KR100379477B1 - Apparatus and Method for acquisition system using burst pilot signal - Google Patents

Abstract

The present invention relates to a mobile communication system. In particular, an initial synchronization using a burst pilot signal that minimizes interference from other time division regions and increases an initial synchronization success probability by integrating only a section where a mobile station is likely to have a burst pilot signal in a forward channel. The present invention relates to a system and a synchronization method using the same. An integrator that integrates for a first time or a second time with respect to the received signal, and compares a first integral value output for the first time in the integrator with a set first threshold value or a second integral value output for the second time. A comparator comparing with the second threshold and a first compared at the comparator When the integral value is greater than or equal to the first threshold value, the determiner transmits an integral section update signal to the integrator and transmits an operation signal to the pulse position estimator, and observes a position where the output of the envelope detector changes according to the operation signal of the determiner. And a pulse position estimator for estimating the position of the burst pilot signal, transmitting an integral section update signal to the integrator, and transmitting a threshold update signal to the comparator.

Description

Initial synchronization system using burst pilot signal and synchronization method using same {Apparatus and Method for acquisition system using burst pilot signal}

The present invention relates to a mobile communication system, and in particular, initial synchronization using a burst pilot signal that minimizes interference from other time division regions and increases an initial synchronization success probability by integrating only a section in which a mobile station is likely to have a burst pilot signal in a forward channel. A system and method using the same.

In general, in a CDMA system, synchronization between a received pseudo-noise code and a local pseudo noise code is required to recover a transmitted signal.

To this end, in the conventional Interim Standard-95 (IS-95) -based system, a base station transmits a pilot signal through a pilot channel, and a mobile station synchronizes between a received pseudo noise code and a local pseudo noise code using the pilot signal. .

In the synchronization process for the above operation, two steps are required.

The first step is an initial synchronization process that ensures that the error between the phase of the local pseudo noise code and the phase of the pseudo noise code used in the received signal is within one chip.

The next step is the code tracking process, which keeps the correct synchronization and keeps it through the code tracking loop.

Here, the first initial synchronization process is again divided into two stages according to the integral section of the correlation detector. The first dwell integrates during this interval when the first time is a relatively short time period compared to each phase. Is a process of screening only those phases that are likely to be synchronized, and a second dwell integrates during this interval when the second time is a relatively long time period for the phase that passed the first step. This completes the initial motivation.

1 is a view showing the configuration of an initial synchronization system according to the prior art.

Referring to the system of FIG. 1, a local pseudo noise code generator 10 generating pseudo noise, a signal received at a mobile station and a pseudo noise signal generated at a local PN code generator 10 are multiplied. A correlator 11, a band pass filter 12 for removing unnecessary components from the signal output from the correlator 11, and an envelope detected from a signal passing through the base band filter 12 Square threshold based on the square-law Envelope Detector (13), Integrate Dump (14) for integrating the signal output from the envelope detector (13), and the integral value output from the integrator (14) A threshold comparison device 15 for comparing with a value, and a decision device 16 for transmitting an update signal with respect to a result output from the threshold comparator 15.

An operation description according to the system configuration of FIG. 1 is as follows.

First, the signal received at the mobile station is multiplied by the correlator 11 together with the local pseudo noise code generated by the local pseudo noise code generator 10 and the signal output from the correlator 11 passes through the baseband pass filter 12. While the unnecessary components are removed, this signal passes through the envelope detector 13, at which time the detected envelope signal is input to the integrator 14.

The integrator 14 performs the integration for the set first time and transmits the integrated value to the threshold comparator 15.

Here, the first time refers to a time of a relatively short interval.

The threshold comparator 15, in which the integrated value is input, inputs the result of the comparison to the determiner 16 in comparison with the set first reference threshold value.

The determiner 16 determines the integral section of the integrator 14 and the threshold comparator 15 when the integral value is smaller than the first reference threshold value according to the result of the threshold comparator 15. Each of the first reference thresholds is maintained and a code phase update signal is transmitted to the local pseudo noise code generator 10.

The local pseudo noise code generator 10 receiving the code phase update signal delays or advances the phase of the generated pseudo noise code by one step.

However, the determiner 16 transmits an integration length update signal to the integrator 14 when the integral value is greater than or equal to the first reference threshold value according to the result of the threshold comparator 15. The threshold comparator 15 transmits a threshold value update signal.

The integrator 14 receiving the integration section update signal changes the integration time from the first time to the second time.

Here, the second time has a value that is relatively larger than the first time and is a time of a section that is relatively longer than the phase.

