KR100682980B1 - Multistage Adaptive Parallel Interference Canceller - Google Patents

Abstract

It is included in the downlink receiver composed of multi-channels and has a multi-stage parallel structure that removes the interference signal by other users and the interference signal by multipath. The interference canceller of each stage is used for each channel with respect to the output signal of the rake receiver. Matching filter unit for matching the signal of the component, soft decision unit having a monotonically increasing slope, soft decision unit for determining the output signal of the match filter, weight control unit for controlling the slope of the soft decision unit in front of the soft decision unit, the soft decision signal and the Walsh code The calculated interference from the re-spreading unit for respreading using a scrambling code, the interference reproducing unit for calculating the interference signal by other users included in the re-spread signal, and the multi-path interference signal, and the signal received at the rake receiver Adaptive multi-stage partial parallel between A subtractor is disclosed.

Multipath Fading, Interference Canceller, Rake Receiver, Channel Predictor, Diffusion

Description

Multistage Adaptive Parallel Interference Canceller             

1 is an overall configuration diagram of a multi-stage parallel interference canceller using a conventional hard decision device;

FIG. 2 is a diagram for describing a process of removing an interference signal as an internal configuration diagram of an interference canceller of an i-th stage of FIG. 1;

3 is an overall configuration diagram of an adaptive multi-stage partial parallel interference canceller for removing interference signals in downlink according to a preferred embodiment of the present invention;

4 is a schematic configuration diagram illustrating the transmitting end of FIG. 3;

5 is a detailed configuration diagram of the receiving end of FIG. 3;

6 is an internal configuration diagram of the rake receiver of FIG.

FIG. 7 is a diagram illustrating an internal configuration of an interference canceller of an ith stage of FIG. 5;

FIG. 8 is a diagram illustrating an internal configuration of an interference canceller of an i-th stage in which an interference signal calculation process of the interference regenerator of FIG. 7 is changed to simplify a circuit;

9 is a block diagram of an adaptive multi-stage partial parallel interference canceller of FIG.

10 is an overall configuration diagram of an adaptive multi-stage partial parallel interference canceller for removing interference signals in uplink according to a preferred embodiment of the present invention;

FIG. 11 is a schematic configuration diagram illustrating the transmitting end of FIG. 10; FIG.

12 is a detailed configuration diagram of the receiving end of FIG. 10;

FIG. 13 is a diagram illustrating an internal configuration of the rake receiver of FIG. 12;

FIG. 14 is a diagram illustrating an internal configuration of an interference canceller of an ith stage of FIG. 12;

15 is a block diagram of an adaptive multi-stage partial parallel interference canceller of FIG.

16 is a block diagram of an adaptive multi-stage partial parallel interference canceller that removes an interference signal from an output stage of a matched filter according to another embodiment of the present invention;

17 is a block diagram of the adaptive multi-stage partial parallel interference canceller of FIG.

18 is a graph comparing the performance of the conventional parallel interference canceller and the adaptive multi-stage partial parallel interference canceller of the present invention;

19a is a performance graph of a multi-stage partial parallel interference canceller that independently controls the slope and the step weights of the soft determiner;

19B is a performance graph of an adaptive multi-stage partial parallel interference canceller in accordance with the present invention.

<Description of main reference numerals in the drawings>

36, 106: Rake receiver 38, 108: Matched filter

40, 120: interference canceller 72, 142: weight controller

74, 144: soft decision device 78, 148: interference regenerator

The present invention relates to an adaptive multi-stage partial parallel interference canceller capable of efficiently eliminating inter-user interference and inter-path interference due to multipath fading channels in a DS-CDMA-based mobile communication system. .

The third generation communication system, which aims at a data rate of 2 Mbps, will always have interference from other user signals and interference from multipath fading channels by using the DS-CDMA scheme. The use of orthogonal codes without inter-symbol interference not only impairs orthogonality of orthogonal codes in time-varying fading channels, but also allows the rake receiver to generate more complex inter-path interference, making MUD (Multi-User Detection) more complex. Cause.

In addition, the implementation of a multi-rate system to provide differentiated services for each user adds to the complexity of the system, and a channel having a low data rate is subject to strong interference from a channel having a high data rate, thereby causing serious performance degradation. Cause.

To solve this problem, the concept of MUD has been proposed and many research results have been published. Among them, MLS (Maximum Likelihood Sequence) detector, linear MUD, MUD using neural network, and nonlinear MUD are known as the representative research results.

However, MLS detector has the disadvantage that the complexity increases exponentially and the real-time implementation is difficult as the user increases, and linear MUD may have a good performance in a white noise environment, but performance is severely degraded in a time-varying channel. The adaptive linear MUD to overcome the time-varying characteristics of the channel has the disadvantage of inefficient channel usage due to the use of the learning sequence.In the case of a high-speed data channel using a long period of code, the correlation coefficient between user codes is very fast. There is a limit to convergence.

Examples of MUDs using neural networks include multi-layer neural networks (MLPs) and hopfield neural networks (HNNs). Like multi-layer neural networks (MLPs), like adaptive linear MUDs, they require learning signals. As the number of neurons increases, a faster back-propagation algorithm is required. In addition, as the number of users increases, the hopfield neural network (HNN) may increase the number of local minimums and thus fail to converge to the global minimum.

On the other hand, a parallel interference canceller, which is a nonlinear MUD, is the most realistic structure for overcoming the limitation of the time varying characteristics of a long period code although the system is relatively complicated. Among them, multi-stage parallel interference canceller has been evaluated as a very effective device for the low speed data channel.

1 is an overall configuration diagram of a multi-stage parallel interference canceller using a conventional hard decision maker. As shown, the received signal r (t) received by the rake receiver 10 passes through the parallel interference canceller 15 of the multi-stage structure and the interference signal by the other user signal and the interference signal by the multi-path are removed.

FIG. 2 is a diagram illustrating an internal configuration of the interference canceller of the i-th stage of FIG. 1, in which an interference signal is removed. Here, the subscript i is used to refer to the interference canceller of the i-th stage, and the subscript j is used to distinguish the channel (j = 1-4).

Referring to the figure, the hard determiner 20 of each channel determines the signal component of each channel as +1 or -1, which is a digital signal, and the determined signal is the Walsh code W (t), which is a channel classification code. And re-spread with a scrambling code S (t) and input to the interference regenerator 22.

If the interference regenerator 22 assumes a multipath delay as shown in FIG. 6, the interference regenerator 22 calculates the total interference signal I _ij (t) including the interference signal by another user according to Equation 1 below.

