KR20010066274A - Parallel-type interference cancellation method of asynchronous transmission system - Google Patents

Abstract

PURPOSE: A parallel type interference removing method for an asynchronous transmission system is provided to improve an initial estimation performance of a receiving parallel type interference remover and improve a transmitting and receiving performance of an entire system by combining a backward link synchronous transmitting method with a parallel type interference removing method as a hybrid type. CONSTITUTION: Walsh demodulators(50,60) inversely spread each user data using an intrinsic orthogonal Walsh code and random PN code for sectioning a user signal. Walsh modulators(51,61) spread the demodulated user data as the orthogonal user data and the random PN code. The first Walsh demodulator(40) subtracts a reproducing signal from an entire receiving signal(r(t)) and recovers a corresponding user data in which an interference is finally removed.

Description

Parallel-type interference cancellation method of asynchronous transmission system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication system. In particular, parallel interference of an asynchronous transmission system using a reverse link synchronous transmission scheme and a parallel interference cancellation scheme in order to reduce multiple access interference in a DS-CDMA system using an asynchronous scheme is disclosed. It is about a removal method.

Currently, the asynchronous DS-CDMA system uses a parallel interference cancellation technique as a way to reduce the interference caused by multiple access between multiple user signals.

The general interference cancellation technique is to subtract the interference component of each user signal from each user signal before determining the code bit of each user. In particular, the parallel interference cancellation technique currently used in the asynchronous DS-CDMA system is used for each user. It is a technique to remove interference components of other user signals at the same time.

In other words, the parallel interference cancellation technique reconstructs the transmission signal by multiplying each determined code bit of each user by each modulation signal and channel parameter of the other user, and then synchronizing the entire interference component of the transmission signals for each user. Subtract from the received signal. The interference canceller used in such a parallel interference cancellation technique basically consists of two parts, a detection part and a subtraction part, and the final value determined by the detection part becomes the input signal of the subtraction part, and thus the interference component of each user's received signal. Subtract

The parallel interference cancellation scheme used in the asynchronous DS-CDMA system will be described in detail. When the transmitted signal of the k-th user transmitted is Equation 1, the k-th user signal of the s-th step of Equation 1 is The estimated value is given by the following equation.

In Equation 1 above Is the received signal of the k-th user, P _k is the power of this received signal, Is a pseudo noise code sequence multiplied by the received signal of the k-th user, hereinafter abbreviated as PN. Is the phase of the k-th user signal.

In equation 2 Is the determinant of the i-th code bit of the k-th user in the s-th interference component elimination step, and the interference component elimination is the entire reception in which the received signal estimated for each user is mixed with several other user signals as shown in Equation 2 above. Subtract it from the signal r (t). However, the received signal of the k-th user in the s th step through the interference component removal procedure is as shown in Equation 3 below.

In Equation 3 above, M means the total number of users.

This interference component removal procedure is then repeated in multiple steps.

However, there are some problems due to the use of the parallel interference cancellation technique described above in an asynchronous DS-CDMA system.

First, interference may occur in the process of subtracting the interference component due to channel estimation error that may occur in the detection portion of the interference canceller for parallel interference cancellation.

Secondly, because of the multi-step repetitive interference cancellation procedure, a time delay may occur in the system, and the hardware of the system becomes more complicated for the multi-step repetition removal procedure.

SUMMARY OF THE INVENTION The present invention has been made in view of the foregoing, and in particular, in order to reduce the multiple access interference in an asynchronous DS-CDMA system, the conventional parallel interference cancellation scheme and the reverse link synchronous transmission scheme are combined with the parallel interference cancellation scheme. The present invention provides a parallel interference cancellation method for an asynchronous transmission system used in a hybrid form.

In order to achieve the above object, a feature of the parallel interference cancellation method of the asynchronous transmission system according to the present invention includes the steps of transmitting a plurality of random user data such that the reception timing is matched by external timing control, and the matching reception timing. Determining each user code of the various user data received by the user; reproducing each received data of other users except for a specific user with the determined user code; and interfering with the received data of each reproduced user The components are subtracted simultaneously from the entire synchronized received signal mixed with several user signals.

In this case, when transmitting the plurality of random user data, the random user data is spread by orthogonal codes for distinguishing the random user data, and when receiving the spread user data, at the time of receiving the orthogonal code used for the spreading, the user data is spread. Receive to match.

