KR100363654B1 - Hybrid Group-wise Interference Cancelling Device and Method - Google Patents

Abstract

The present invention relates to an apparatus and method for eliminating complex multi-user interference, comprising: a matched filter for detecting signal components of respective users from a received signal; A plurality of parallel interference cancellation blocks configured to detect a user signal by applying a parallel interference cancellation technique to an input user signal; User allocation means for determining allocation to each of said plurality of parallel interference cancellation blocks for signals of respective users detected by said matching filter; And means for determining digital signal levels of users detected in the connected parallel interference cancellation block, each connected to the plurality of parallel interference cancellation blocks, wherein the plurality of parallel interference cancellation blocks are connected in series and sequentially assigned. The parallel interference cancellation block which performs interference cancellation and user detection only on the received user signal. First, the parallel interference cancellation block which performs interference cancellation on the received signal after subtracting the regenerated signal through interference cancellation from the received signal is performed. The method according to the present invention is a method of eliminating user interference by connecting a plurality of parallel interference cancellation blocks for detecting a user signal in series by applying a parallel interference cancellation technique to an input user signal. To detect the signal component of each user from the received signal System (a); Determining (b) assigning signals of the respective users detected in the step (a) to the plurality of parallel interference cancellation blocks, respectively; In the sequence of the parallel interference cancellation blocks in series, interference cancellation and user detection are performed only on the assigned user signal, and the parallel interference cancellation block, which first performs the interference cancellation process, is regenerated through interference cancellation in the received signal. And (c) inputting a signal obtained by subtracting the signal into a parallel interference cancellation block for performing interference cancellation later.

According to the apparatus and method according to the present invention, the received signal is divided into several blocks without completely removing the signals of all users from the received signals, and only the signals of the assigned users are removed within the first block and the first within the second block. Since the parallel interference cancellation technique is applied to the signal from which the interference cancellation of the block has been performed, there is an advantage that the operation process and processing time can be reduced as compared to the parallel interference cancellation scheme consisting of two stages.

Description

Hybrid Multi-User Interference Cancellation Device and Method

The present invention relates to an apparatus and method for complex multi-user interference cancellation. More particularly, the present invention relates to an apparatus for and method of canceling interference. The present invention relates to a multi-user interference cancellation apparatus applying the technique.

BACKGROUND Wireless mobile communication systems have recently increased demands for multimedia services such as data and images. In addition, while the number of users for the wireless communication network is increasing, the frequency resource for this is extremely limited. Therefore, in the current mobile communication system, a code division multiple access ("CDMA") method for efficiently operating frequency resources is widely used.

In the CDMA method, multiple users share frequency and time to transmit and receive signals, spread the bandwidth to transmit the signal, and the receiver uses the spread to produce the original signal in the process of despreading the received signal. Since the code must be known correctly, the confidentiality of the communication is ensured, and the external disturbance signals are spread in the opposite direction in the despreading process so that they do not disturb the communication. However, in the CDMA method, since the signal is spread and transmitted in a much wider bandwidth than the signal bandwidth, it is difficult to detect the presence or absence of the signal due to the low power density of the signal. Also, unlike other multiple access methods, the CDMA is divided only by code. There is a problem in that interference between users sharing a channel is large.

Conventional interference cancellation techniques for solving such problems include parallel interference cancellation and serial interference cancellation.

1 shows a configuration of a conventional parallel interference cancellation block.

In FIG. 1, signals of r ₁ to r _n refer to signals of each of n users who share a channel regenerated in all interference cancellation stages. If the illustrated interference cancellation block is the first stage, the signals r ₁ to r _n will be signals of respective users first detected by the base station.

As shown in FIG. 1, each of the signals re-generated in the previous interference cancellation stage is input to N interference cancellers provided by the number of users and processed simultaneously.

Each interference canceller includes a corresponding user signal regenerated at the front end. And a signal obtained by subtracting all of the signals regenerated in the previous stage from r (t-ST) which is a signal received from the base station. Ideally, the signal received from the base station is subtracted from the signal regenerated in all stages, but becomes zero, but is not actually zero due to noise and error in the estimated information sequence.

When the two signals as described above are input to each interference canceller, a specific user's signal from which interference of other users is removed is output from each interference canceller.

FIG. 2 illustrates a detailed configuration of an interference canceller provided in the parallel interference cancellation block illustrated in FIG. 1 by the number of users. Referring to FIG. 2, a process of removing interference from other users other than the corresponding user in each interference canceller is as follows.

First of all, the signal from a specific user Is added to the base station received all user signals minus all user signals regenerated all stages.

