KR100992727B1 - Method for determinating optimal parameter of multi-path searcher - Google Patents

Abstract

The parameter derivation method of the multipath searcher according to the present invention calculates the detection probability and the pulse alarm probability most similar to the target detection probability and the pulse alarm probability while varying the coherent sum interval (length) and the number of integrals after the detection, and once the target detection is performed. When the detection probability and the pulse alarm probability most similar to the probability and the pulse alarm probability are calculated, the corresponding coherent sum interval and the number of post-detection integrals are determined as the optimal parameters.

Multipath Finder. Parameter Determination, Coherent Sum, Probability of Detection

Description

Optimal Parameter Derivation Method of Multipath Searcher {METHOD FOR DETERMINATING OPTIMAL PARAMETER OF MULTI-PATH SEARCHER}

1 is a structure of a transmitter for a multipath searcher in a terminal of W-CDMA.

2 is a structure of a multipath searcher of a receiver

3 shows a transmitter structure for transmitting four pilot channels

4 is a multipath searcher architecture for four pilot channel receptions.

5 is a flowchart illustrating a parameter determination method of a multipath searcher according to the present invention.

Figure 6 is a graph showing the calculation value of the detection probability and the pulse alarm probability in accordance with the formula applied in the present invention.

FIG. 7 is a table illustrating a correlation between a coherent sum interval and a Doppler frequency error applied to a multipath path detector. FIG.

The present invention relates to a multipath searcher of a mobile communication system, and more particularly, to a method for deriving an optimal parameter in a multipath searcher in response to an increase in the number of transmit antennas.

In general, the multipath searcher is located at the front end of the rake receiver to search for the multipath of the pilot channel transmitted from the transmitting end and deliver the multipath to the rake fingers of the rake receiver. Since the multipath searcher has the same conventional structure applied to the terminals of the asynchronous and synchronous CDMA systems, only the multipath searcher applied to the terminals of the asynchronous W-CDMA system will be described.

1 is a structure of a transmitter for a multipath searcher in a terminal of W-CDMA.

Referring to FIG. 1, two pilot channels transmitted from a base station of a W-CDMA system are transmitted to a UE through two antennas Tx1 and Tx2 using the same channelization code C _OVSF and scrambling code C _SC . Is sent. In this case, two pilot symbol patterns AA, AA or -AA are used for transmission diversity allocated to each antenna.

For example, the serial pilot symbols AA to be transmitted are input to the mixers 11a and 11b through the serial-to-parallel converter 10, respectively, and the mixers 11a and 11b are input to the input pilot symbols. The channelization code C _OVSF is multiplied to generate an I channel signal and a Q channel signal. At this time, the Q channel signal is converted into a complex value in the mixer 12.

The adder 13 adds the outputs of the mixers 11a and 12, and the mixer 14 spreads the output signal of the adder 13 to the scrambling code C _SC . The signal spread by the mixer 14 is separated into a real part Re {s} and an imaginary part Im {S} by the signal separator 15 and then filtered by the transmission filters 16a and 16b. The two filtered signals are added by adder 18 after multiplying cos (wt) and sin ((wt) in mixers 17a. 17b, respectively. Thus, the pilot channel signal added in adder 18 is added. It is transmitted to the terminal through the transmission antenna (Tx1).

For convenience of explanation, only the transmission operation of the pilot symbol AA is described, but another pilot symbol AA or -AA is also the same as the elements 10-18 in the pilot symbol AA. After the sequential processing in the ()) will be transmitted to the terminal through the transmit antenna (Tx2).

The transmit diversity signals transmitted from the transmitter are transmitted to the receiver through a multipath. The cell searcher (not shown) of the receiving end allocates the slot synchronization for the multipath and the seed of the scrambling code to the reference finger, and then performs a slot detected by performing AFC (Automatic Frequency Control) and DLL (Delay Locked Loop) operations. Pass the sync value to the multipath finder. The multipath searcher receives a pilot channel signal by searching for a window size determined based on the slot synchronization value, applies a calculation process described later to the received pilot channel signal, searches for the location of the multipaths, and then searches for the location of the multipath. Is assigned to the rake fingers of the rake receiver.

2 is a structure of a multipath searcher of a receiver.

