KR100266445B1 - A transmission diversity embodiment method and device for hybrid wideband-cdma as multi-carrier/direct sequence of telecommunication system - Google Patents

Abstract

PURPOSE: A method and a device for implementing transmission diversity of a communication system in MC/DS(Multi-Carrier/Direct Sequence) hybrid W-CDMA(Wideband-Code Division Multiple Access) are provided to use a Walsh code as an orthogonal code, if a ratio of a symbol transmission speed to a chip transmission speed of a parallel data sequence satisfies a ratio of one-to-2k, so as to increase processing gains per carrier and increase the number of available orthogonal codes. CONSTITUTION: A serial-to-parallel converter(1) converts an encoded and interleaved data sequence into at least two parallel sequence signals. A diffusion circuit(2) diffuses each parallel sequence signal to at least two diffusion codes. A summing circuit(8) sums optional diffusion signals corresponding to mutually different parallel sequence signals among the diffusion signals. A modulation circuit(3) modulates the summed signals with mutually different frequencies of sub-carriers. And a transmission antenna(9) transmits the modulated signals.

Description

Method and apparatus for realizing transmission diversity in multicarrier / direct sequence hybrid broadband CDMA communication system

The present invention relates to a method and apparatus for implementing transmission diversity in a multicarrier / direct sequence hybrid broadband CDMA communication system, and more particularly, to a multi-carrier capable of future high-speed multimedia service under a wireless channel. Transceiver Design Technique for Maximizing Frequency Diversity Effect in Hybrid Wideband Code Division Multiple Access (hereinafter referred to as "MC / DS Hybrid W-CDMA") Combination Method and Direct Sequence Method It is to provide.

In general, broadband CDMA (hereinafter referred to as "W-CDMA"), which is being developed in various countries of the world, is a ground-based wireless multiple access technology of the next generation mobile communication system ("IMT-2000"). There are two broad categories: base station synchronous W-CDMA based on North America and base station asynchronous W-CDMA developed in Japan and Europe. Digital cellular mobile phones and PCS (Personal Communication Services) systems currently commercially available in Korea are second generation systems and are based on narrowband CDMA (hereinafter referred to as IS-95), a standard of the US TIA / EIA (Telecommunication Industry Association / Electronic Industries Association). &Quot; N-CDMA " The fundamental difference between the W-CDMA scheme for IMT-2000 and the existing N-CDMA scheme is the difference in bandwidth. That is, the N-CDMA scheme has a spread bandwidth of 1.25 MHz, whereas the W-CDMA scheme has a bandwidth of 5 MHz or more. In addition, the N-CDMA scheme is designed for voice communication, so the maximum data rate is very limited to 9600 (or 14400) bits per second, but the W-CDMA scheme provides transmission speeds of millions of bits per second or more.

In addition, the W-CDMA forward link channel, which is being developed based on North America as a wireless transmission technology for IMT-2000, has two types. The first is a pure direct sequence DS W-CDMA method. The MC / DS hybrid W-CDMA method combines a multicarrier method and a direct sequence method. The reason why the North American scheme considers the MC / DS hybrid scheme as well as the pure DS spread spectrum scheme in the forward link is to consider backward compatibility with the existing IS-95 N-CDMA system.

In other words, the North American MC / DS hybrid W-CDMA system presupposes the use of frequency overlap with the existing N-CDMA system in the 800 MHz band and the 1.7-1.8 GHz band in the cellular band as well as the 2 GHz band in the IMT-2000 frequency band. Doing.

In general, multipath causes severe fading in narrowband modulation systems, such as the analog FM modulation scheme used in first generation cellular telephone systems. However, in the CDMA modulation scheme, since signals through different paths are independently received, the severity of the multipath fading problem can be somewhat solved. Nevertheless, in this method, a multipath phenomenon that cannot be independently processed by the demodulator occurs and the fading phenomenon is still a serious problem because the multipath fading is not completely eliminated. Three methods are known: temporal diversity (using interleaving and error correction), frequency diversity, and spatial / path diversity. The present invention focuses on a design technique of a transceiver for implementing transmission diversity in a multicarrier / direct sequence hybrid broadband CDMA communication system.