Another feature of the interference cancellation method includes transmitting and transmitting a plurality of modulated user data to a random PN code and an orthogonal Walsh code for user identification, and transmitting user data of each transmitted path to a matched reception time point. Receiving and performing an initial estimation for each of the received user data, and subtracting each user data estimated for each user from the total received data including several other user data at the same time .

1 is a block diagram illustrating a parallel interference cancellation method of an asynchronous transmission system according to the present invention.

2 is a block diagram of a transmission and reception system for explaining a parallel interference cancellation method of an asynchronous transmission system according to the present invention.

3 is a timing diagram of a spreading code of an asynchronous transmission system to which a conventional reverse link synchronous transmission scheme is not applied.

4 is a timing diagram of a spreading code of an asynchronous transmission system to which a reverse link synchronous transmission scheme of the present invention is applied.

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

10 to 12 modulator (MOD) 20 to 22 Walsh modulator (Washish MOD-1 to Walsh MOD-M)

30: delay unit 40: first Walsh demodulation unit (Washish DEM-1)

50: second Walsh demodulator (Walsh DEM-2)

60: M Walsh demodulator (Wash DEM-M)

Hereinafter, a preferred embodiment of a parallel interference cancellation method of an asynchronous transmission system according to the present invention will be described with reference to the accompanying drawings.

In the present invention, the reverse link synchronous transmission scheme without the interference cancellation scheme is used together with the parallel interference cancellation scheme.

In general, due to the distribution of users randomly (or mobile stations) in the reverse link, the reception time of each user signal received by the base station is asynchronous.

However, if the reverse link synchronous transmission scheme is used, the timing of the received signal may be transmitted by external timing control. This is because an orthogonal code is used, and since each user signal is spread and transmitted by the orthogonal code, orthogonality is maintained between each user signal, thereby eliminating interference by multiple access.

As described above, in a system considering the reverse link synchronous transmission scheme, an orthogonal code provided to maintain orthogonality between user signals and a PN code for randomizing each user signal are used for spreading and scrambling.

The following describes in more detail the reverse link synchronous transmission scheme without interference cancellation scheme used in an asynchronous DS-CDMA system.

In the reverse link synchronous transmission scheme, once the main path timing is synchronized by external timing control, multipath components are received asynchronously.

Thus, in a system employing a RAKE receiver, a synchronous branch in the main path signal components and a branch in which multipath signal components are affected. Receive and asynchronous receive coexist.

However, in a system using the current reverse link synchronous transmission scheme, multipath interference or multiuser interference may not be eliminated by external timing control.

Accordingly, the present invention uses a combination of a reverse link synchronous transmission technique that transmits the timing of a received signal by the external timing control described above and a parallel interference cancellation technique described above in a hybrid form.

In other words, the timing is matched by external timing control to determine each user code bit of the transmitted multiple user signals, and the determined user code bits are multiplied by respective modulation signals and channel parameters of the other users except the user. Reconstruct the reproduction signal which is almost identical to the transmission signal, and then subtract the interference component of the reproduction signals for each user from the total synchronized signals.

1 is a block diagram illustrating a parallel interference cancellation method of an asynchronous transmission system according to the present invention, and illustrates a parallel interference cancellation procedure employing a reverse link synchronous transmission scheme.

Referring to FIG. 1, first, a user signal s _i (t) (where i = 1… M) transmitted from each mobile station is a received signal arriving at a base station by a timing control algorithm 1 used in a reverse link synchronous transmission scheme. Synchronize at the time of reception.

In other words, the user signal r (t) received at the base station is received to coincide with the reception time of a quadrature walsh code for distinguishing each user. Therefore, orthogonality is maintained between each user signal, thereby eliminating interference between user signals due to multiple accesses.

However, this only applies to the main path controlled by external timing, and inter-signal interference remains in a random multipath user signal that cannot be controlled by external timing.

Therefore, the parallel interference canceller 2 using the parallel interference cancellation technique performs first-order estimation on the received signals of each path, and the received received signals mixed with several different user signals are estimated for each user. Subtracts from r (t) to remove the interference component.

The final decision block 3 then obtains a signal s _i (t) (where i = 1 ... M) that was finally determined with each user signal from which the interference component has been removed.

2 is a block diagram of a transmission and reception system for explaining a parallel interference cancellation method of an asynchronous transmission system according to the present invention, and illustrates a parallel interference cancellation procedure employing a reverse link synchronous transmission scheme.