The calculated total interference signal I _ij (t) is removed from the input signal r (t) of the rake receiver 24, and the rake receiver 24 outputs the output signal x _ij based on the signal from which the interference signal has been removed. . Where a _ij (t), b _ij (t), c _ij (t) is the output of the channel estimator in the rake receiver 24, that is shown in the drawings to refer to the tap gains of each of the paths a _i3 (t), b _i3 (t), c _i3 (t) is the tap gain of the i th only third channel.

The output signal x _ij (t) of the rake receiver 24 is again extracted by the matching filter 26 as a signal component of each channel and input as an input signal of the i + 1 interference canceller. As described above, the signal passing through the multi-level parallel interference canceller is calculated with more accurate interference signal, and finally only valid signals for each channel can be detected.

 On the other hand, since the multi-stage parallel interference canceller using the above-described hard determiner is greatly influenced by the bit decision by the hard determiner of the previous stage, the bit information which is initially determined incorrectly may cause a problem of rapidly degrading performance by adding interference. . In particular, in a system with a low spreading gain for high speed data transmission, the initial detection error is not eliminated even as the step is increased and continues to be affected, causing a detection error saturation phenomenon.

In order to overcome this problem, a multistage partial parallel interference canceller (Multistage Partial PIC) has been recently proposed to remove only a part of an interference signal at each stage of an interference canceller. That is, a weight controller is provided at the rear end of the hard determiner to give a weight to the hard determined value or to use a soft determiner that can change the slope step by step. In addition, by placing a weight controller at the rear end of the soft determiner, the soft decision value may be weighted again to calculate a more precise interference signal.

However, the method has a difficulty in optimizing the slope and the step weights of the soft determiner at the same time. In particular, in a time-varying channel with strong inter-channel interference due to power control failure or an increase in the number of users, it is more difficult to optimize the slope and the step weight of the soft determiner.

Therefore, there is an urgent need for an interference canceller that can effectively eliminate the interference caused by multiple users and multiple paths in the fading channel having time varying characteristics by easily optimizing the slope and the step weight of the soft decision device.

The present invention was devised to solve the above problems, and includes a soft decision device capable of tilt control in a multi-stage parallel interference canceller and a weight controller in front of the soft decision device so that the weight controller adaptively controls the slope of the soft decision device. An object of the present invention is to provide an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) that effectively removes interference by multi-users and multi-paths in a characteristic channel.

In addition, an object of the present invention is to provide an adaptive multi-stage parallel interference canceller (Multistage Adaptive Partial PIC) that minimizes orthogonal degradation between user signals by normalizing the output signal of the rake receiver to the output signal of the channel predictor.                         

In addition, by storing the output signal of the rake receiver or the output signal of the matching filter in the memory, and repeatedly using the value stored in the memory to provide an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) to improve the complexity of the circuit For the purpose of

Other objects and advantages of the invention will be described below and will be appreciated by the practice of the invention. In addition, the objects and advantages of the present invention can be realized by means and combinations indicated in the claims.

In order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in a downlink (or uplink) receiver composed of a plurality of channels and eliminates interference signals by other users and interference signals by multipaths. An interference canceller composed of a multi-stage parallel structure, the interference canceller of each stage having a monotonically increasing slope and a soft decision on the output signal of the matched filter, matching the signal of each channel component with respect to the output signal of the rake receiver. Soft decision unit, weight control unit for controlling the slope of the soft decision unit in front of the soft decision unit, re-spreading unit for respreading the soft decision signal using Walsh code and scrambling code, interference signal by other users included in the re-spread signal And from the signal received at the interference reproducing unit and the rake receiver for calculating the interference signal by the multipath. It includes an interference signal removal unit for removing the calculated interference signal.

In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in a downlink (or uplink) receiver composed of a plurality of channels, and an interference signal by another user and an interference signal by multipath. An interference canceller composed of a multi-stage parallel structure that removes a signal, the interference canceller of each stage matches a signal of each channel component with respect to an input signal, and a soft board having a monotonically increasing slope and softly determining the output signal of the matched filter. Weight control unit for controlling the slope of the soft decision government in front of the government, the soft decision government, re-spreading unit for respreading the soft decision signal using the Walsh code and the scrambling code, interference signals from other users included in the re-spread signal, and The calculated interference signal in the output signal of the interference reproducing unit and the rake receiver for calculating the interference signal by the multipath It includes an interference signal removing unit for removing the call.

In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in a downlink (or uplink) receiver composed of a plurality of channels, and an interference signal by another user and an interference signal by multipath. An interference canceller for eliminating a signal, comprising: a normalizer for normalizing an output signal of a rake receiver to a sum of squares of tap gains of each path, a first memory unit for storing the normalized signal, a Walsh code, a scrambling code, and a A second memory unit for storing the strength of the received signal, a fourth memory unit for storing the multipath tap gain of the rake receiver, and an interference signal (IPI) based on a predetermined equation using the tap gain stored in the fourth memory And an interference reproducing unit calculating a compensation signal IPS, and subtracting the interference signal IPI calculated by the interference reproducing unit from the normalized signal stored in the first memory. An interference signal removing unit, a third memory unit storing an output signal of the interference signal removing unit, a compensation signal adding unit adding a compensation signal IPS stored in the interference reproducing unit from a signal stored in the third memory unit; And a signal processor for sequentially re-spreading the signal using matched filtering, weight control, soft decision, deinterleaving, decoding, interleaving, encoding, and the value of the second memory with respect to the output signal of the compensation signal adder. The output signal of the signal processor is characterized in that the feedback structure is input to the interference regeneration unit.

In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in an uplink receiver composed of a plurality of channels and multi-stage parallel elimination of interference signals by other users and interference signals by multipath. An interference canceller having a structure, the interference canceller at each stage has a matching filter unit for matching signals of each channel component with respect to an input signal, and a soft decision unit for leading the soft decision output signal of the matching filter with a monotonically increasing slope. A weight control unit for controlling the slope of the soft decision unit, a re-spreading unit for respreading the soft decision signal using the Walsh code and the scrambling code, interference by other users included in the re-spread signal, and interference by multipath Removing the calculated interference signal from the output signal of the interference reproducing unit and the rake receiver for calculating the signal It includes parts of interference signal removal.

In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in an uplink receiver composed of a plurality of channels, and an interference canceller for removing interference signals by other users and interference signals by multipaths. A normalization unit for normalizing the output signal of the rake receiver to the sum of the squared tap gains of each path, a first memory unit for storing the normalized signal, a Walsh code, a scrambling code, and the intensity of the received signal of each channel. A second memory unit for storing, a fourth memory unit for storing the multipath tap gain of the rake receiver, and an interference reproducing unit for calculating the interference signal I by a predetermined equation using the tap gain stored in the fourth memory And an interference signal removing unit for removing the interference signal I calculated by the interference reproducing unit from the normalized signal stored in the first memory. A third memory unit which stores a negative output signal, and sequentially matched filtering, weight control, soft decision, deinterleaving, decoding, interleaving, encoding, and the value of the second memory with respect to the signals stored in the third memory unit. And a signal processing unit for respreading the signal, wherein the output signal of the signal processing unit has a feedback structure input to the interference regeneration unit.