First, referring to the power spectrum of the signal according to the W-CDMA scheme, FIG. 1 shows a power spectrum of a base station antenna output signal of a pure DS W-CDMA scheme having a bandwidth of 5 MHz (including a guard band), and FIG. The power spectrum of the antenna output signal of the hybrid W-CDMA system is shown.

Here, considering the current state of Korea's second-generation digital mobile communication that uses IS-95 N-CDMA as the standard for digital cellular and PCS, MC / DS hybrid W-CDMA is considered to be compatible with N-CDMA. It can be called a third generation mobile communication system suitable for the domestic situation.

The conventional frequency diversity method for the MC / DS hybrid CDMA scheme is illustrated in FIG. 3. As shown, the encoded and interleaved symbol data sequence (transmission rate Rs) is branched to N branches having the same transmission rate and spread, and then modulated to each carrier and transmitted. However, in this case, if the chip rate ratio of the code rate of the encoded and interleaved symbol (R _S ) to the spread code (C) does not satisfy 1: 2 ^K (where K is a natural number), the Walsh code is used as the spreading code. Orthogonal code such as cannot be used. Moreover, this in such a way transmission rate of the symbols (R _S) chip data rate of large spreading code ratio of 1: due to satisfy the condition of 2 ^K to the availability of an orthogonal code is also no change in the processing gain (processing gain) There is a problem that the number of orthogonal codes available per carrier must be very limited.

4 is another conventional transmitter basic concept diagram of the MC / DS hybrid W-CDMA scheme. The serial-to-parallel converter 1 converts a coded or interleaved data symbol sequence (symbol transmission rate = R) in parallel. The converted N data symbol sequences (transmission rate = R / N) are Walsh codes (W _A , W _B , .., W _N ) for distinguishing channels from other channels in the same carrier. It spreads to orthogonal codes such as (2). Here, the Walsh codes W _A , W _B , ..., W _N are orthogonal codes and may be the same code or different codes.

As described above, each of the N signals spread by the orthogonal code is RF-modulated to a corresponding carrier frequency (COS (2πf _A t), COS (2πf _B t) ... COS (2πf _N t)).

On the other hand, IMT-2000 wireless transmission multiple access candidate technology, which is an application example of MC / DS hybrid CDMA in the above-described hybrid transmitter, is proposed by a North American company based on Qualcomm. As shown in Fig. 5, the N data sequences serially converted by the serial-to-parallel converter 1 are each quaternary phase modulated (QPSK) (4), and the phase modulation ( 4) The data sequence is first spread by the orthogonal codes W _A , W _B , .., W _N (2) and then second spread (5) by the pilot PN sequence. The second spread (5) signal is then filtered through the baseband filter (6) and the corresponding carriers (COS (2πf _A t), COS (2πf _B t) ... COS (2πf _N t), SIN (2πf _A t), SIN (2πf _B t) ... SIN (2πf _N t)) is RF modulated (3). This RF modulated signal 3 is amplified and transmitted over the radio channel via an antenna.

However, such a conventional MC / DS hybrid CDMA system degrades the receiver performance somewhat in a multipath fading channel environment, and also requires a lot of transmission power because the performance of the receiver is further reduced when the frequency is overlapped with the existing N-CDMA scheme. By doing so, there is a problem in that the capacity of the entire communication system is reduced due to the CDMA characteristics in which the system capacity is determined by interference of other users.