In addition, the threshold comparator 15 to which the threshold update signal is input changes the reference value from the first reference threshold value to the second reference threshold value, where the second reference threshold value is relatively larger than the first reference threshold value. .

If the output of the integrator 14 whose integral time is changed to the second time which is the time of the section longer than the phase is greater than or equal to the second reference threshold value, the determiner 16 is initially synchronized. The initial synchronous system enters the code tracking process.

On the other hand, when the output value of the integrator 14 whose integral time is changed to the second time is smaller than the second threshold value, the determiner 16 considers that initial synchronization is not performed and integrates the integrator 14. The interval update signal is transmitted, and the threshold comparator 15 transmits a threshold update signal.

The local pseudo noise code generator 10 then transmits a code phase update signal.

The integrator 14, in which the integral period update signal is input again, returns the integral time from the second time to the first time, and the threshold comparator 15 in which the threshold update signal is inputted removes the reference value from the second reference threshold. 1 Return to the reference threshold.

The local pseudo noise code generator 10 to which the code phase update signal is input may delay or advance the phase of the generated pseudo noise code by one step.

The above listed process is repeated until initial synchronization is achieved.

As described above, in the conventional IS-95 based system, continuous data having a pilot signal value of 1 is applied with a unique pseudo noise code assigned to each base station to continuously transmit time.

However, in the case of 1x High Data Rate, Qualcomm's wireless data technology, which provides data rates of up to 2.4 Mbps over 1.25 MHz CDMA standard voice channels, the entire system has been moved from one point to another for a given amount of time. In order to maximize data throughput, a burst pilot signal is periodically transmitted as shown in FIG. 2.

In other words, the initial synchronization can be achieved with the burst pilot signal in the same manner as in the conventional method.

However, in such a high-speed data transmission system, the integration for the section without the pilot signal has a problem that the initial synchronization probability is lowered due to the interference signal due to the correlation between the signal existing in the section and the local pseudo noise code.

Accordingly, an object of the present invention has been made in view of the above-mentioned problems of the prior art, and an initial synchronization system using a burst pilot signal that increases an initial synchronization probability by excluding an integration for a section in which a pilot signal does not exist and the same. It is to provide a method used.

According to an aspect of the present invention for achieving the above object, a correlator multiplying a signal received at a mobile station with a pseudo noise signal generated by the local pseudo noise code generator, and detecting an envelope in a signal passing through the correlator. The envelope detector, an integrator that integrates the signal detected by the envelope detector for a first time or a second time, and the first integral value output for the first time in the integrator are compared with or set to a first reference threshold value. A threshold comparator for comparing a second integral value output for two hours with a set second reference threshold value, and the integrator if the first integral value compared by the threshold comparator is greater than or equal to the first reference threshold value; A judging unit for transmitting an integral section update signal to a signal and transmitting an operation signal to a pulse position estimator, Including the pulse position estimator for observing the position where the output of the envelope detector changes, estimating the position of the burst pilot signal, transmitting an integral section update signal to the integrator, and transmitting a threshold update signal to a threshold comparator. do.

Advantageously, said threshold comparator maintains an integral period of said integrator and maintains said first reference threshold of said threshold comparator if said first integral value is less than a first reference threshold and a local pseudo noise code generator. It is characterized in that for adjusting the phase of the pseudo noise code generated by transmitting a code phase update signal.

According to another aspect of the present invention for achieving the above object, correlating a pilot signal received at a mobile station and a local pseudo noise signal, integrating the correlation signal for a first time, and the integral value Determining whether or not the received pilot signal is greater than or equal to the first reference threshold value compared to the first reference threshold value, and if the pilot signal is present, the integral period is longer than the first time Adjusting to time and changing the reference threshold to a second reference threshold that is greater than a first reference threshold; and completing initial synchronization if the integral value for the second time is greater than or equal to the second reference threshold. Characterized in that it comprises a step.

Preferably, the step of inputting the integral value as a threshold comparator and comparing the result with a first reference threshold value and transmitting the comparison result to the determiner, when the integral value is smaller than the first reference threshold value according to the comparison result, The phase of the pseudo noise code generated by maintaining an integral section of the signal, maintaining the first reference threshold value of the threshold comparator, and transmitting a code phase update signal to a local pseudo noise code generator.

The second time may be an integral time relatively longer than the first time, and the second reference threshold may have a threshold that is relatively larger than the first reference threshold.