In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in an uplink receiver composed of a plurality of channels and a multi-stage parallel structure for removing interference signals by other users and interference signals by multipaths. The interference canceller of each stage has a monotonically increasing slope, a soft decision unit for soft decision of an input signal, a weight control unit for controlling the slope of the soft decision unit in front of the soft decision unit, and a scrambling of the soft decision signal with the Walsh code. Respreading unit to re-spread using code, Interference regenerating unit to calculate interference signal by other users included in re-spread signal and Multipath interference signal, Output signal of rake receiver as signal of each channel component Matching filter unit for matching and eliminating interference signal to remove the calculated interference signal from the matched signal It includes.

)를 계산하는 간섭재생부, 상기 제1메모리에 저장된 정합된 신호로부터 상기 간섭재생부에서 계산된 간섭신호(

)를 제거하는 간섭신호제거부, 상기 간섭신호제거부의 출력 신호를 저장하는 제3메모리부, 상기 제3메모리부에 저장된 신호에 대하여 순차적으로 가중치제어, 연판정, 디인터리빙, 디코딩, 인터리링, 인코딩 및 상기 제2메모리의 값을 이용하여 신호를 재확산시키는 신호처리부를 포함하고, 상기 신호처리부의 출력신호는 다시 간섭재생부에 입력되는 궤환구조로 이루어진 것 을 특징으로 한다.In addition, in order to achieve the above object, the adaptive multi-stage partial parallel interference canceller according to the present invention is included in an uplink receiver composed of a plurality of channels, and an interference canceller for removing interference signals by other users and interference signals by multipaths. A normalizing unit for normalizing the output signal of the rake receiver to the sum of the tap gain squares of each path, a matching filter unit for matching each channel component from the normalized signal, a first memory unit for storing the matched signal, and A second memory unit for storing the channel Walsh code, the scrambling code and the strength of the received signal of each channel, a fourth memory unit for storing the multipath tap gain of the rake receiver, and a predetermined value using the tap gain stored in the fourth memory Interference signal by the equation (

And an interference signal calculated by the interference reproducing unit from the matched signal stored in the first memory.

), A third memory unit for storing the output signal of the interference signal removing unit, weight control, soft decision, deinterleaving, decoding, interleaving in sequence for the signals stored in the third memory unit. And a signal processor for re-spreading the signal using the encoding and the value of the second memory, wherein the output signal of the signal processor has a feedback structure input to the interference regeneration unit.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Prior to the description, the subscript i written in the variable X _ij representing a specific signal refers to a signal input or output to the interference canceller of the i th stage, and the subscript j refers to the j th channel.

<Downlink>

3 is an overall configuration diagram of an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) for removing interference signals in downlink according to a preferred embodiment of the present invention. Referring to the figure, each terminal used by K users uses m _k channels having different data rates. Data information of each channel received at the base station is encoded and interleaved by an encoder / interleaver 32 and multiplied by the Walsh code W _k (t) for distinguishing channels.

The output signals of each channel are summed and multiplied by the scrambling code S (t) used to distinguish the base station and transmitted to each user terminal. At this time, each signal is affected by multipath fading and white noise n (t) is added to the rake receiver 36 of the user terminal.

Multipath fading refers to a phenomenon in which transmitted radio signals have different amplitudes and phases due to irregular terrain and multiple reflections / diffractions of obstacles. That is, the delay spread phenomenon occurs due to the time difference of the radio waves reaching through each path, and the arrival speed varies depending on the frequency.

A receiver for independently separating and demodulating each reflected wave arriving with such a time delay is referred to as a rake receiver 36.

On the other hand, the output signal of the rake receiver 36 is input to the matching filter 38 to output the signal component y _ij of each channel. However, since y _ij , a signal component of each channel, is a signal in which interference by other users and interference by multiple paths are not removed, it cannot actually be used in a time-varying channel environment used by multiple users. Accordingly, the present invention is to effectively remove the interference by the multi-user and the multi-path interference by using an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) for the signal input to the rake receiver 36.

4 simplifies the configuration of the transmitter of FIG. The transmitting end may generally be a base station transmitting a signal to a user terminal.

Referring to the figure, it is assumed that three users use one, two, and one channel having various data rates. The user may separately transmit an audio signal and a video signal through two channels.

As described above with reference to FIG. 3, the signal passing through the encoder / interleaver 32 is multiplied by the Walsh code W _j (t) to distinguish the channels, and again, the scrambling code S (t) to distinguish the base station is multiplied to each terminal of the user. Is sent to. As described above, in the process of transmitting a signal, the multipath is affected by fading, and the white noise n (t) is added and transmitted to the user terminal.

FIG. 5 is a detailed configuration diagram of the receiving end of FIG. 3. The receiving end may generally be a mobile communication terminal receiving a signal from a base station.

Referring to the figure, the signal r (t) transmitted by the fading due to multipath from the base station and added with white noise is received by the rake receiver 36. The lake receiver 36 outputs x ₀ (t) by applying the output of the internal channel predictor, that is, tap gain of each finger.

The output signal x ₀ (t) of the rake receiver 36 is extracted by each channel component y _1j (j = 1 to 4) by the matching filter 38 of each channel, thereby eliminating the interference of the first stage. Is entered. The output signal of the first stage interference canceller 40 is again input to the second stage interference canceller 40 and sequentially input to the multiple stage interference canceller 40 in the same manner.

The signal of each channel passes through the multi-level interference canceller 40, and the more accurately calculated interference signal is removed, and the signal passed through the final interference canceller 40 is deinterleaver / decoder 42. It is extracted to the desired user terminal signal.

6 shows an internal configuration of the rake receiver of FIG. 5. Referring to the drawing, when the signal r (t) transmitted by the base station is input to the rake receiver 36 of the user terminal, the channel estimator 64 in the rake receiver 36 is a _i , which is the tap gain of each finger. (t), b _i (t), c _i (t) and the intensity A _j (t) of each channel reception signal are output.

On the other hand, the signals input with the time difference by the multi-path are multiplied by the tap gain of the channel predictor 64 and summed again to be input to the matching filter 38. In this case, the present invention further includes a process of normalizing the output of the rake receiver in order to prevent the orthogonality between user signals due to the time-varying channel. That is, it is normalized by dividing the output of the conventional rake receiver (part shown by the broken line in the figure) by the sum of the squares of the path tap gains.