On the other hand, the present invention has been made to solve the above problems, and is a technique for implementing transmission diversity in the MC / DS hybrid W-CDMA scheme as shown in FIG. 2 suitable for a domestic communication environment. After serial-to-parallel conversion of the interleaved data sequence, each converted parallel data sequence is spread with two or more arbitrary codes, and then modulated and transmitted by two or more carriers at the same time. On the receiving side, a signal received from two or more carriers is reversed. Demodulation is performed using the Maximum Ratio Combining method to perform parallel-to-serial conversion and to deinterleave or decode the converted data. Symbol transmission rates of even does not satisfy the condition of 2 ^K of the serial-to-parallel converted parallel data sequence (Rs: The present invention overcomes the problems of the prior art and the ratio of the symbol rate and the chip transmission rate 1 as in the example of Fig. 3 / N) and the chip transmission speed ratio of 1: 2 ^K , orthogonal code such as Walsh code can be used as a spreading code, while increasing the processing gain per carrier (channel capacity) Is to increase. In addition, the IS-95 narrowband CDMA scheme and hybrid W-CDMA are commercially available, as well as greatly improving the performance of the MC / DS hybrid W-CDMA receiver in a wireless fading channel environment. SUMMARY OF THE INVENTION An object of the present invention is to provide a transmission diversity implementation method and apparatus for a multicarrier / direct sequence hybrid wideband CDMA scheme in which interference to an IS-95 narrowband CDMA receiver is minimized when frequency overlapping is used.

In order to achieve the above object, the present invention provides a method for serially converting a coded or interleaved data sequence into at least two parallel sequence signals in a multicarrier / direct sequence hybrid broadband CDMA communication system, and converting each of the converted data sequence signals. Spreading at least two spreading codes, summing any spreading signals corresponding to the different parallel sequence signals among the spreading signals, and modulating each of the summing signals with a carrier having a different frequency. The spreading signals added together in the summing step are spread to different spreading codes. In addition, the receiving side receives signals spread and spread with different spreading codes, demodulates them by respective carriers, performs correlation with each spreading code, despreads them, and then applies them to each of the same parallel sequence signals. The maximum decoupling (MRC) method is applied to the corresponding despread signals so that the original signal is restored and subjected to a process of parallel-to-serial conversion, decoding, or deinterleaving.

1 is a frequency spectrum of a direct sequence W-CDMA signal having a transmission bandwidth of 5 MHz.

2 is a frequency spectrum of a multicarrier / direct sequence hybrid W-CDMA signal having a transmission bandwidth of 5 MHz.

3 is a diagram illustrating a conventionally proposed method of implementing frequency diversity.

4 is a basic conceptual diagram of a conventional MC / DS hybrid W-CDMA transmitter.

5 is a structural diagram of a conventional MC / DS hybrid W-CDMA transmitter proposed as an IMT-2000 wireless transmission technique.

6 is an exemplary diagram illustrating a basic concept of a transmitter according to the present invention for transmitting the same parallel data on two or more carrier frequencies (when N is 3).

7 is an illustration showing the basic concept of a transmitter according to the present invention spaced so that each carrier frequency transmitting the same data when N is 6 is subject to maximum independent fading.

8 is an embodiment of the present invention for transmitting data through two transmit antennas when diversity branch is 2 and N is 3. FIG.

9 is another embodiment of the present invention for transmitting data through two transmit antennas when diversity branch is 2 and N is 6. FIG.

10 is a conceptual diagram illustrating a method of applying the present invention to a conventional MC / DS hybrid W-CDMA transmitter proposed by IMT-2000 wireless transmission technology.

11 is an exemplary configuration diagram of a receiver of the present invention for performing maximum uncoupled diversity for each of parallel data.

<Description of the code | symbol about the principal part of drawing>

1: serial and parallel conversion means 2: diffusion means

3: modulation means 4: quaternary phase modulation means

8: summation means 9: transmission antenna

10: reception antenna 11: down converter

12 correlator 13 maximum non-coupler

14: parallel serial conversion means 15: deinterleaver / encoder

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the drawings according to the embodiment of the present invention for the components having the same or similar functions are used the same reference numerals to facilitate the understanding of the invention.