Referring to FIG. 2, the reception filter 30 of the multipath searcher filters the signal received through the reception antenna Rx and outputs the result to the mixer 31, and the mixer 310 scrambling code C _SC on the received signal. The I and Q channel signals are despread by the channelization code C _OVSF in the mixers 33a and 33b, respectively, and then separated into the I and Q channel signals. Decoded into two pilot symbol patterns AA, AA or -AA in 33d), where the mixers 33a and 33c are multiplied by the pilot symbol pattern AA, and the mixers 33b and 33d are multiplied. The pilot symbol pattern AA or -AA is multiplied.

The accumulators 34a-34d are coherent accumulators, and accumulate the symbols decoded by the mixers 33a-33d during the coherent sum period N, respectively, and store the energy calculator 35a-. 35d) squares the cumulative values of the accumulators 34a-34d to perform non-coherent summation to remove noise components from the decoded symbols. In this case, N represents the number of symbols (1 symbol = 256 chips) for the coherent sum.

In general, since the transmitted symbols are decoded in units of two symbols, the adder 36 adds the outputs Y _I1 and Y _Q1 of the energy calculating units 35a and 35c, and the adder 37 adds the energy calculating unit. The outputs Y _I2 and Y _Q2 of the 35a and 35c are added, and the adder 38 adds the outputs of the adders 36 and 37 and outputs them to the accumulator 39.

Accordingly, the accumulator 39 detects pilot channel symbols by performing post-detection integration on the output of the adder 38 for a predetermined number of times. In this case, the integration after detection is to obtain a higher detection probability (P _D ) at a constant pulse alarm probability (P _F ) when the detection probability (P _D ) and the pulse alarm probability (P _F ) are obtained. Apply.

3 shows a transmitter structure for four pilot channel transmissions.

Referring to FIG. 3, each of the pilot symbols AA, AA or -AA is coded by two channelization codes C _OVSF1 , C _OVSF2 and one scrambling code C _SC , and then four transmit antennas. Transmitted through (Tx1-Tx4). In this case, the pattern of the symbol sequence for transmit diversity assigned to each transmit antenna is set differently.

4 is a multipath searcher structure for receiving four pilot channels.

The operation of the multipath searcher shown in FIG. 4 is basically the same as that of the multipath searcher shown in FIG. That is, the received signal is processed using one scrambling code (C _SC ) and two channelization codes (C _OVSF1 ) and (C _OVSF2 ), followed by symbols according to two pilot symbol patterns AA, AA or -AA. Decoded into units of signal. The decoded signal is coherently accumulated for each of I and Q channels in a plurality of accumulators and then squared by a plurality of energy calculators. The symbol components of the I and Q channels output from the energy calculators are sequentially added to each other in the adder and finally processed in the accumulator.

Until now, since the transmitting end of the W-CDMA system transmits data using only one transmitting antenna, the receiving end (terminal) matches the performance of the receiver corresponding to one transmitting antenna. However, when the number of transmitting antennas increases, in order to accurately receive a signal transmitted through a multipath, a value of a reception parameter must be reset in more detail according to the number of transmission antennas.

However, in the related art, as the number of antennas increases, it is difficult to optimize the parameters one by one through trial and error because it does not suggest a separate method for deriving an optimal parameter by simply using the structure shown in FIG. 2. There was this.

Accordingly, an object of the present invention is to provide a signal detection method which can improve the detection performance of a transmission signal.

Another object of the present invention is to provide a method for effectively deriving an optimal parameter value of a multipath searcher according to an increase in the number of transmit antennas.

In order to achieve the above object, a method for deriving a parameter of a multipath searcher according to the present invention in a mobile communication terminal receiving signals transmitted from a plurality of transmitting antennas and searching for multipath includes: a target detection probability and a pulse ( false) setting an alarm probability; Calculating a detection probability and a pulse alarm probability; And comparing the calculated detection probability and the pulse alarm probability with the target detection probability and the pulse alarm probability, respectively, to determine an optimal parameter value according to the number of transmitting antennas.

Preferably, the parameter value represents a coherent sum interval and the number of detections after integration.

Preferably, the parameter value is determined when the calculated detection probability is greater than or equal to the target detection probability and the calculated pulse alarm probability is less than the target pulse alarm probability.

Preferably, the parameter value determining step includes calculating a detection probability and a pulse alarm probability most similar to a target detection probability and a pulse alarm probability while increasing the coherent sum length and the number of post-integral integrations; And determining the number of coherent sum intervals and post-integration integrals applied to the calculated detection probability and the pulse alarm probability as optimal parameters.