The signal x ₀ of the normalized rake receiver 36 is input to the matching filter 38 of each channel and matched. The process of matching the input signal x ₀ by the matching filter 38 is the same as the equation described in the drawing. That is, the integrated during the R _j T _c of time multiplied by the rake receiver 36, the output signal x ₀ (t) Walsh code W _ij (t) and the scrambling code S _i (t) to distinguish the base station to distinguish user channels on the . Here, R _j refers to the spreading gain of the j-th channel, 1 / T _c refers to the chip rate (chip rate).

The output signal of the first matching filter 38, y _1j (t) is input to the interference canceller 40 of the first stage and the precise interference signal is calculated while passing through the interference canceller 40 of the first stage.

FIG. 7 is a diagram illustrating an internal configuration of an interference canceller of an i-th stage of FIG. 5. The adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) according to the present invention may be implemented by placing a weight controller in front of the soft determiner and a soft determiner capable of tilt control and controlling the inclination of the soft determiner by the weight controller.

Preferably, a hyperbolic tangent function capable of tilt control is used as a soft determiner, and a weight controller can monotonically increase the slope of the hyperbible tangent function in each stage from the first stage to the last stage. You can simplify it a bit more. In addition, by controlling the change of the gradient step by step according to the user and the channel environment, it is possible to prevent performance degradation in various channels.

Referring to the drawings, the soft determiner 74 uses a hyperblick tangent as shown in Equation 2 below, and in order to avoid the difficulty of directly controlling the inclination of the soft determiner 74, the weight controller 72 is provided at the front end thereof. It can be easily optimized by controlling the slope ω.

(여기서, U는 연판정기의 입력신호, ω는 기울기)

Where U is the input signal of the soft judge and ω is the slope.

The weight controller 72 that controls the slope of the soft determiner controls the slope of the soft determiner 74 by an LMS algorithm or an average / dispersion ratio algorithm.

은 최종 간섭제거기단의 판정신호

를 의미한다. The LMS algorithm for estimating the slope ω is as shown in Equation 3 below.

Is the decision signal of the final interference canceller.

Means.

Also, the average / dispersion ratio algorithm is shown in Equation 4 below.

If the output signal y _ij (t) of the i-first stage interference canceller is input to the i-th stage interference canceller, it is effective in the jth channel by the soft determiner 74 having the slope controlled by the weight controller 72. The signal magnitude is determined. That is, instead of being determined as +1 or -1 collectively as in the hard decision maker, the appropriate value is determined step by step according to the controlled inclination value.

The signal passing through the soft determiner 74 is sequentially deinterleaved, decoded, encoded and interleaved and respread by the Walsh code W _ij (t) and the scrambling code S _i (t). The spread signal z _ij (t) is input to the interference regenerator 78 and the interference signal included in each channel is calculated.

The interference signal calculated by the interference regenerator 78 is expressed by Equation 5 below.

In Equation 5, a (t), b (t), and c (t) are tap gains for each path of the rake receiver, z (t) is a respread signal, 1 / Tc Is chip rate, lTc, mTc is multipath delay time, R _j is spread gain
The interference signal calculated in Equation 5 is subtracted from the output signal of each finger of the rake receiver, and normalized by the tap gain of the channel predictor to output x _i (t).

Where r _i (t), a _i (t), b _i (t), c _i (t) interfere with r (t), a ₀ (t), b ₀ (t), c ₀ (t) The time-synchronized signal considering the processing delay time of the i-th stage of eliminator.

On the other hand, the IPS _ij value calculated in Equation 5 is added to the output x _i (t) of the normalized rake receiver to compensate for the excessively subtracted interference signal.

As described above, the signal from which the interference signal is removed by the i &lt; th &gt; interference canceller is input to the matching filter 38 and matched to be input again to the i + 1 &lt; th &gt;

FIG. 8 is an internal configuration diagram of an ith interference canceller simplified by changing an interference signal calculation process of the interference regenerator of FIG. 7. Here, the same reference numerals as in FIG. 7 indicate the same members having the same function.

Referring to FIG. 7, if the interference regenerator 78 assumes a multipath delay as shown in FIG. 6, the interference signal is calculated according to Equation 6 below. In Equation 6, a (t), b (t), and c (t) are tap gains for each path of the rake receiver, and z (t) is a respread signal, 1 / Tc. Is chip rate, lTc, mTc is multipath delay time, R _j is spread gain

Interference regenerator 78, the interference signal is also input to the rake receiver, such as 7 to x ₀ of the first output signal from the x _io (Rake receiver instead of being removed for each path, the output signal of the RAKE receiver i-th stage calculated by The circuit can be implemented simply by eliminating from the signal delayed in accordance with the interference canceller processing time. The subsequent process is the same as FIG.

FIG. 9 is a block diagram of the adaptive multistage partial parallel interference canceller (Multistage Adaptive Partial PIC) of FIG. As described above, since each stage of the interference canceller performs the same function, the output signal of the rake receiver is stored in the memory, and the values stored in the memory are repeatedly used, thereby making it possible to use the entire adaptive multilevel partial parallel interference canceller (Multistage Adaptive Partial PIC). Can be implemented in a simple circuit.

Referring to the drawing, the first output signal x ₀ of the rake receiver 36 is input to the first memory 85 and stored. In addition, the second memory 86 stores the Walsh code W _j and the scrambling code S of each channel, and the reception strength A _j of the signal input to each channel.

The third memory 87 stores a value obtained by subtracting the interference signal IPI _i calculated by the interference regenerator 84 from the output signal x ₀ of the rake receiver. In addition, the fourth memory 88 stores the tap gains a, b, and c for each path, which are output signals of the channel predictor.

The signal processor 89 is a device packaged using an ASIC or a DSP. The signal processor 89 includes a matching filter, a weight controller, a soft determiner, a deinterleaver / decoder, an encoder / interleaver, and a spreader, and sequentially performs each function.

The overall operation of FIG. 9 is the same as that of FIG. 8. That is, the interference signal IPI _i calculated by the interference regenerator 78 is subtracted from x ₀ stored in the first memory 85 and stored in the third memory 87. The value stored in the third memory 87 is again compensated by the IPS _ij value and input to the signal processor 89. In this case, the IPS _ij value is a value that compensates for the excess signal content when the interference signal is removed and is calculated according to Equation 6 by the interference regenerator 84.