FIG. 6 shows a transmission apparatus which is an embodiment of the present invention when the number of carriers used is 3 (N = 3), the configuration of which is serial-to-parallel for serial-to-parallel conversion of a predetermined data sequence. parallel means of the conversion means 1, spreading means 2 for spreading the parallel data sequence converted by the parallel-parallel conversion means 1 into two or more orthogonal codes, and a signal spread by the spreading means. A summation means (8) for summing arbitrary spreading signals corresponding to different parallel sequence signals, modulation means (3) for modulating each of the signals summed by the summation means (8) at different frequencies; The transmission antenna 9 transmits a signal modulated by the modulating means 3 on the radio channel.

Here, spread signals transmitted on different carriers may be spread with the same orthogonal code, but spread signals transmitted on the same carrier should be spread with different orthogonal codes. For example, the orthogonal codes W _A1 and W _B2 in the spreading means 2 may be the same code or different codes, but W _A1 and W _A2 must be different codes.

Meanwhile, referring to a transmission operation for the MC / DS hybrid wideband CDMA scheme configured as described above, three parallel sequence signals P1, P2, and P3 are first encoded or interleaved by the serial-to-parallel conversion means 1. Are converted to. The converted parallel data sequences P1, P2, and P3 are input to the respective spreading means 2 so that one parallel data sequence P1 is spread by the orthogonal codes W _A1 and W _B2 so that two spread signals are spread. (P11, P12) in the other parallel data sequence (P2) is spread by an orthogonal code, W _B1 and W _C2 of two spread signals (P21, P22) with another parallel data sequence (P3) is W _C1 and Spread by an orthogonal code W _A2 and converted into two spread signals P31 and P32, respectively.

Further, spreading signals corresponding to different parallel sequences are summed in the summing means 8, and the signal spread by the orthogonal code W _A1 and the spread signal by the orthogonal code W _A2 in FIG. 6 are added to the summing means 8a. The signal spread by the orthogonal code W _B1 and the signal spread by the orthogonal code W _B2 are summed by the summation means 8b and the signal spread by the orthogonal code W _C1 and the orthogonal code W _C2 . The signals spread by are added up by the summing means 8c, respectively.

As described above, the signals summed up by the summation means 8a, 8b, and 8c are inputted to the respective modulation means 3, so that the respective carriers (COS (2πf _A t), COS (2πf _B t), COS (2πf) _C t)), which are summed and transmitted by the transmitting antenna 9 on the radio channel.

Here, in the summing means 8 and the modulating means 3 for modulating the summed signal, the carrier frequencies of the spread signals corresponding to the same parallel data sequence are preferably summed or modulated so as to be spaced apart from each other as much as possible. This is to receive independent fading by ensuring that the center frequencies of different carriers carrying the same data sequence are spaced apart as much as possible. The receiver of the present invention, which will be described later, recovers original data by maximizing the maximum ratio combining of the outputs of the correlators of each signal when demodulating a signal including two or more pieces of identical data information. Maximum performance when received independent fading through.

7 shows an example of realizing this, in which two carriers carrying the same parallel sequence are converted into six parallel data sequences and the same parallel sequence is received when the diversity branch for each parallel sequence is two. The transmission diversity method is shown. That is, the embodiment of FIG. 7 is configured to convert the input data sequence in parallel to 1: 6 and uses six carriers, and its transmission operation is the same as that of the embodiment of FIG. 6.

On the other hand, while the foregoing invention has been described as basically using one transmit antenna, it can be combined with a spatial (antenna) diversity method using two or more antennas in order to receive maximum independent fading between each carrier. This is as shown in FIGS. 8 and 9. That is, the effects of spatial diversity can also be obtained by transmitting the modulation signals in FIGS. 6 and 7 having the diversity branch of 2 and the data sequence of 3 or 6, respectively, through the two antennas 9a and 9b.