The added signal is multiplied by user information including spreading code and channel coefficients to despread the corresponding user signal, the despread signal passes through the match filter 20, and at decision block 21 the level (1) of the digital signal Or -1). Hard decision is generally used as a determination method. Once the level of the signal is determined, the signal is spread again by multiplying the user information signal again. This interference cancellation can be done in several stages, and as the interference cancellation stage increases, the signal reliability becomes higher.

As described above, since the conventional parallel interference cancellation scheme removes interference for all users, as the number of users increases, the complexity and calculation process of the system increases. In addition, since the method of extracting the signals of each user at the same time, when using the user signal of low reliability when removing interference, there is a high possibility that an error due to the wrong interference cancellation process occurs.

3 shows a configuration of a conventional serial interference cancellation block.

As shown in FIG. 3, the serial indirect cancellation scheme removes interference sequentially for several users. In FIG. 3, the first interference canceller is a full user signal. Is input, and extract only one user for this signal Is output. That is, the first interference canceller regenerates only one user signal of n users sharing one channel. This process is sequentially performed until the interference for n users is removed in the second to Nth interference removers, and interference cancellation may be performed through various stages as shown in FIG. 3. Another output from the first interference canceller Is a value obtained by subtracting a user signal detected by the first interference canceller from all user signals. This value is input to the second interference canceller, and the second interference canceller extracts a specific user signal from a signal obtained by subtracting the user signal detected by the first interference canceller from the entire user signal.

FIG. 4 illustrates a detailed configuration of an interference canceller provided in the serial interference cancellation block illustrated in FIG. 3 by the number of users. Referring to Figure 4 describes the interference cancellation process of the serial interference canceller as follows.

The signal input to the interference canceller is despreaded by multiplying with a corresponding user information signal including a spreading code and a channel coefficient. The despread signal passes through the matched filter 40, and the decision block 41 determines the level (1 or -1) of the digital signal. When the level of the signal is determined, the corresponding user information signal is multiplied again, so that the signal is spread and is a regeneration signal for the k-th user. Is output. On the other hand, the input signal Is delayed by the delay block 42 by the interference cancellation time in the interference canceller, and the delayed signal And detected signal Is the signal minus Is output as another output signal. The output signal Is then input to the interference canceller.

As such, since the serial interference cancellation technique removes only one user signal, each interference canceller reduces MAI (Multiple Access Interference) to the remaining users from the next step.

In the serial interference cancellation technique, it is effective to first detect and remove the signal of the user with the highest signal strength. Therefore, the first interference canceller multiplies the user information with the highest signal power among the users sharing the channel and has the highest signal power. Is detected first, and the second interference canceller next detects a user having a large signal power.

Since the serial interference cancellation technique extracts each user signal sequentially, it is more reliable than the parallel interference cancellation technique, but it requires a lot of delay time to handle the interference for all users. In addition, when the initial estimate is unreliable, even if the estimation of the amplitude and the phase is perfect, there is a problem that greatly affects the determination of the information bit.

In the present invention, in order to solve the problems of the prior art as described above, the parallel interference cancellation block is divided into several sets, the interference is removed only for the assigned user, and the serial interference cancellation scheme is divided between the divided parallel interference cancellation blocks. In this paper, we propose a group-wise parallel interference cancellation scheme that is easy to implement.

Another object of the present invention is to maximize the interference cancellation efficiency by effectively allocating users to the divided parallel interference cancellation block.

1 illustrates a configuration of a conventional parallel interference cancellation block,

FIG. 2 illustrates a detailed configuration of an interference canceller provided in the parallel interference cancellation block illustrated in FIG. 1 by the number of users.

3 illustrates a configuration of a conventional serial interference cancellation block,

4 illustrates a detailed configuration of an interference canceller provided in the serial interference cancellation block illustrated in FIG. 3 by the number of users.

5 is a block diagram of a multi-user interference cancellation apparatus according to a preferred embodiment of the present invention.

FIG. 6 is a flow chart showing the operation of the multi-user interference cancellation apparatus shown in FIG. 5; FIG.

In order to achieve the above object, the multi-user interference cancellation apparatus according to the present invention includes a matched filter for detecting the signal components of each user from the received signal; A plurality of parallel interference cancellation blocks configured to detect a user signal by applying a parallel interference cancellation technique to an input user signal; User allocation means for determining allocation to each of said plurality of parallel interference cancellation blocks for signals of respective users detected by said matching filter; And means for determining digital signal levels of users detected in the connected parallel interference cancellation block, each connected to the plurality of parallel interference cancellation blocks, wherein the plurality of parallel interference cancellation blocks are connected in series and sequentially assigned. The parallel interference cancellation block which performs interference cancellation and user detection only on the received user signal. First, the parallel interference cancellation block which performs interference cancellation on the received signal after subtracting the regenerated signal through interference cancellation from the received signal is performed. Characterized in by input.

