to the delay profile averaging circuit 7, and the determined reception timing switching cycle is specified to the reception timing control unit 9. The delay profile averaging circuit 7 averages the delay profiles at the specified averaging time, and the reception timing control unit 9 determines the reception timing at the specified switching cycle.

In the present embodiment, the averaging time / reception timing switching cycle control section 24 shortens the averaging time of the delay profile as the moving speed increases. This is because when the moving speed is high, the propagation path fluctuates instantaneously, and follows the fluctuation. On the other hand, when the moving speed is low, the averaging time of the delay profile is lengthened to improve the accuracy of path selection (certification).

FIGS. 7 and 8 are diagrams showing examples of the averaging time with respect to the moving speed. The averaging time for the moving speed may be obtained by using a calculation formula, or as shown in FIG.
The averaging time may be determined for the moving speed in a certain section based on experimental values measured in advance.

The averaging time / reception timing switching cycle control section 24 shortens the reception timing switching cycle as the moving speed increases. This is because when the moving speed is high, the influence of shadowing or fading is strongly exerted. On the other hand, when the moving speed is low, the switching period of the reception timing is lengthened to reduce the power consumption of the reception timing control unit 9 and the like.

Further, the averaging time / reception timing switching cycle control unit 24 prevents the switching cycle of the reception timing from being longer than the averaging time of the delay profile.

The CDMA radio receiving apparatus according to the present embodiment determines the averaging time of the delay profile and the switching period of the reception timing according to its own moving speed. Alternatively, only one of the reception timing switching periods may be determined.

The CDMA radio receiving apparatus according to this embodiment determines the averaging time of the delay profile and / or the switching cycle of the reception timing according to the amount of interference of the received radio waves.

The interference amount measuring circuit 21 measures the interference amount of the received radio wave.

FIG. 9 is a diagram showing a configuration example of the interference amount measuring circuit 21 according to the present embodiment. 9 includes a detector 51, an averaging unit 52, an adding unit 53, and a power measuring unit 54.

The detector 51 detects the digital signal output from the A / D converter 5. The averaging unit 52 averages the power value of the detected digital signal. Adder 53
Then, a difference between the power value of the detected digital signal and the average power value is obtained. The power measuring unit 54 obtains the interference amount of the received radio wave based on the difference between the power values.

The averaging time / reception timing switching cycle control section 24 determines the averaging time of the delay profile and the switching cycle of the reception timing according to the amount of interference measured by the interference amount measuring circuit 21. Then, the determined averaging time of the delay profile is specified to the delay profile averaging circuit 7, and the determined reception timing switching cycle is specified to the reception timing control unit 9. The delay profile averaging circuit 7 averages the delay profiles at the specified averaging time, and the reception timing control unit 9 determines the reception timing at the specified switching cycle.

In this embodiment, the averaging time / reception timing switching cycle control section 24 increases the averaging time of the delay profile as the amount of interference increases. This is to prevent erroneous path recognition due to interference.

The averaging time / reception timing switching cycle control unit 24 prevents the switching cycle of the reception timing from being longer than the averaging time of the delay profile.

The CDMA radio receiving apparatus according to the present embodiment determines the averaging time of the delay profile and the switching cycle of the reception timing in accordance with the amount of interference of the received radio waves. , Or only one of the switching periods of the reception timing may be determined.

The CDMA radio receiving apparatus according to the present embodiment, when determining the time for averaging the delay profile and the switching cycle of the receiving timing, determines the number of paths of the received radio wave, its own moving speed, and the received radio wave. Based on the amount of interference, but one or two of those three factors
One.

When determining the averaging time and the like based on the number of paths of the received radio wave, the moving speed of the radio wave itself and the amount of interference of the received radio wave, for example, a function using these three elements as variables is prepared. Alternatively, a function may be prepared for each element to calculate the averaging time and the like, and the maximum value among the calculated values may be adopted. The determination may be made using a correspondence table as shown in FIG. 8 instead of the function.