As described above with reference to FIG. 8, the signal input to the signal processor 89 is output to the interference regenerator 78 through a matched filter, a weight controller, a soft determiner, a deinterleaver / decoder, an encoder / interleaver and a spreader. Here, the spreader of the signal processor 89 respreads the received signal using the Walsh code W _j and the scrambling code S stored in the second memory 86 and the received signal strength A _j of each channel.

The interference regenerator 78 calculates the interference signal more precisely as the input of the respread signal and the tap gain of each path stored in the fourth memory. The calculated interference signal is fed back to the first memory 85 that stores the output value of the rake receiver 36, subtracted at x ₀ , and repeats the above-described process. As feedback is repeated, a more precise interference signal is calculated, and when converged to a predetermined interference signal, a desired user signal is extracted by removing the converged interference signal.

Through this feedback structure, the circuit complexity, which is a disadvantage of nonlinear MUD, can be significantly reduced.

<Uplink>

10 is an overall configuration diagram of an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) for removing interference signals in uplink according to a preferred embodiment of the present invention. Referring to the figure, each terminal used by K users uses m _k channels having different data rates. Data information of each channel is encoded and interleaved by an encoder / interleaver, and the Walsh code W _k (t) for distinguishing channels is multiplied.

The output signals of each channel are summed for each user and multiplied by a scrambling code S _j (t) for distinguishing a user terminal and transmitted to a base station. At this time, each signal is affected by multipath fading and white noise n (t) is added and received by the rake receiver 106 of the base station.

On the other hand, the output signal of the rake receiver 106 is input to the matching filter 108 and the signal component y _ij of each channel is output. However, since y _ij , a signal component of each channel, does not remove interference by other users and interference by multiple paths, it cannot be used in a time-varying channel environment that is actually used by multiple users. Accordingly, the present invention is to effectively remove the interference by the multi-user and the interference by the multi-path using an adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) with respect to the signal input to the rake receiver 106.

11 simplifies the configuration of the transmitting end of FIG. In general, the transmitting end may be a user terminal transmitting a signal to a base station.

Referring to the figure, it is assumed that three users use one, two, and one channel having various data rates. The user may separately transmit an audio signal and a video signal through two channels.

As described with reference to FIG. 10, the signals passing through the encoder / interleaver 102 are multiplied by the Walsh code W _j (t) to distinguish the channels, and again, the scrambling code S _j (t) to distinguish the user terminal is multiplied to the base station. Is sent. As described above, in the process of transmitting a signal, fading is affected by multipath, and white noise n (t) is added to the base station.

12 is a detailed block diagram of the receiving end of FIG. 10. The receiving end may generally be a base station receiving a signal from a user terminal.

Referring to the figure, the signal r (t) transmitted by the fading due to multipath from the user terminal and added with white noise is received by the rake receiver 106. The rake receiver 106 outputs x _j (t) by applying the output of the internal channel predictor, that is, the tap gain of each finger.

The output signal x _j (t) of the rake receiver 106 is extracted by each channel component y _1j (j = 1 to 4) by the matching filter 108 of each channel, thereby eliminating the interference of the first stage 120. Is entered. The output signal of the first stage interference canceller 120 is again input to the second stage interference canceller 120 and sequentially input to the multiple stage interference canceller 120 in the same manner.

The signal of each channel passes through the multi-level interference canceller 120 and the interference signal is completely eliminated. The signal passed through the final interference canceller 120 is a desired user terminal signal by a deinterlever / decoder 122. Extracted.

FIG. 13 shows an internal configuration of the rake receiver of FIG. 12. Referring to the figure, when the signal r (t) transmitted by the base station is input to the rake receiver 106, the channel estimator 134 in the rake receiver 106 is a _ij (t), which is the tap gain of each finger. , b _ij (t), c _ij (t) and the strength A _j (t) of each channel reception signal are output.

On the other hand, the signals input with the time difference by the multi-path are multiplied by the tap gain of the channel predictor 134 and summed again and input to the matching filter 108. In this case, the present invention further includes a process of normalizing the output of the rake receiver in order to prevent the orthogonality between user signals due to the time-varying channel. That is, it is normalized by dividing the output of the conventional rake receiver (part shown by the broken line in the figure) by the sum of the squares of the path tap gains.

The signal x _j of the normalized rake receiver 106 is input to the matching filter 108 of each channel and matched. The process of matching the input signal x _j by the matching filter 108 is the same as the equation described in the drawing. That is, the output signal x _j (t) of the rake receiver 106 is multiplied by the Walsh code W _j (t) for classifying a user channel and the scrambling code S _j (t) for classifying a user terminal, and then integrated during R _j T _c. do. Here, R _j refers to the spreading gain of the j-th channel, 1 / T _c refers to the chip rate (chip rate).

The output signal of the first matching filter 108, y _1j (t) is input to the first stage of the interference canceller 120, and passes through the multiple stages of interference canceller 120, the precise interference signal is calculated.

FIG. 14 is a diagram illustrating an internal configuration of an interference canceller of an ith stage of FIG. 12. The adaptive multi-stage partial parallel interference canceller (Multistage Adaptive Partial PIC) according to the present invention may be implemented by placing a weight controller in front of the soft determiner and a soft determiner capable of tilt control and controlling the inclination of the soft determiner by the weight controller.

Preferably, a hyperbolic tangent function capable of tilt control is used as a soft determiner, and a weight controller can monotonically increase the slope of the hyperbible tangent function in each stage from the first stage to the last stage. You can simplify it a bit more. In addition, by controlling the change of the gradient step by step according to the user and the channel environment, it is possible to prevent performance degradation in various channels.

Referring to the drawing, the soft determiner 144 can be easily optimized by using a hyperbly tangent as shown in Equation 2 like the downlink and controlling the slope ω by placing the weight controller 142 at the front thereof.

The weight controller 142 that controls the slope of the soft determiner 144 controls the slope of the soft determiner 144 by an LMS algorithm or an average / dispersion ratio algorithm.

The LMS algorithm and the average / dispersion ratio algorithm are as described above in downlink.

When the output signal y _ij (t) of the i-first stage interference canceller is input to the i th stage interference canceller, it is effective in the j th channel by the soft decision unit 144 having the slope controlled by the weight controller 142. The signal magnitude is determined. That is, instead of being determined as +1 or -1 collectively as in the hard decision maker, the appropriate value is determined step by step according to the controlled inclination value.

The signal passing through the soft determiner 144 is sequentially deinterleaved, decoded, encoded and interleaved and respread by the Walsh code W _ij (t) and the scrambling code S _i (t). The spread signal z _ij (t) is input to the interference regenerator 148 and the interference signal included in each channel is calculated.

The interference signal calculated by the interference regenerator 148 is expressed by Equation 7 below.