In addition, the MC / DS hybrid W-CDMA forward (C / DS hybrid W-CDMA forward) proposed by a North American company centered on Qualcomm, which is an IMT-2000 wireless transmission multiple access candidate technology, is a method for transmitting diversity for MC / DS hybrid CDMA according to the present invention. An embodiment applied to a mobile station) channel structure in a base station is shown in FIG. That is, the three parallel data sequences, which are serially and serially converted by the serial-to-parallel conversion means 1, are each phase-modulated by a quaternary phase shift keying method (QPSK) (4), and the phase-modulated data sequences are first-order spreading means. By (2), each is spread by two or more orthogonal codes. The first spread signal is input to the second spreading means 5 to second spread by the pilot PN sequence. The second-order spread signals are filtered through the baseband filter 6, and the filtered signals are RF-modulated by a carrier having two different frequencies by summing by the summing means 8 and the modulating means 3. It is transmitted on the radio channel through one or more transmitting antennas.

Since the MC / DS hybrid W-CDMA scheme can reduce the transmission power by increasing the reception performance of the receiver and has excellent narrowband interference cancellation capability, the N / CDMA (IS-95) scheme overlaps with the frequency. In addition, the interference to the N-CDMA (IS-95) receiving end can be minimized without affecting the capacity of the system. In this case, the transmission signal of the N-CDMA (IS-95) can be added to the summation means of FIG. In 8) it may be added to the transmission signal of the MC / DS hybrid W-CDMA scheme.

In the multicarrier / direct sequence hybrid broadband CDMA communication system as described above, a receiving side for implementing transmit diversity performs down-conversion and demodulation of a transmission signal input through the receiving antenna 10 as shown in FIG. A correlator 12 which correlates the down-converter 11 and three baseband signals down-converted by the down-converter 11 to respective orthogonal codes identical to those of the transmitting side. And a maximum ratio of combining the corresponding despread signals by the same parallel sequence signal among the signals despread by the correlator 12 and restoring the original signal by a known maximum ratio combining method. Combiner 13, parallel-to-parallel converter 14 for serially converting a predetermined number of parallel data sequences restored by this maximum non-combiner 13, and this parallel-to-parallel converter 14 It consists of a sequence of data converted to series by the decoding or deinterleaving the deinterleaver / decoder 15 to.

That is, in this configuration, the signal transmitted from the transmitting side on the radio channel is received through the receiving antenna 10 and the received signal is input to each down converter 11. Therefore, the down converter 11 removes the carrier included in the original data sequence and inputs it to the correlator 12 including two or more orthogonal codes. The correlator 12 then correlates the input parallel data sequence by two or more orthogonal codes used at the transmitting side, where the Walsh code, which is the orthogonal code at the receiving side, is different from the Walsh code used at the transmitting side. The same is true, W _A1 and W _A2 , W _B1 and W _B2 , W _C1 and W _C2 are different codes.

The data sequence correlated by the correlator 12 is inputted to the corresponding maximum non-combiner 13, and as the maximum non-combination (MRC) is performed, the original signal is restored. That is, the data sequences S1 and S4 correlated by the orthogonal codes W _A1 and W _B2 are transmitted to the first maximum non-combiner 13a and the data sequences S3 correlated by the orthogonal codes W _B1 and W _C2 , respectively. S6 is transmitted to the second maximum non-combiner 13b, and the data sequences S2 and S5 correlated by the orthogonal codes W _A2 and W _C1 are transmitted to the third maximum non-combiner 13c, respectively. Restore the original data by the combining method. Accordingly, the plurality of parallel data sequences restored through the maximum non-combiner 13 are converted into a serial data sequence by being input to the parallel-serial converter 14, and the converted data sequences are input to the deinterleaver / decoder 15. By deinterleaving or decoding, the original data is finally recovered.

In another embodiment, a known equal gain combining method may be used instead of the MRC method.