The user assigning means is characterized in that the user assigning means assigns users whose signal strength is greater than a set threshold to a block for first performing interference elimination among the plurality of interference eliminating blocks.

The user allocating means is characterized in that the user allocating means allocates users requiring QoS lower than a predetermined threshold value to a block for first performing interference cancellation among the plurality of interference cancellation blocks.

Meanwhile, the method of the present invention provides a method of eliminating user interference by connecting a plurality of parallel interference cancellation blocks for detecting a user signal in series by applying a parallel interference cancellation technique to an input user signal. Detecting a signal component of each user (a); Determining (b) assigning signals of the respective users detected in the step (a) to the plurality of parallel interference cancellation blocks, respectively; In the sequence of the parallel interference cancellation blocks in series, interference cancellation and user detection are performed only on the assigned user signal, and the parallel interference cancellation block, which first performs the interference cancellation process, is regenerated through interference cancellation in the received signal. And (c) inputting a signal after subtracting the signal into a parallel interference cancellation block for performing interference cancellation later.

Hereinafter, exemplary embodiments of a multi-user interference cancellation apparatus and method according to the present invention will be described in detail with reference to the accompanying drawings.

5 illustrates a configuration of a multi-user interference cancellation apparatus according to a preferred embodiment of the present invention.

As shown in FIG. 5, the multi-user interference cancellation apparatus according to the preferred embodiment of the present invention includes a user matching / assignment block 50, a delay block 51, and a first parallel interference cancellation block connected in series. 52 and a second parallel interference cancellation block 53, a first decision block 54 and a second decision block 55.

In FIG. 5, r (t) is a received signal received from the base station, and is a signal in which signals of several users sharing a channel are mixed.

The user matching / assignment block 50 detects a signal component of each user in the received signal r (t), and converts the detected user signal into any one of a first parallel interference cancellation block and a second parallel interference cancellation block. Perform the function of determining whether to allocate. A method of allocating users will be described later.

The first parallel interference cancellation block 52 functions to remove interference and detect each user signal among user signals assigned to the user among the signals detected in the user matching / assignment block 50. The interference cancellation process is the same as the parallel interference cancellation process described with reference to FIGS. 1 and 2, except that the interference cancellation is not performed for all users.

Each detected user's signal is input to a first decision block 54, which determines the digital signal level (1 or -1) of the user assigned to the first parallel interference cancellation block.

The first parallel interference cancellation block 52 also outputs a regenerated signal obtained by multiplying the detected user signal by a spreading code. The value obtained by subtracting the regenerated signal output from the received signal r (t) is input to the second parallel interference cancellation block.

The second parallel interference cancellation block 53 performs a function of removing interference and detecting a signal for a user assigned to the user among the signals detected in the user matching / assignment block. The second parallel interference cancellation block 53 also removes interference in the same manner as the parallel interference cancellation process described with reference to FIGS. 1 and 2. However, in the case of the second parallel interference cancellation block, the interference is removed for the user assigned to the user while the interference is removed for some users through the first parallel interference cancellation block. The signal can be detected more accurately than the first parallel interference cancellation block.

The second decision block 55 determines the digital signal levels of the users detected by the second parallel interference cancellation block.

FIG. 6 is a flowchart illustrating an operation of the multi-user interference cancellation apparatus of FIG. 5. The operation of the multi-user interference cancellation apparatus according to the present invention will be described in detail with reference to FIG. 6 as follows.

As shown in FIG. 6, first, the user matching / assignment block 50 detects a signal of each user in a received signal in which signals of users who share the same channel are mixed (S600). The signal can be detected using a general matching filter or the like.

When signal detection for the users is completed, it is determined in which block of the two parallel interference cancellation blocks to allocate the users (S601).

According to a preferred embodiment of the present invention, the first parallel interference cancellation block 52 is assigned to users having a high signal strength, and the second parallel interference cancellation block 53 is the first parallel interference cancellation block 53. It is desirable to assign users that are weaker than the signal strength of the users assigned to. As described above, since the second parallel interference cancellation block 53 cancels the interference after being removed to the interference for some users in the first parallel interference cancellation block 52, it detects more than the first parallel interference block 52. Because of the high accuracy, the weak signal strength, which is difficult to detect, is allocated to the second parallel interference cancellation block 53.

According to another embodiment of the present invention, the first parallel interference cancellation block 52 is assigned to users requiring a lower quality of service (QoS) than an arbitrary threshold value, and the second parallel interference cancellation block 53 is assigned. In this case, the users requiring QoS higher than an arbitrary threshold value are allocated. Since users sharing the same channel may request different services, the users are allocated according to the QoS of the required service, not the signal strength. As described above, since the detection accuracy in the second parallel interference cancellation block 53 is higher, signals of users requiring high QoS are allocated to the second parallel interference cancellation block.