The interference signal calculated in Equation 7 is removed from the output signal x _ij of the normalized rake receiver.

Where r _ij (t), a _ij (t), b _ij (t), and c _ij (t) interfere with r (t), a _0j (t), b _0j (t), and c _0j (t) The time-synchronized signal considering the processing delay time of the i-th stage of eliminator.

As described above, the signal from which the interference signal is removed by the i-th interference canceller is matched by the matching filter 108 and input again to the i + 1 th interference canceller.

FIG. 15 is a block diagram of a multi-stage partial parallel interference canceller (Multistage Partial PIC) of FIG. 14 configured as a feedback structure. As described above, since each stage of the interference canceller performs the same function, the output signal of the rake receiver is stored in the memory, and the values stored in the memory are repeatedly used, thereby making it possible to use the entire adaptive multilevel partial parallel interference canceller (Multistage Adaptive Partial PIC). Can be implemented in a simple circuit.

Referring to the drawing, the first output signal x _j of the rake receiver 106 is input to the first memory 135 and stored. In addition, the second memory 136 stores the Walsh code W _j and the scrambling code S _j of each channel, and the reception strength A _j of the signal input to each channel.

The third memory 137 stores a value obtained by subtracting the interference signal I _ij calculated by the interference regenerator 148 from the output signal x _j of the rake receiver. In addition, the fourth memory 138 stores the tap gains a, b, and c for each path, which are output signals of the channel predictor.

The signal processor 139 is a device packaged using an ASIC or a DSP. The signal processor 139 includes a matching filter, a weight controller, a soft determiner, a deinterleaver / decoder, an encoder / interleaver, and a spreader, and sequentially performs each function. .

The overall operation of FIG. 15 is the same as that of FIG. That is, the interference signal I _ij calculated by the interference regenerator 148 is subtracted from x _j stored in the first memory 135 and stored in the third memory 137, and the value stored in the third memory 137 is again a signal. It is input to the processing unit 139.

As described above with reference to FIG. 14, the signal input to the signal processor 139 is again output to the interference regenerator 148 through a matching filter, a weight controller, a soft determiner, a deinterleaver / decoder, an encoder / interleaver, and a spreader. The spreader of the signal processor 139 respreads the received signal using the Walsh code W _j and the scrambling code S _j stored in the second memory 136 and the received signal strength A _j of each channel.

The interference regenerator 148 calculates the interference signal more accurately by using the re-spread signal and the tap gain of each path stored in the fourth memory 138 as input. The calculated interference signal is fed back to the first memory 135 that stores the output value of the rake receiver 106, subtracted from x _j , and repeats the above-described process. As feedback is repeated, a more precise interference signal is calculated, and when converged to a predetermined interference signal, the value is removed to extract a desired user signal.

Through this feedback structure, the circuit complexity, which is a disadvantage of nonlinear MUD, can be significantly reduced.

FIG. 16 is a block diagram of an adaptive multi-stage partial parallel interference canceller (PSI) for removing interference signals at an output of a matched filter according to another embodiment of the present invention.

The overall operation is the same as that described with reference to FIG. 14, but the interference signal calculation process of the interference regenerator 148 is partially changed and the interference signal is removed from the output of the matching filter 108. The circuit can be further simplified by eliminating the interference signal at the output of the matched filter 108.

The modified interference signal calculation process of the interference regenerator 148 is expressed by Equation 8 below.

에서 간섭재생기(148)에 의해 계산된 간섭신호

를 제거한다. The output signal x _ij of the rake receiver is directly input to the matched filter 108 and the signal passed through the matched filter.

Signal calculated by the interference regenerator 148 at

Remove it.

FIG. 17 is a diagram illustrating a feedback structure of the adaptive multistage partial parallel interference canceller of FIG. 16. Here, the same reference numerals as in FIG. 15 denote the same members having the same function.

는 제1메모리(135)에 저장된 다. Referring to the drawings, the signal x _j (t) output from the rake receiver 106 is first input to the matching filter 108 to be signal matched, and the matched signal.

Is stored in the first memory 135.

에서 간섭재생기(148)의 의해 계산된 간섭신호

를 감산하고 제3메모리(137)에 저장한다. 제3메모리(137)에 저장된 값은 다시 신호처리부(139)에 입력된다. After this, stored in the first memory 135

Interference signal calculated by the interference regenerator 148 at

Is subtracted and stored in the third memory 137. The value stored in the third memory 137 is input to the signal processor 139 again.

The signal input to the signal processor 139 is again outputted to the interference regenerator 148 through a weight controller, a soft determiner, a deinterleaver / decoder, an encoder / interleaver and a spreader. The spreader of the signal processor 139 respreads the received signal using the Walsh code W _j and the scrambling code S _j stored in the second memory 136 and the received signal strength A _j of each channel.

에서 감해지고 다시 상술한 과정을 반복한다. 궤환을 반복할수록 더욱 정밀한 간섭신호가 계산되어 지고, 소정의 간섭신호로 수렴되면 이 값을 제거하여 원하는 사용자 신호를 추출한다. The interference regenerator 148 calculates the interference signal more accurately by using the re-spread signal and the tap gain of each path stored in the fourth memory 138 as input. The calculated interference signal is fed back to the first memory 135 that stores the output value of the rake receiver 106

Subtracted from and repeat the above process. As feedback is repeated, a more precise interference signal is calculated, and when converged to a predetermined interference signal, the value is removed to extract a desired user signal.

<Simulation Results>

For the uplink system, the performance of the adaptive multistage partial parallel interference canceller (Multistage Adaptive Partial PIC) was tested based on the environment shown in Table 1 below.

division parameter user 3-4 people Multiple access method DS-CDMA Chip transfer rate 3.84 Mcps Modulation method BPSK Spreading code Short Scrambling Code (Length: 256) Walsh code Spreading gain 4 Channel coding Rate 1/3, Turbo Code Channel model 3-path multipath channel COST207 Urban environment (Component: 0, 1, 2)

First, FIG. 18 is a graph comparing performance of an adaptive multistage partial parallel interference canceller (Multistage Adaptive Partial PIC) according to an embodiment of the present invention with a conventional parallel interference canceller.

Reference numeral 181 in the figure is a conventional multi-stage parallel interference canceller, 182 is a five-stage partial parallel interference canceller that partially removes the interference signal step by step by increasing the weight of the soft determiner step by step. 183 is a five-stage partial parallel interference canceller which partially removes the interference signal step by step by increasing the slope of the soft determiner, and 184 is an adaptive two-stage partial parallel interference canceller according to the present invention.