[0068]

As described above, according to the present invention, C
In the DMA wireless reception, high-quality reception can be performed by determining the averaging time of the delay profile and / or the switching cycle of the reception timing according to the number of paths of the received radio wave.

In addition, high-quality reception can be performed by determining the averaging time of the delay profile and / or the switching cycle of the reception timing according to the moving speed of the apparatus that performs CDMA wireless reception.

Further, according to the amount of interference of the received radio waves,
By determining the averaging time of the delay profile and / or the switching cycle of the reception timing, high-quality reception can be performed.

[Brief description of the drawings]

FIG. 1 is a diagram for describing an example of investigation and acquisition of path reception timing.

FIG. 2 is a diagram illustrating an example of a measured delay profile and an averaged delay profile.

FIG. 3 is a diagram illustrating a configuration example of a conventional CDMA radio receiving apparatus.

FIG. 4 is a diagram illustrating a configuration example of a CDMA radio receiving apparatus according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating a configuration example of a delay profile measurement circuit according to an embodiment of the present invention.

FIG. 6 is a diagram illustrating a configuration example of a moving speed measuring circuit according to the embodiment of the present invention.

FIG. 7 is a diagram illustrating an example of an averaging time with respect to a moving speed.

FIG. 8 is a diagram illustrating an example of an averaging time with respect to a moving speed.

FIG. 9 is a diagram illustrating a configuration example of an interference amount measurement circuit according to an embodiment of the present invention.

[Explanation of symbols]

1, 101 Antenna 2, 102 Mixer 3, 103 Reference Wave Generator 5, 105 A / D Converter 6, 106 Delay Profile Measurement Circuit 7, 107 Delay Profile Averaging Circuit 8, 108 Spread Code Generator 9, 109 Reception Timing Control unit 10-1, 10-2, 110-1, 110-2 Despreader 12-1, 12-2, 51, 112-1, 112-2
Detector 14, 114 RAKE combiner 15-1, 15-2, 115-1, 115-2 Despreading unit 21 Interference amount measuring circuit 22 Moving speed measuring circuit 23 Path number measuring circuit 24 Averaging time / reception timing switching cycle Control unit 31 Shift register 32 Code setting unit 33-1 to 33-n Multiplication unit 34, 53 Addition unit 35 Memory 41 Average level measurement unit 42 Crossing frequency counter 43 Moving speed estimation unit 44 Level crossing frequency characteristic database 52 Averager 54 Power measurement unit

Claims (6)