Preferably, the calculating step includes checking whether the calculated detection probability and the pulse alarm probability are similar to the target detection probability and the pulse alarm probability; Checking whether the attenuation value due to the Doppler effect is equal to or greater than a predetermined value when the calculated detection probability and the pulse alarm probability are not similar to the target detection probability and the pulse alarm probability; Calculating a detection probability and a pulse alarm probability while increasing the coherent sum interval when the attenuation value due to the Doppler effect is less than a predetermined value; If the attenuation value due to the Doppler effect is greater than or equal to a predetermined value, the detection probability and the pulse alarm probability are calculated while increasing the number of integration times after detection.

In order to achieve the above object, a parameter derivation method of a multipath searcher according to the present invention includes setting a target detection probability and a false alarm probability; Calculating a detection probability and a pulse alarm probability; Calculating a detection probability and a pulse alarm probability most similar to the target detection probability and the pulse alarm probability using the coherent sum interval and the number of post-integration integrals; And determining the coherent sum length and the number of post-integral integrals applied to the calculated detection probability and the pulse alarm probability as optimal parameters.

Preferably, the calculating step includes checking whether the calculated detection probability and the pulse alarm probability are similar to the target detection probability and the pulse alarm probability; Checking whether the attenuation value due to the Doppler effect is equal to or greater than a predetermined value when the calculated detection probability and the pulse alarm probability are not similar to the target detection probability and the pulse alarm probability; Calculating a detection probability and a pulse alarm probability while increasing the coherent sum interval when the attenuation value due to the Doppler effect is less than a predetermined value; If the attenuation value due to the Doppler effect is greater than or equal to a predetermined value, the detection probability and the pulse alarm probability are calculated while increasing the number of integration times after detection.

Hereinafter, the preferred embodiment of the present invention will be described.

In general, when the number of transmit antennas is increased in the multipath searcher, a phenomenon in which the quality of the reception level is degraded at the receiving end due to the deep fading phenomenon is reduced. Accordingly, the present invention proposes a method for deriving an optimal parameter value according to an increase in the number of transmit antennas in a multipath searcher of a W-CDMA / CDMA terminal in order to maximize such an effect. In particular, the present invention provides a parameter of an optimal coherent sum interval (length) (N) and the number of post-integral integrations (L) so that a multi-path searcher can efficiently receive a signal at a receiver generated according to an increase in the number of transmit antennas. To Suggest ways to make decisions.

To this end, the present invention determines the optimal coherent sum interval and post-integration frequency by varying the coherent sum interval and post-integration frequency and calculating the detection probability and the pulse alarm probability that are most similar to the target detection probability and the pulse alarm probability. .

5 is a flowchart illustrating a parameter determination method of the multipath searcher according to the present invention.

As shown in FIG. 5, first, the multipath searcher sets a target reference detection probability P _D0 and a target pulse alarm probability P _F0 according to a given number of transmit antennas (S10). For example, the target detection probability is set to 90% (P _D0 = 90%) and the target pulse alarm probability is set to 10% (P _F0 = 10%). At this time, the initial L value and the N value are initialized to one.

Thereafter, the multipath searcher calculates a detection probability P _D1 and a pulse alarm probability P _F1 using the following (1) and (2) (S11). At this time, the detection probability P _D0 is a function of P _D (n, L, N), and the pulse alarm probability P _F0 is defined as a function of P _F (n, L, N).

Where P ₀ (Z) is the likelihood function for the zero hypothesis and P ₁ (Z) is the estimation function for the hypothesis 1. V is the variance sum of the I-phase and the P-phase, q is an arbitrary boundary value, and n is the number of antennas.

Equations (1) and (2) are expressions representing detection probabilities and pulse alarm probabilities in a Rayleigh fading channel, and are general equations of a multipath searcher in a system to which transmission diversity is applied.

Fig. 6 is a graph showing a calculation example of the detection probability P _D1 and the pulse alarm probability P _F1 according to the above formulas (1) and (2), and shows the detection performance of the receiving end according to the number of transmitting antennas. Based on the calculation result shown in FIG. 6, the performance of the desired multipath searcher may be compared to some extent, and the detection result may be referred to in particular in performing a simulation.