After the threshold comparator changes the reference threshold to the second reference threshold, if the integral value of the integrator is smaller than the second reference threshold, the determiner sends an integral section update signal to the integrator and integrates the integrated value. Change a time from a second time to a first time and the determiner sends a threshold update signal to the threshold comparator and changes a second reference threshold to a first reference threshold and code phases to a local pseudo noise code generator. And performing initial synchronization repeatedly by adjusting a phase of a pseudo noise code generated by transmitting an update signal.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

1 is a diagram showing the configuration of an initial synchronization system according to the prior art;

2 illustrates a burst pilot signal in which periodic transmission is performed.

3 is a diagram illustrating a configuration of an initial synchronization system according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: local pseudo noise code generator 110: correlator

120: baseband pass filter 130: envelope detector

140: Integrator 150: Threshold Comparator

160: determiner 170: pulse position estimator

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a diagram illustrating a configuration of an initial synchronization system according to the present invention.

Referring to the system of FIG. 3, a local pseudo noise code generator 100 for generating pseudo noise, a correlator 110 for multiplying a signal transmitted from a mobile station with a pseudo noise signal generated at the local pseudo noise code generator 100, A baseband filter 120 for removing unnecessary components of the signal output from the correlator 110, an envelope detector 130 for detecting an envelope in a signal passing through the baseband filter 120, and the envelope detector ( An integrator 140 that integrates for a first time or a second time with respect to the signal detected at 130, and compares the first integral value output during the first time from the integrator 140 with a set first reference threshold value; A threshold comparator 150 for comparing a second integral value output for 2 hours with a set second reference threshold value, and the first integral value compared by the threshold comparator 150 is greater than the first reference threshold value. Or like When the integral section update signal is transmitted to the integrator 140 and an operation signal is transmitted to the pulse position estimator, the output of the envelope detector 130 is output according to the operation signal of the determiner 160. The pulse position tracker 170 for estimating the position of the burst pilot signal by observing the changing position, transmitting an integral section update signal to the integrator 140, and transmitting a threshold update signal to the threshold comparator 150. It consists of.

An operation description according to the system configuration of FIG. 3 is as follows.

First, the received signal at the mobile station is multiplied in the correlator 110 together with the local pseudo noise code generated by the local pseudo noise code generator 100 and the signal output from the correlator 110 passes through the baseband pass filter 120. While unnecessary components are removed and the signal passes through the envelope detector 130, the detected envelope is input to the integrator 140.

The integrator 140 performs integration for a preset first time and transmits the integrated value to the threshold comparator 150.

The threshold comparator 150 in which the transmission value is input is input to the determiner 160 by comparing the result of the comparison with the set first reference threshold value.

The determiner 160 integrates and integrates the first reference threshold between the integrator 140 and the threshold comparator 150 when the result of the threshold comparator 150 is smaller than the first reference threshold. Retain each value and send a code phase update signal to the local pseudo noise code generator 100.

The local pseudo noise code generator 100 receiving the code phase update signal delays or advances the phase of the generated pseudo noise code by one step.

However, when the integral value is greater than or equal to the first reference threshold value according to the result of the threshold comparator 150 in the determiner 160, the determiner 160 sends an integral section update signal to the integrator 140. Transmits and transmits an operation signal to the pulse position tracker 170.

The integrator 140 that receives the integral section update signal from the determiner 160 changes the total integration time from the first time to the second time.

Here, the second time has a relatively large value compared to the first time.

The pulse position estimator 170 estimates the position at which the burst pilot signal exists by observing a position at which the output of the envelope detector 130 changes, and integrating the integral section to the integrator 140 when the determiner 160 sends an operation signal. The update signal is transmitted and the threshold update signal is transmitted to the threshold comparator 150. In this case, when the burst pilot signal does not exist, the pulse position estimator 170 may not operate, and the integration for the section without the burst pilot signal may be excluded.

The threshold comparator 150 receiving the threshold update signal changes the reference value from the first reference threshold value to the second_1 reference threshold value so as to be suitable for the integration section.

If the output of the integrator 140 whose total integration time is changed to the second time is greater than or equal to the 2_1 reference threshold, the determiner 160 considers that initial synchronization is made and the system enters the code tracking process.

On the other hand, when the output of the integrator 140 whose total integration time is changed to the second time is smaller than the 2_1 reference threshold value, which is the reference value, it is regarded that the initial synchronization is not performed and the determiner 160 determines that the integrator ( An integral period update signal is transmitted to the controller 140, a threshold update signal is transmitted to the threshold comparator 150, and a code phase update signal is transmitted to the local pseudo noise code generator 100.

