JP2005109541A - Path search method and path search circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a path search circuit enhancing an in-phase summation effect and improving path detection characteristics. <P>SOLUTION: A correlator 1 calculates a correlation value of a pilot signal from inputted received data. A weight multiplication section 2 monitors level fluctuations or phase shift of an output of the correlator 1 to apply weighting of amplitude multiplication or phase amount multiplication to the correlation value in response to a result of monitoring. An in-phase summation section 3 carries out in-phase summation of outputs of the correlator 1 for a preset number of times. A power summation section 4 converts a result of in-phase summation into a power value, summates powers by the preset number of times, obtains an averaged correlation power value caused by a delay (delay profile), and provides an output. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a path search circuit, and more particularly, to a path search circuit in a CDMA (Code Division Multiple Access) communication system.

  As an example of this type of prior art, in a CDMA receiver, when adding in-phase continuous data for accurate delay profile measurement (delayed wave path detection), the number of additions is varied. , Acquiring a plurality of data, and detecting the power value of the received signal or the ratio between the power of the received signal and the noise power based on the acquired data, and the detected power value or power ratio The number of data to be subjected to in-phase addition is adaptively changed according to the fading frequency by comparing the values or determining the temporal change thereof (see, for example, Patent Document 1).

  In a static radio propagation condition without fading, the path detection capability improves as the in-phase addition number increases, so that the power addition number can be reduced and the detection time is also shortened.

  However, when there is a level fluctuation due to fading, the received signal point changes, and there is a problem that the effect of in-phase addition is reduced.

JP 2001-274724 A

  The conventional path search circuit described above adaptively changes the number of data to be added in-phase according to the fading frequency. However, when there is a level fluctuation due to fading, the received signal point changes, so that the in-phase addition is performed. There is a disadvantage that the effect is reduced.

  An object of the present invention is to provide a path search circuit capable of improving the in-phase addition effect and improving the path detection characteristic by weighting before adding the in-phase correlation values in order to eliminate such a conventional defect. Is to provide.

  It is another object of the present invention to provide a path search circuit that suppresses an increase in processing load due to weighting by using an approximation coefficient as a weighting coefficient.

  The path search method of the present invention is a path search method in a CDMA communication system, which calculates a correlation value of a pilot signal from input received data, and performs in-phase addition of the correlation value for a preset number of times. In order to increase the common-mode addition effect in the procedure of delay profile calculation for converting the value into a value and adding the power value a predetermined number of times to obtain the averaged correlation power value (delay profile) in the delay, The correlation value is weighted by complex multiplication.

  The weighting is characterized in that amplitude multiplication is performed by using an absolute value of the correlation value or an absolute value of a real part or an imaginary part of the correlation value, whichever is larger.

  In addition, when the phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ is equal to or less than a set threshold, the weighting is calculated as follows. It is characterized in that the phase correction used is performed, and when it is equal to or greater than the threshold value, the phase correction is performed using a set value within the threshold value.

  The weighting is performed by amplitude multiplication using the absolute value of the correlation value or the absolute value of the real part or the imaginary part of the correlation value, which is larger, the correlation value at the present time (time t), and the time t−t. When the phase shift amount per unit time between the correlation values in ′ is equal to or less than the set threshold value, the phase correction using the phase shift amount is set, and when it is equal to or greater than the threshold value, the phase shift amount is set within the threshold value. It is characterized by a combination of phase correction using values.

  The path search circuit of the present invention includes a correlator that calculates a correlation value of a pilot signal from input received data, an in-phase addition unit that performs in-phase addition of the correlator output a preset number of times, and in-phase addition A path search circuit having a power addition unit that converts a result into a power value, performs power addition a predetermined number of times, and obtains and outputs an averaged correlation power value (delay profile) in the delay; It is characterized by comprising a weight multiplier for monitoring level fluctuation or phase shift of the correlator output and weighting the correlation value by complex multiplication according to the monitoring result.

  Further, the weight multiplication section weights the correlation value of the correlator output using the absolute value calculated from the correlation value as a weighting coefficient.

  The weight multiplying unit is characterized in that the correlation value of the correlator output is weighted using a larger absolute value of a real part or an imaginary part calculated from the correlation value as a weighting coefficient.

  Further, the weight multiplication unit sets a phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ with respect to the correlation value of the correlator output. When the threshold value is less than or equal to the threshold value, the phase correction using the phase shift amount is performed.

  Further, the weight multiplication unit sets a phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ with respect to the correlation value of the correlator output. If the threshold value is greater than or equal to the threshold value, phase correction is performed using a set value within the threshold value.