As shown in the graph, the adaptive multistage partial parallel interference canceller (Multistage Adaptive Partial PIC) according to the present invention shows a remarkable effect compared to the conventional 5-stage parallel interference canceller using only two stages, and a bit error rate (BER). Assuming 10 ⁻³ ), a gain of 2-3 dB can be obtained. It can be seen that this is in close agreement with the optimum performance 185 in an environment where there is no multi-user interference assuming one user.

FIG. 19A is a performance graph of a multistage partial interference canceller (Multistage Partial PIC) in which the slope and step weights of the soft determiner are changed at the rear end of the soft determiner, respectively. FIG. Performance graph of a Multistage Adaptive Partial PIC.

As shown in the figure, simply controlling the slope of the soft judge can solve the performance improvement and detection error saturation like the multistage partial PIC which simultaneously controls the slope and the step weight of the soft judge. It can be seen.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this, The person of ordinary skill in the art to which this invention belongs, Of course, various modifications and variations are possible within the scope of equivalent claims.

According to the present invention, a multi-stage parallel interference canceller is provided with a soft decision device capable of tilt control, and a weight controller is placed in front of the soft decision device to adaptively control the slope of the soft decision device. Can be effectively removed.

Also, by normalizing the output signal of the rake receiver to the output signal of the channel predictor, orthogonal deterioration between user signals can be minimized.

In addition, the complexity of the circuit may be improved by storing the output signal of the rake receiver or the output signal of the matching filter in a memory and repeatedly using the value stored in the memory.

Claims (42)

It is included in a downlink receiver composed of a multi-channel interference canceller consisting of a multi-stage parallel structure to remove interference signals by other users and interference signals by multipath, Each stage interference canceller A normalizer for normalizing the output signal of the rake receiver to the sum of squares of the path tap gains of the rake receiver; A matching filter unit for matching the signal of each channel component with respect to the output signal of the rake receiver using the normalization unit output signal; A soft decision unit having a monotonically increasing slope and soft decision of a matched signal; A weight control unit controlling the slope of the soft decision unit in front of the soft decision unit; A respreading unit for respreading the soft decision signal using the Walsh code and the scrambling code; An interference reproducing unit configured to calculate an interference signal by another user and an interference signal by a multipath included in the respread signal; And An interference signal removing unit for removing the calculated interference signal from the signal received at the rake receiver; Adaptive multi-stage partial parallel interference canceller comprising a. delete The method of claim 1, The soft decision unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the soft decision based on the following equation (1). (Equation 1)

Where ω is the slope and U is the input signal. The method of claim 3, wherein And the weight controller controls slope ω based on an LMS algorithm. The method of claim 3, wherein And the weight controller controls slope ω based on an average / dispersion ratio algorithm. The method according to any one of claims 3 to 5, And the interference regeneration unit calculates an interference signal (IPI) based on Equation 2 below. (Equation 2)

Where a (t), b (t) and c (t) are the tap gains for each path of the rake receiver, z (t) is the respread signal, 1 / Tc Is the chip rate, lTc and mTc are the multipath delay times. The method of claim 6, The interference regeneration unit further calculates a compensation signal IPS according to Equation 3 below. The interference canceller of each stage further comprises a compensation signal adder for adding the compensation signal (IPS) to the received signal from which the interference signal has been removed. (Equation 3)

Where R _j is the diffusion gain. The method of claim 1, The interference canceller of each stage Further comprising a deinterleaver / decoder section and an interleaver / encoder section in front of the respreading section, Adaptive multi-stage partial parallel interference canceller characterized in that for correcting the error of the signal through the deinterleaver / decoder unit, and interleaving and encoding the signal again through the interleaver / encoder unit. It is included in a downlink receiver composed of a multi-channel interference canceller consisting of a multi-stage parallel structure to remove interference signals by other users and interference signals by multipath, Each stage interference canceller A normalizer for normalizing the output signal of the rake receiver to the sum of squares of the path tap gains of the rake receiver; A matching filter unit matching a signal of each channel component with respect to an input signal using the normalization unit output signal; A soft decision unit having a monotonically increasing slope and soft decision of a matched signal; A weight control unit controlling the slope of the soft decision unit in front of the soft decision unit; A respreading unit for respreading the soft decision signal using the Walsh code and the scrambling code; An interference reproducing unit configured to calculate an interference signal by another user and an interference signal by a multipath included in the respread signal; And An interference signal removing unit for removing the calculated interference signal from the output signal of the rake receiver; Adaptive multi-stage partial parallel interference canceller comprising a. delete The method of claim 9, The soft decision unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the soft decision based on the following equation (4). (Equation 4)

Where ω is the slope and U is the input signal. The method of claim 11, And the weight controller controls slope ω based on an LMS algorithm. The method of claim 11, And the weight controller controls slope ω based on a mean / dispersion ratio algorithm. The method according to any one of claims 11 to 13, And the interference reproducing unit calculates an interference signal (IPI) based on Equation 5 below. (Equation 5)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, lTc and mTc are the multipath delay times. The method of claim 14, The interference regeneration unit further calculates a compensation signal IPS based on Equation 6 below. The interference canceller of each stage further comprises a compensation signal adder for adding the compensation signal (IPS) to the received signal from which the interference signal has been removed. (Equation 6)

Where R _j is the diffusion gain. The method of claim 9, The interference canceller of each stage Further comprising a deinterleaver / decoder section and an interleaver / encoder section in front of the respreading section, Adaptive multi-stage partial parallel interference canceller characterized in that for correcting the error of the signal through the deinterleaver / decoder unit, and interleaving and encoding the signal again through the interleaver / encoder unit. An interference canceller included in a downlink receiver composed of a plurality of channels and removing interference signals by other users and interference signals by multipath, A normalizer for normalizing the output signal of the rake receiver to the sum of squares of tap gains of each path; A first memory unit which stores the normalized signal; A second memory unit for storing each channel Walsh code, a scrambling code, and a strength of a received signal of each channel; A fourth memory unit for storing the multipath tap gains of the rake receiver; An interference reproducing unit configured to calculate an interference signal IPI and a compensation signal IPS based on Equation 7 using tap gains stored in the fourth memory; An interference signal removing unit for removing an interference signal (IPI) calculated by the interference reproducing unit from a normalized signal stored in a first memory; A third memory unit which stores an output signal of the interference signal removing unit; A compensation signal adding unit which adds a compensation signal IPS stored in the interference reproducing unit from a signal stored in the third memory unit; And A signal processor for sequentially re-spreading the signal using matched filtering, weight control, soft decision, and the value of the second memory with respect to the output signal of the compensation signal adder The output signal of the signal processing unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the feedback structure is input to the interference regeneration unit. (Equation 7)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, lTc, mTc is the multipath delay time, and R _j is the spreading gain. The method of claim 17, And the signal processing unit makes soft decision based on Equation (8). (Equation 8)