The integrator 140 receiving the integral section update signal from the determiner 160 returns the entire integration time from the second time to the first time, and the threshold comparator 150 receiving the threshold update signal receives the reference value. The second reference threshold is returned to the first reference threshold.

In addition, the pseudo noise code generator 100 receiving the code phase update signal from the determiner 160 delays or advances the phase of the generated pseudo noise code by one step, and the enumeration process is repeated until initial synchronization is achieved. .

As described above, the initial synchronization system using the burst pilot signal and the method using the same according to the present invention estimate the position of the burst pilot signal during the first initial synchronization process and integrate the interval for the burst pilot signal without the second synchronization process. By eliminating this, the probability of achieving the initial synchronization is increased, thereby improving the performance of the initial synchronization system.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (8)

A correlator for multiplying a signal received at a mobile station with a pseudo noise signal generated at the local pseudo noise code generator; An envelope detector for detecting an envelope in a signal passing through the correlator; An integrator that integrates the signal detected by the envelope detector for a first time or a second time; A threshold comparator for comparing a first integral value output for a first time in the integrator with a set first reference threshold or a second integral value output for a second time with a set second reference threshold; A determiner for transmitting an integral period update signal to the integrator and transmitting an operation signal to a pulse position estimator when the first integral value compared by the threshold comparator is greater than or equal to the first reference threshold value; Observe the position where the output of the envelope detector changes according to the operation signal of the determiner, estimate the position where the burst pilot signal exists, transmit an integral section update signal to the integrator, and transmit a threshold update signal to a threshold comparator. An initial synchronization system using a burst pilot signal, characterized in that it comprises a pulse position estimator. The method of claim 1, wherein the threshold comparator, If the first integral value is less than a first reference threshold, the integral interval of the integrator is maintained, the first reference threshold of the threshold comparator is maintained, and a code phase update signal is transmitted to a local pseudo noise code generator. Initial synchronization system using a burst pilot signal, characterized in that for adjusting the phase of the pseudo noise code. Correlating a pilot signal received at the mobile station with a local pseudo noise signal; Integrating for the correlation signal for a first time; Comparing the integrated value with a first reference threshold and determining whether the received pilot signal is greater than or equal to the first reference threshold; Adjusting the integral section to a second time longer than the first time when the pilot signal is present and changing the reference threshold to a second reference threshold greater than a first reference threshold; And initializing synchronization when the integral value during the second time period is greater than or equal to the second reference threshold value. The method of claim 3, wherein the step of inputting the integral value to a threshold comparator and comparing the first reference threshold value to the comparison result to the determiner comprises: an integral value smaller than the first reference threshold value according to the comparison result And maintains the integral period of the integrator, maintains the first reference threshold of the threshold comparator, and adjusts the phase of the pseudo noise code generated by transmitting a code phase update signal to a local pseudo noise code generator. Initial synchronization method using burst pilot signal. 4. The burst pilot signal of claim 3, wherein the second time is an integral time relatively longer than the first time, and the second reference threshold has a relatively large threshold compared to the first reference threshold. Initial synchronization method used. 4. The method of claim 3, wherein after the threshold comparator changes the reference threshold to the second reference threshold, if the integral value of the integrator is less than the second reference threshold, the determiner sends an integral section update signal to the integrator. Transmit, change the integral time from a second time to a first time, and in the determiner, transmit a threshold update signal to the threshold comparator, change a second reference threshold to a first reference threshold, and generate a local pseudo noise code generator And performing initial synchronization repeatedly by adjusting a phase of a pseudo noise code generated by transmitting a code phase update signal to the. An envelope detector for detecting an envelope in a signal correlated with a signal received at the mobile station and a local pseudo noise code generator generated signal; An integrator that integrates the detected signal for a first time or a second time; A threshold comparator for comparing the integral value in the integrator with a set first and second reference threshold values; In the threshold comparator, if the first integral value compared during the first time is greater than or equal to the set first reference threshold value, a control signal is generated to integrate the second integrator with the integrator for the second time period; A determiner for transmitting; Observe the position of the output change of the envelope detector according to the operation signal of the determiner, estimate the position where the burst pilot signal exists, and transmit the integral section update signal according to the estimated position to the integrator. And a pulse position estimator for transmitting an update signal to a second reference threshold. In a mobile communication receiver that receives a pilot signal periodically received, when synchronization is detected by detecting a correlation value between the received pilot signal and a local pseudo noise code for a first integral period, Determining whether the pilot signal exists for a second integration section longer than the first integration section; And detecting a correlation value between the pilot signal and the local pseudo noise code for the second integration section only when the pilot signal exists, and determining whether to synchronize with the pilot signal. .