  Further, the weight multiplication unit, with respect to the correlation value of the correlator output, an amplitude multiplication using the absolute value of the correlation value or the larger absolute value of the real part or the imaginary part of the correlation value; If the phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ is equal to or less than a set threshold, phase correction using the phase shift amount; When the threshold is equal to or greater than the threshold, the phase correction using a set value within the threshold is performed in combination.

  The weight multiplication unit may perform complex multiplication using a time-series average value of the correlation values for the correlation value of the correlator output.

  Further, the weight multiplication unit is characterized by performing complex multiplication using a time series FIR (Finite Impulse Filter) calculation result of the correlation value instead of the time series average value of the correlation value.

  According to the path search method and path search circuit of the present invention, weighting is performed before the correlation values are added in phase, thereby improving the in-phase addition effect and improving the path detection characteristics.

  In addition, by applying a certain degree of weighting to the influence of instantaneous strong electric field level due to noise or fading compensation, erroneous detection of reception path timing due to noise can be reduced, and good reception characteristics can be obtained.

  Next, the best mode for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of an embodiment of a path search circuit of the present invention. The path search circuit calculates delay profiles for multiple different paths from the received signal, detects effective correlation value peaks as path timings from the obtained delay profiles, and notifies the timing to the finger unit and rake synthesis unit (not shown) To do.

  The figure also shows a delay profile calculation unit in the path search circuit.

  Referring to FIG. 1, a delay profile calculation unit 10 includes a correlator 1 that calculates a correlation value of a pilot signal from an input signal, a weight multiplication unit 2 that weights the output of the correlator 1, and an in-phase addition unit 3 that performs in-phase addition. And a power adding unit 4 for obtaining an averaged correlation power value (delay profile).

  Next, the operation of the delay profile calculation unit will be described in detail with reference to FIG.

  According to FIG. 1, the correlator 1 performs despreading by multiplication of the baseband input signal converted into a digital signal and the pilot symbol of the spreading code, and outputs a correlation value.

  The weight multiplication unit 2 monitors the correlation value of the correlator 1 output and performs weighting according to the correlation value.

  The in-phase addition unit 3 adds the weighted correlation value a predetermined number of times for each I signal component and Q signal component.

  The power addition unit 4 converts the in-phase addition result into a power value, performs power addition for the set number of times, and obtains a correlation power value in the delay. Further, the correlation power values are totaled and output as a delay profile. This delay profile indicates the correlation power in each delay time, and the amount of delay at the peak is notified to a Finger section (not shown).

  Next, the weighting operation will be described.

  First, the output of the correlator 1 is expressed as h1 (t) = h0 (t) + n (t) where h0 (t) is a signal in the absence of noise and n (t) is noise.

If there is no noise, the fading state can be estimated from the output of the correlator 1, and if h0 (t) is known, h1 (t) * h0 ^* (t) (h0 ^* (t) is a complex conjugate of h0 (t)). By calculating and adding in time, the S / N ratio can be improved.

  However, when h0 (t) cannot be completely estimated, if h1 (t) is used as it is instead of h0 (t), the characteristics are deteriorated due to the influence of noise n (t).

  Next, the weighting operation of the present invention will be described.

When the output of the correlator 1 is a complex signal, the output is expressed as h1 (t) = x1 (t) + ji1 (t).
Here, the correlator 1 output h1 (t) is first multiplied by the absolute value | h1 (t) |.

  Further, if the phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ is Δφ = arg {h1 (t) −h1 (t−t ′)}, When the absolute value | Δφ | is equal to or smaller than π / 4, for example, the imaginary part exp (−jΔφ) of the phase shift amount is multiplied. Here, j represents an imaginary number.

  By the above operation, the effect of the subsequent in-phase addition can be enhanced by enhancing the amplitude of the correlation value and correcting the phase shift.

  When it is difficult to implement the calculation of the absolute value | h1 (t) | on the hardware with respect to the amplitude multiplication, as the weighting coefficient of the weight multiplication unit 2, for example, instead of | h1 (t) | , H1 (t), whichever has the larger absolute value of the real part or imaginary part, that is, max (| x1 (t) |, | y1 (t) |) can be used as the approximate weighting factor.

  In this case, although the degree of improvement is somewhat reduced, the circuit configuration can be simplified, so that the processing load can be reduced.

  Further, regarding the multiplication of the phase amount shift amount, when the phase shift amount Δφ per unit time between the correlation value at the present time (time t) and the correlation value at time t−t ′ is, for example, π / 4 or more, a certain set value It is conceivable that the correction is limited to the above.

  When the phase shift amount Δφ is large, it is possible to prevent the correlation of the received data from being impaired by limiting it in consideration of an instantaneous increase. As the set value at this time, for example, ± π / 8 within ± π / 4 is assumed.