Once the detection probability (P _D1 ) and the pulse alarm probability (P _F1 ) are calculated, the multi-path detector can find the detection probability (P _D1 ) equal to or higher than the target detection probability (P _D0 ), and the obtained pulse alarm probability (P _F1 ) is the target. Check whether the pulse alarm probability (P _F0 ) is less than (S12). That is, the multipath searcher checks whether the detection probability and the pulse alarm probability most similar to the target detection probability and the pulse alarm probability are calculated.

If the above conditions are met, the multi-path finder uses the parameters applied when obtaining the corresponding detection probability (P _D1 ) and the pulse alarm probability (P _F1 ), that is, the coherent sum interval (N) and the number of post-integration integrals (L). Is determined as the optimal parameter value.

On the other hand, if the condition of step S12 is not satisfied, the multipath searcher uses the performance reduction according to the correlation between the coherent sum interval N and the Doppler frequency error shown in FIG. N) is increased (S13, S14). That is, the multipath detector compares whether the attenuation due to the Doppler effect is greater than a predetermined value (X dB) while increasing the coherent sum interval (N). The number of times of the cumulative integral L is increased (S15).

Subsequently, the steps S11 to S15 are repeatedly performed while increasing the number of post-integration integrals L, and when the condition of the step S12 is satisfied, the multipath searcher detects the coherent sum interval N and the detection. The number of cumulative integrals L is determined as an optimal parameter value.

Among the above steps, steps S11 to S14 are particularly useful when the number of transmitting antennas is four or more, and when the number of transmitting antennas is two, applying the step S15 together leads to more accurate parameter values. can do.

As described above, according to the present invention, as the number of transmitting antennas increases, the optimal parameter value of the multipath searcher is easily derived, thereby improving the detection performance of the received signal.

In addition, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (7)

In the multipath searcher of a mobile communication terminal for receiving a signal transmitted from a plurality of transmit antennas to search for multipath, Setting a target detection probability and a false alarm probability; Calculating a detection probability and a pulse alarm probability; And comparing the calculated detection probability and the pulse alarm probability with the target detection probability and the pulse alarm probability, respectively, to determine an optimal parameter value according to the number of transmitting antennas. The method of claim 1, wherein the parameter value is A parameter derivation method of a multipath finder characterized in that it represents a coherent sum interval and the number of detections after integration. The method of claim 1, wherein the parameter value is The parameter derivation method of the multipath searcher, characterized in that it is determined when the calculated detection probability is greater than the target detection probability and the calculated pulse alarm probability is less than the target pulse alarm probability. The method of claim 1, wherein the determining of the parameter value Calculating a detection probability and a pulse alarm probability most similar to the target detection probability and the pulse alarm probability while increasing the coherent sum length and the number of post-integration integrals; And determining the number of coherent sum intervals and post-integration integrals applied to the calculated detection probability and pulse alarm probability as optimal parameters. The method of claim 4, wherein the calculating step Checking whether the calculated detection probability and the pulse alarm probability are similar to the target detection probability and the pulse alarm probability; Checking whether the attenuation value due to the Doppler effect is greater than or equal to a predetermined value when the calculated detection probability and the pulse alarm probability are not similar to the target detection probability and the pulse alarm probability; Calculating a detection probability and a pulse alarm probability while increasing the coherent sum interval when the attenuation value due to the Doppler effect is less than a predetermined value; And calculating the detection probability and the pulse alarm probability by increasing the number of integrals after detection if the attenuation value due to the Doppler effect is equal to or greater than a predetermined value. Setting a target detection probability and a false alarm probability; Calculating a detection probability and a pulse alarm probability; Calculating a detection probability and a pulse alarm probability most similar to the target detection probability and the pulse alarm probability using the coherent sum interval and the number of post-integral integrations; And determining the coherent sum interval and post-integral integration times applied to the calculated detection probability and the pulse alarm probability as optimal parameters. The method of claim 6, wherein the calculating step Checking whether the calculated detection probability and the pulse alarm probability are similar to the target detection probability and the pulse alarm probability; Checking whether the attenuation value due to the Doppler effect is equal to or greater than a predetermined value when the calculated detection probability and the pulse alarm probability are not similar to the target detection probability and the pulse alarm probability; Calculating a detection probability and a pulse alarm probability while increasing the coherent sum interval when the attenuation value due to the Doppler effect is less than a predetermined value; And calculating the detection probability and the pulse alarm probability by increasing the number of integrals after detection if the attenuation value due to the Doppler effect is equal to or greater than a predetermined value.

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