As described above, according to the present invention, whether or not the possibility of using an orthogonal code such as a Walsh function as a spreading code is not completely dependent on the transmission rate (Rs) of the symbol, and the symbol transmission rate (Rs / N) of the parallel data sequence converted in parallel and parallel conversion. Chip rate is 1: 2 ^k , the orthogonal code can be used as a spreading code, and N carrier rates are reduced to Rs / N, respectively, increasing the processing gain per carrier and increasing Orthogonal code can be accommodated to increase the subscriber's capacity. Furthermore, the MC / DS hybrid W-CDMA receiver has better reception performance, which minimizes the transmission power and provides excellent narrowband interference cancellation. Even when the frequency is overlapped with the CDMA (IS-95) method, even if the interference to the N-CDMA (IS-95) receiver is minimized while maintaining the maximum capacity of the entire system. The MC / DS-CDMA transmission stage hybrid W can be obtained the effect that makes it possible to realize an advanced frequency diversity.

Claims (10)

A method for implementing transmission diversity in a multicarrier / direct sequence hybrid wideband CDMA communication system, a) serial-to-parallel converting the encoded or interleaved data sequence into at least two parallel sequence signals; b) spreading each of the parallel sequence signals with at least two spreading codes; c) summing any spreading signals corresponding to the different parallel sequence signals among the spreading signals, respectively; d) modulating each of the sum signals with a carrier of a different frequency; And e) transmitting said modulated signal, The spreading signals summed together in the summing step (c) are spread with different spreading codes. The method of claim 1, f) receiving the transmission signals; g) demodulating the received signals by respective carriers; h) despreading the demodulated signals by performing correlation with each spreading code; i) restoring an original signal by applying a maximum non-coupling (MRC) method to despread signals corresponding to each of the same parallel sequence signals among the despread signals; And j) parallel decoding the decoded signals to decode or deinterleave the method. The method of claim 1, And all or part of the spreading codes for the same parallel sequence signal in the signal spreading step (step b) are the same. The method of claim 1, The carrier diver of the spreading signals corresponding to the same parallel sequence signal in the summing step (c) and the summing step (d) of the spread signal are summed and modulated so as to be spaced apart from each other as much as possible. How to implement a city. The method of claim 1, The modulation step (d step) is performed by a quaternary phase shift keying (QPSK) scheme, and the signal spreading step (b step) includes (i) a first-order spreading step using an orthogonal code; And (ii) a second spreading step by a pilot PN sequence. The method of claim 1, And transmitting the modulated signal (step e) transmits the modulated signals through at least two antennas. The method according to claim 1 or 2, A method of implementing transmit diversity, wherein the frequency is overlapped with an existing narrowband CDMA (IS-95 A / B) system. A transmission apparatus for implementing transmission diversity in a multicarrier / direct sequence hybrid wideband CDMA communication system, a) means for serial-to-parallel converting the encoded or interleaved data sequence into at least two parallel sequence signals; b) means for spreading each of said parallel sequence signals with at least two spreading codes; c) means for summing any spreading signals corresponding to the different parallel sequence signals of the spreading signals, respectively; d) means for modulating each of said sum signals with a carrier of a different frequency; And e) means for transmitting said modulated signal, The spreading signals summed together by the summing means (c means) are spread with different spreading codes. A receiver for implementing transmit diversity in a multicarrier / direct sequence hybrid wideband CDMA communication system, a) means for receiving the transmission signals according to claim 1; b) means for demodulating the received signals by respective carriers; c) means for despreading the demodulated signals by performing correlation with each spreading code; d) means for restoring an original signal by applying a maximum non-combination (MRC) method to despread signals corresponding to each of the same parallel sequence signals among the despread signals; And e) means for parallel-to-serial converting the decoded signals for decoding or deinterleaving. A CDMA communication system using a method for implementing transmit diversity according to claim 1 or 2.