Next, another weighting coefficient calculation method will be described assuming that a 3-tap FIR (Finite Impulse Filter) is used.
From the correlation value of the correlator 1 output, the slot period is T,
h1 ′ (t) = α1 * h1 (t−T) + α2 * h1 (t) + α1 * h1 (t + T)
And a weighting factor based on h1 ′ (t) = x1 ′ (t) + ji1 ′ (t) from the complex signal output.
However, α1 and α2 are coefficients satisfying α1 + α2 + α1 = 1.
Here, when α1 and α2 have the same value, this is equivalent to a case where a time series average is simply calculated.

  As described above, the path search circuit of the present invention enhances the effect of in-phase addition by performing weighting by correlation value amplitude multiplication, phase shift correction, or phase correction restriction before performing in-phase addition of correlation values. Thus, the S / N ratio can be improved.

  Further, by providing a restriction on the weighting, it is possible to avoid erroneous path detection, simplify the additional process of the path search circuit, and suppress an increase in processing load.

  In particular, when the Doppler frequency is large and fading that cannot be ignored with respect to the correlator output period is applied, great improvement can be expected.

It is a block diagram of an embodiment of a path search circuit of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Correlator 2 Weight multiplication part 3 In-phase addition part 4 Power addition part 10 Delay profile calculation part

Claims (12)

A path search method in a CDMA communication system, wherein a correlation value of a pilot signal is calculated from input received data, the correlation value is converted into a power value by performing in-phase addition a predetermined number of times, and the power value In a delay profile calculation procedure for adding a predetermined number of times to obtain an averaged correlation power value (delay profile) in the delay, in order to enhance the in-phase addition effect, the correlation value is calculated by complex multiplication. A path search method characterized by weighting. 2. The path according to claim 1, wherein the weighting is an amplitude multiplication by using an absolute value of the correlation value or an absolute value of a real part or an imaginary part of the correlation value, whichever is larger. Search method. For the weighting, when the phase shift amount per unit time between the correlation value at the present time (time t) and the correlation value at time t-t ′ is equal to or less than a set threshold, the phase shift amount is used. 2. The path search method according to claim 1, wherein phase correction is performed, and when the threshold value is equal to or greater than the threshold value, phase correction is performed using a set value within the threshold value. The weighting is performed by amplitude multiplication using the absolute value of the correlation value or the larger absolute value of the real part or the imaginary part of the correlation value, and the correlation value at the present time (time t) and the time t−t ′. When the phase shift amount per unit time between the correlation values is equal to or less than the set threshold value, the phase correction using the phase shift amount is set. The path search method according to claim 1, wherein the phase correction is used in combination. A correlator that calculates the correlation value of the pilot signal from the input received data, an in-phase addition unit that performs in-phase addition of the correlator output for a preset number of times, and converts the in-phase addition result into a power value and sets in advance And a power adder that calculates and outputs an averaged correlation power value (delay profile) in the delay and outputs a level fluctuation or phase shift of the correlator output. A path search circuit comprising a weight multiplication unit that monitors the correlation value and performs weighting by complex multiplication on the correlation value according to the monitoring result. 6. The path search circuit according to claim 5, wherein the weight multiplication unit weights the correlation value of the correlator output using an absolute value calculated from the correlation value as a weighting coefficient. 6. The weight multiplying unit weights the correlation value of the correlator output with a larger absolute value of a real part or an imaginary part calculated from the correlation value as a weighting coefficient. The described path search circuit. The weight multiplying unit is a threshold in which a phase shift amount per unit time between a correlation value at the present time (time t) and a correlation value at time t−t ′ is set with respect to the correlation value of the correlator output. 6. The path search circuit according to claim 5, wherein phase correction using the phase shift amount is performed in the following cases. The weight multiplying unit is a threshold in which a phase shift amount per unit time between a correlation value at the present time (time t) and a correlation value at time t−t ′ is set with respect to the correlation value of the correlator output. 6. The path search circuit according to claim 5, wherein in the above case, phase correction is performed using a set value within the threshold. The weight multiplication unit performs amplitude multiplication using an absolute value of the correlation value or an absolute value of a real part or an imaginary part of the correlation value, which is larger than the correlation value of the correlator output, When the phase shift amount per unit time between the correlation value at time t) and the correlation value at time t−t ′ is equal to or less than a set threshold value, phase correction using the phase shift amount and the threshold value 6. The path search circuit according to claim 5, wherein in the above case, phase correction using a set value within the threshold is combined. 6. The path search circuit according to claim 5, wherein the weight multiplication unit performs complex multiplication using a time-series average value of the correlation values for the correlation value of the correlator output. 12. The weight multiplication unit performs complex multiplication using a time series FIR (Finite Impulse Filter) calculation result of the correlation value instead of the time series average value of the correlation value. Path search circuit.

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