Referring to FIG. 2, the system shown is largely divided into a transmitting side and a receiving side.

On the transmitting side, various modulators (MODs) 10 to 12 modulating each user data, and various orthogonal Walsh codes and a random PN code for each user to distinguish each user, spread each user data. Walsh modulators (Washish MOD-1 to Walsh MOD-M) 20 to 22 are provided.

Therefore, the transmitting side spreads the modulated user data into a random PN code and an orthogonal Walsh code for user identification.

After that, each signal transmitted in the radio section undergoes multipath fading, which causes multipath interference or multi-user interference at the receiver.

Each user signal s _i (t) (where i = 1… M) transmitted by the reverse link synchronous transmission scheme arrives at the receiving side by the number of users M, and the reverse link synchronous transmission between the transmitting side and the receiving side is performed. The signal r (t) is received by which the reception time is synchronized (the reception time of the random PN code and the orthogonal Walsh code for user identification are synchronized).

Separately, FIG. 3 illustrates a timing diagram of a spreading code of an asynchronous transmission system to which a reverse link synchronous transmission technique is not applied. FIG. 4 illustrates a spreading code of an asynchronous transmission system to which a reverse link synchronous transmission technique is applied as in the present invention. The timing diagrams are shown, which show only the main paths.

Since the receiving side receives a signal r (t) whose reception time is synchronized by reverse link synchronous transmission, the orthogonality between user data is secured, and the interference between signals is reduced.

On the other hand, the received signal r (t) is synchronized with the reception time by reverse link synchronous transmission and is input to the detection portion of the parallel interference canceller on the receiving side.

The parallel interference canceller on the receiving side, which performs the above operation, basically consists of two parts, the detection part and the subtraction part, and the detection part is made by excluding the specific user data from the received signal r (t) with synchronized reception points. An estimated value of the other user data is determined, and a subtracted portion is provided with a reproduced signal in which the estimated signal corresponding to the finally determined estimated value is spread back to a unique orthogonal Walsh code for each user and one random PN code. Therefore, the subtraction section subtracts the reproduction signal provided by the detection section from the entire received signal r (t).

The detection portion of the parallel interference canceller illustrated in FIG. 2 includes a plurality of Walsh demodulators (Wash DEM-2 to despread each user data with a unique orthogonal Walsh code and a random PN code for each user to distinguish a user signal). Walsh DEM-M) (50,60) and various Walsh modulators (Washish MOD-2 to Walsh MOD-M) 51,61 for spreading each demodulated user data back to orthogonal Walsh codes and random PN codes. Equipped.

In addition, the subtraction section subtracts the reproduction signal provided by the detection section from the entire reception signal r (t), and restores the corresponding user data from which interference has been finally removed (Wash DEM-1) 40. It is provided.

In particular, in the present invention, a more accurately synchronized signal is reproduced and subtracted.

In addition, in the present invention, the interference component may be repeatedly removed according to the required system performance level.

As described above, by using the parallel interference cancellation method of the asynchronous transmission system according to the present invention using the reverse link synchronous transmission scheme combined with the parallel interference cancellation scheme in a hybrid form, The estimated performance is improved to improve the transmit and receive performance of the overall system. In particular, it prevents error spreading due to the multi-step repetitive interference elimination procedure used in the past, and reduces time delay and hardware complexity.

In addition, when the parallel interference cancellation method of the present invention is applied to a synchronous transmission system, since the multipath interference or the multi-user interference generated in the synchronous transmission system can be eliminated by the parallel interference canceller, the transmission / reception performance of the overall system is improved. do.

Claims (3)

Transmitting a plurality of random user data such that a reception time coincides by external timing control; Determining each user code of the various user data received at the matched reception point; Reproducing each received data of other users except for a specific user with each of the determined user codes; And simultaneously subtracting the interference component of the received data of each reproduced user from all the synchronized received signals mixed with several user signals. 2. The method of claim 1, wherein when transmitting the plurality of random user data, the random user data is spread by an orthogonal code for distinguishing each of the random user data. When receiving the spread user data, the orthogonal code used for the spreading is transmitted. Parallel interference cancellation method for an asynchronous transmission system, characterized in that the reception so as to match the reception time of. Transmitting and spreading the modulated user data into a random PN code and an orthogonal Walsh code for user identification; Receiving user data of each transmitted path at a matched reception time point; Performing an initial estimation on each of the received user data; And subtracting each user data estimated for each user from all received data including several other user data at the same time.