Where ω is the slope and U is the input signal. The method of claim 18, And the weight controller controls slope ω based on an LMS algorithm. The method of claim 18 And the weight controller controls slope ω based on an average / dispersion ratio algorithm. It is included in the uplink receiver composed of a multi-channel interference canceller composed of a multi-stage parallel structure to remove interference signals by other users and interference signals by multipath, Each stage interference canceller A normalizer for normalizing the output signal of the rake receiver to the sum of squares of the path tap gains of the rake receiver; A matching filter unit matching a signal of each channel component with respect to an input signal using the normalization unit output signal; A soft decision unit having a monotonically increasing slope and soft decision of a matched signal; A weight control unit controlling the slope of the soft decision unit in front of the soft decision unit; A respreading unit for respreading the soft decision signal using the Walsh code and the scrambling code; An interference reproducing unit configured to calculate an interference signal by another user and an interference signal by a multipath included in the respread signal; And An interference signal removing unit for removing the calculated interference signal from the output signal of the rake receiver; Adaptive multi-stage partial parallel interference canceller comprising a. delete The method of claim 21, The soft decision unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the soft decision based on the following equation (9). (9)

Where ω is the slope and U is the input signal. The method of claim 23, wherein And the weight controller controls slope ω based on an LMS algorithm. The method of claim 23, wherein And the weight controller controls slope ω based on an average / dispersion ratio algorithm. The method according to any one of claims 23 to 25, The interference reproducing unit is based on the following equation 10

Adaptive multi-stage partial parallel interference canceller, characterized in that for calculating. (Equation 10)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, R _j is the spreading gain, lTc, mTc is the multipath delay time. The method of claim 26, The interference canceller of each stage Further comprising a deinterleaver / decoder section and an interleaver / encoder section in front of the respreading section, Adaptive multi-stage partial parallel interference canceller, characterized in that for correcting the error of the signal through the deinterleaver / decoder unit, and interleaving and encoding the signal again through the interleaver / encoder. An interference canceller included in a multi-channel uplink receiver and removing interference signals by other users and interference signals by multipath, A normalizer for normalizing the output signal of the rake receiver to the sum of squares of tap gains of each path; A first memory unit which stores the normalized signal; A second memory unit for storing each channel Walsh code, a scrambling code, and a strength of a received signal of each channel; A fourth memory unit for storing the multipath tap gains of the rake receiver; An interference reproducing unit configured to calculate an interference signal (I) by using Equation 11 below using tap gain stored in the fourth memory; An interference signal removing unit for removing the interference signal I calculated by the interference reproducing unit from the normalized signal stored in the first memory; A third memory unit for storing an output signal of the interference signal canceller; And a signal processor for sequentially re-spreading the signal stored in the third memory unit using matched filtering, weight control, soft decision, and the value of the second memory. The output signal of the signal processing unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the feedback structure is input to the interference regeneration unit. (Equation 11)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, R _j is the spreading gain, lTc, mTc is the multipath delay time. The method of claim 28, And the signal processing unit makes soft decision based on Equation 12 below. (Equation 12)

Where ω is the slope and U is the input signal. The method of claim 29, And the weight controller controls slope ω based on an LMS algorithm. The method of claim 29 And the weight controller controls slope ω based on an average / dispersion ratio algorithm. It is included in the uplink receiver composed of a multi-channel interference canceller composed of a multi-stage parallel structure to remove interference signals by other users and interference signals by multipath, Each stage interference canceller A soft decision unit for softly determining an input signal with a monotonically increasing slope; A weight control unit controlling the slope of the soft decision unit in front of the soft decision unit; A respreading unit for respreading the soft decision signal using the Walsh code and the scrambling code; An interference reproducing unit configured to calculate an interference signal by another user and an interference signal by a multipath included in the respread signal; A normalizer for normalizing the output signal of the rake receiver to the sum of squares of the path tap gains of the rake receiver; A matched filter unit for matching the output signal of the rake receiver with the signal of each channel component using the normalizer output signal; And An interference signal removal unit for removing the calculated interference signal from the matched signal; Adaptive multi-stage partial parallel interference canceller comprising a. delete The method of claim 32, The soft decision unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the soft decision based on the following equation (13). (Equation 13)

Where ω is the slope and U is the input signal. The method of claim 34, wherein And the weight controller controls slope ω based on an LMS algorithm. The method of claim 34, wherein And the weight controller controls slope ω based on an average / dispersion ratio algorithm. The method according to any one of claims 34 to 36, The interference reproducing unit is an interference signal based on Equation 14 below.

Adaptive multi-stage partial parallel interference canceller, characterized in that for calculating. (Equation 14)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, R _j is the spreading gain, lTc, mTc is the multipath delay time. The method of claim 37, The interference canceller of each stage Further comprising a deinterleaver / decoder section and an interleaver / encoder section in front of the respreading section, Adaptive multi-stage partial parallel interference canceller, characterized in that for correcting the error of the signal through the deinterleaver / decoder unit, and interleaving and encoding the signal again through the interleaver / encoder. An interference canceller included in a multi-channel uplink receiver and removing interference signals by other users and interference signals by multipath, A normalizer for normalizing the output signal of the rake receiver to the sum of squares of tap gains of each path; A matching filter unit matching each channel component from the normalized signal; A first memory unit which stores the matched signal; A second memory unit for storing each channel Walsh code, a scrambling code, and a strength of a received signal of each channel; A fourth memory unit for storing the multipath tap gains of the rake receiver; By using the tap gain stored in the fourth memory, the interference signal

An interference regeneration unit for calculating); The interference signal calculated by the interference reproducing unit from the matched signal stored in the first memory (

Interference signal removal unit for removing; A third memory unit for storing an output signal of the interference signal canceller; A signal processor for sequentially respreading a signal using weight control, soft decision, and a value of the second memory with respect to the signal stored in the third memory unit; The output signal of the signal processing unit is an adaptive multi-stage partial parallel interference canceller, characterized in that the feedback structure is input to the interference regeneration unit. (Equation 15)

Where a (t), b (t) and c (t) are tap gains for each path of the rake receiver, z (t) is the re-spread signal, 1 / Tc Is the chip rate, R _j is the spreading gain, lTc, mTc is the multipath delay time. The method of claim 39, And the signal processor determines soft decision based on Equation (16) below. (Equation 16)

Where ω is the slope and U is the input signal. The method of claim 40, And the weight controller controls slope ω based on an LMS algorithm. 41. The method of claim 40 And the weight controller controls slope ω based on an average / dispersion ratio algorithm.

Images