If it is determined how the user is allocated, the first parallel interference cancellation block removes the interference on the users assigned to the user and detects the user's signal (S602). Interference cancellation uses a common parallel interference cancellation scheme that simultaneously removes interference for multiple users, as described above.

Signals of the users detected by removing the interference are input to the first decision block 54, and the first decision block 54 determines the digital signal level of each user signal (S603).

Meanwhile, the first parallel interference cancellation block 52 regenerates signals of spread users by multiplying the detected signal by a spreading code, and subtracts the regenerated signal from the signal received from the base station. This signal is input to the second parallel interference cancellation block 53 together with the signals of users assigned to the second parallel interference cancellation block 53 (S604). To subtract the regenerated signal in the first parallel interference cancellation block 52 from the received signal, the received signal is delayed by the processing time of the first parallel interference cancellation block in the delay block 51. The second parallel interference cancellation block 53 performs interference cancellation on the remaining users after the interference is removed for the users assigned to the first parallel interference cancellation block, so that the signals of the users can be detected more accurately. .

The second parallel interference cancellation block 53 removes interference with respect to the assigned users and detects a signal of each user (S605).

The detected signal is input to the second decision block 55, and the second decision block 55 determines the digital signal level of each user whose interference has been removed (S606).

Preferred embodiments of the invention described above are disclosed for purposes of illustration. In FIG. 5, a structure in which two parallel interference cancellation blocks are connected in series, but this is only an example, and the case of changing the number of parallel interference cancellation blocks is within the scope of the present invention. In addition to this case, those skilled in the art will appreciate that various modifications, changes, and additions can be made within the spirit and scope of the present invention, and such modifications, changes, and additions should be regarded as belonging to the following claims. .

As described above, according to the apparatus and method for multi-user interference cancellation according to the present invention, the received signal is divided into several blocks without completely removing the signals of all users from the received signal, and the allocated users are allocated within the first block. Since only the signal is removed and the second block has a parallel interference cancellation method for the signal from which the first block has been canceled, the computation and processing time can be reduced compared to the parallel interference cancellation method having two stages. There is an advantage. Since the interference canceling apparatus according to the present invention does not remove the user's signal in the first block, residual interference signal components exist even after the interference cancellation process, so that some degradation of the performance is expected. You can mitigate performance degradation. In particular, when there are users requiring various services, the present invention can be effectively utilized because the users can be assigned according to QoS.

Claims (6)

A matched filter for detecting signal components of respective users from the received signal; A plurality of parallel interference cancellation blocks configured to detect a user signal by applying a parallel interference cancellation technique to an input user signal; User allocation means for determining allocation to each of said plurality of parallel interference cancellation blocks for signals of respective users detected by said matching filter; And Means for determining digital signal levels of users detected in the connected parallel interference cancellation blocks, respectively, connected to the plurality of parallel interference cancellation blocks; The plurality of parallel interference cancellation blocks are connected in series to perform interference cancellation and user detection only on sequentially allocated user signals, and the parallel interference cancellation block, which first performs the interference cancellation process, is regenerated through interference cancellation in the received signal. And a signal obtained by subtracting the signal into a parallel interference cancellation block for performing interference cancellation later. The method of claim 1, And the user allocating means assigns users whose signal strength is greater than a set threshold to the first block for performing interference cancellation among the plurality of interference cancellation blocks. The method of claim 1, And the user allocating means assigns users requiring QoS lower than a set threshold to a block for performing interference cancellation first among the plurality of interference cancellation blocks. A method for eliminating user interference by connecting a plurality of parallel interference cancellation blocks for detecting a user signal in series by applying a parallel interference cancellation technique to an input user signal, Detecting a signal component of each user from the received signal (a); Determining (b) assigning signals of the respective users detected in the step (a) to the plurality of parallel interference cancellation blocks, respectively; In the sequence of the parallel interference cancellation blocks in series, interference cancellation and user detection are performed only on the assigned user signal, and the parallel interference cancellation block, which first performs the interference cancellation process, is regenerated through interference cancellation in the received signal. And (c) inputting the signal after subtracting the signal into a parallel interference cancellation block for performing interference cancellation later. The method of claim 4, wherein User assignment in step (b), And allocating users whose signal strength is greater than a predetermined threshold to the first block for performing interference cancellation among the plurality of interference cancellation blocks. The method of claim 4, wherein User assignment in step (b), And assigning users requiring QoS lower than a set threshold to a block for performing interference cancellation first among the plurality of interference cancellation blocks.