[Claims] 1. A CDMA radio receiving apparatus, comprising: a delay profile measuring means for measuring a delay profile of a received radio wave; a delay profile averaging means for averaging a delay profile measured by the delay profile measuring means; Reception timing control means for determining the reception timing of radio waves based on the delay profile averaged by the delay profile averaging means; and path number measurement for measuring the number of radio wave paths based on the delay profile averaged by the delay profile averaging means. Means for determining the averaging time by the delay profile averaging means and / or the averaging time for determining the switching cycle of the reception timing by the reception timing control means according to the number of paths measured by the path number measurement means. Reception timing switching cycle control And the delay profile averaging means performs averaging with the averaging time determined by the averaging time / reception timing switching cycle control means, and the reception timing control means comprises the averaging time / reception timing. A CDMA radio receiving apparatus characterized in that the reception timing is determined based on the switching period determined by the switching period control means. 2. A CDMA radio receiving apparatus, comprising: a delay profile measuring means for measuring a delay profile of a received radio wave; a delay profile averaging means for averaging a delay profile measured by the delay profile measuring means; Receiving timing control means for determining the reception timing of the radio wave based on the delay profile averaged by the delay profile averaging means;
A moving speed measuring means for measuring a moving speed of the DMA radio receiving apparatus; and an averaging time by the delay profile averaging means and / or the reception timing controlling means according to the moving speed measured by the moving speed measuring means. Averaging time / reception timing switching cycle control means for determining the switching cycle of the reception timing by the delay profile averaging means, wherein the delay profile averaging means averages the averaging time determined by the averaging time / reception timing switching cycle control means. CDMA radio receiving apparatus, wherein the reception timing control means determines the reception timing based on the switching cycle determined by the averaging time / reception timing switching cycle control means. 3. A CDMA radio receiving apparatus, comprising: a delay profile measuring unit for measuring a delay profile of a received radio wave; a delay profile averaging unit for averaging a delay profile measured by the delay profile measuring unit; Reception timing control means for determining the reception timing of the radio wave based on the delay profile averaged by the delay profile averaging means; interference amount measurement means for measuring the amount of interference of the received radio wave; and interference measured by the interference amount measurement means. Averaging time / reception timing switching cycle control means for determining the time of averaging by the delay profile averaging means and / or the switching cycle of the reception timing by the reception timing control means in accordance with the amount. The profile averaging means is configured to calculate the averaging time. Averaging is performed by the averaging time determined by the reception timing switching cycle control means, and the reception timing control means determines the reception timing by the switching cycle determined by the averaging time / reception timing switching cycle control means. A CDMA radio receiving apparatus characterized by the above-mentioned. 4. A control method in CDMA radio reception, comprising: a delay profile measuring step of measuring a delay profile of a received radio wave; and a delay profile averaging step of averaging a delay profile measured by the delay profile measuring step. A reception timing control step of determining a radio wave reception timing based on the delay profile averaged by the delay profile averaging step; and a path measuring the number of radio wave paths based on the delay profile averaged by the delay profile averaging step. Number measuring step, and averaging time in the delay profile averaging step and / or reception timing in the reception timing control step in accordance with the number of paths measured in the path number measuring step. Averaging time / reception timing switching cycle control step of determining a switching cycle, wherein the delay profile averaging step performs averaging with the averaging time determined in the averaging time / reception timing switching cycle control step, The control method, wherein the reception timing control step determines a reception timing based on the switching cycle determined in the averaging time / reception timing switching cycle control step. 5. A control method in CDMA wireless reception, comprising: a delay profile measuring step of measuring a delay profile of a received radio wave; and a delay profile averaging step of averaging the delay profiles measured by the delay profile measuring step. A reception timing control step of determining a reception timing of a radio wave based on the delay profile averaged by the delay profile averaging step; and a CDM based on a temporal change of a reception level of the received radio wave.
A moving speed measuring step of measuring the moving speed of the device that performs the A wireless reception; and an averaging time in the delay profile averaging step and / or the reception timing according to the moving speed measured by the moving speed measuring step. An averaging time and a reception timing switching cycle control step of determining a switching cycle of the reception timing in the control step, wherein the delay profile averaging step includes the averaging time determined in the averaging time and the reception timing switching cycle control step. A control method characterized in that the reception timing is determined by the switching cycle determined in the averaging time / reception timing switching cycle control step. 6. A control method in CDMA radio reception, comprising: a delay profile measuring step of measuring a delay profile of a received radio wave; and a delay profile averaging step of averaging a delay profile measured by the delay profile measuring step. A reception timing control step of determining a reception timing of a radio wave based on the delay profile averaged by the delay profile averaging step; an interference amount measurement step of measuring an interference amount of the received radio wave; and a measurement by the interference amount measurement step. An averaging time in the delay profile averaging step and / or an averaging time / reception timing switching cycle control step for determining a reception timing switching cycle in the reception timing control step in accordance with the amount of interference obtained. The delay profile averaging step performs averaging with the averaging time determined in the averaging time / reception timing switching cycle control step, and the reception timing control step includes the averaging time / reception timing switching cycle control. A control method, wherein a reception timing is determined based on the switching cycle determined in the step.