JP5163351B2 - OFDM signal transmission method, OFDM transmitter, and OFDM receiver - Google Patents

Description

  The present invention relates to an OFDM signal transmission method, an OFDM transmitter, and an OFDM receiver, and more particularly, an OFDM signal transmission method, an OFDM transmitter, and an OFDM signal transmission method capable of transmitting and receiving an orthogonal frequency division multiplexed signal (OFDM signal). And relates to an OFDM receiver.

  In recent years, the macro pilot diversity which obtains a required gain (gain) by transmitting the same pilot channel signal and data channel signal from a plurality of different OFDM transmitters at the same carrier frequency and combining them with the OFDM receiver. Reception techniques are known.

  Non-Patent Document 1 describes a technique related to MBS (Multicast and Broadcast Services), and defines a communication method for broadcasting common information to a plurality of OFDM receivers. According to the communication method proposed in Non-Patent Document 1, by transmitting a common pilot channel signal and a common data channel signal using a common frequency resource to a plurality of OFDM receivers, Compared with the method of allocating frequency resources individually, it is possible to effectively use resources.

  Non-Patent Document 1 further defines macro diversity as a method for improving MBS performance. The macro diversity defined in Non-Patent Document 1 is that a plurality of OFDM transmitters transmit a common pilot channel signal and data channel signal with the same frequency resource and time resource after time-synchronizing a plurality of OFDM transmitters. By doing so, the macro diversity reception in the OFDM receiver (mobile device) is enabled. Thereby, the reception error rate of the OFDM receiver can be improved in the vicinity of the cover area boundary between the OFDM transmitters. In Orthogonal Frequency Division Multiplexing (OFDM), multiple transmit signals from multiple OFDM transmitters that arrive within the guard interval interval can be easily multipath combined as desired signal power, so macro diversity is This is a particularly effective method.

  Further, in Patent Document 1, a subcarrier group including a plurality of subcarriers is set, and a pilot channel signal and a data channel signal allocated to subcarriers in the subcarrier group are determined for each subcarrier group. A technique for generating and transmitting an OFDM signal by performing OFDM modulation after multiplying by a complex value is disclosed. The technique disclosed in Patent Document 1 is a technique for a multicast (or broadcast) service in which an OFDM receiver performs macro diversity reception. According to the technique disclosed in Patent Document 1, when the OFDM receiver performs macro diversity reception on the OFDM receiver side as compared with a communication scheme in which each OFDM transmitter simply transmits a common pilot channel signal and a common data channel signal. Therefore, it is possible to reduce the amount of calculation, to reduce degradation of channel estimation accuracy due to interference, and to simplify control.

Further, the technique disclosed in Patent Document 1 has two further effects. First, since the transmission path can be decorrelated between the set subcarrier groups, an additional diversity gain can be obtained. Second, by using the complex value of the scrambling code applied to orthogonalize or pseudo-orthogonalize the pilot channel signal for each OFDM transmitter as the complex value to be multiplied for each subcarrier group, The pilot channel signal used for channel estimation is reestablished for channel estimation of the data channel signal during unicast reception (when macro diversity reception is not performed), or for timing synchronization and frequency synchronization between each OFDM transmitter and OFDM receiver. Can be used.
JP 2007-189646 A LAN MAN Standards Committee of the IEEE Computer Society, ANSI / IEEE Std 802.16e-2005

  However, in the technique disclosed in Patent Document 1, not only when performing macro diversity reception, but also a pilot channel signal that can be used for channel estimation of a data channel signal at the time of unicast reception is a subcarrier group. There is one principle for each. In general, pilot channel data and data channel signals for unicast reception are subjected to different scrambling codes for each symbol for the purpose of randomizing inter-transmitter interference, and have the same phase for each subcarrier group. This is because a plurality of pilot channel signals cannot be secured. Therefore, with the technique disclosed in Patent Document 1, there is a possibility that sufficient channel estimation accuracy cannot be obtained in an environment where the signal-to-noise ratio (SN ratio) is poor. Of course, in order to solve this, a method of arranging a simple copy of the pilot channel signal and performing channel estimation using a plurality of pilot channel signals is also conceivable, but this method is used for channel estimation of a macro diversity reception signal. Although the power of the pilot channel signal that can be increased increases, it is difficult to use the copied pilot channel signal for the purpose of channel estimation of the unicast reception signal. That is, in this case, in order to use a copy of the pilot channel signal as a unicast pilot, a scrambling code to be applied to the copy source pilot channel signal is held and held in the copied pilot channel signal. A scrambling code to be applied to the copied pilot channel signal must be applied, not only to generate a different scrambling code for each symbol, but also to hold a scrambling code to be applied to the copied pilot channel signal. Don't be. Furthermore, even if the pilot channel signal of the copy can be used for channel estimation of the unicast reception signal by this method, the interference between the transmitters of the pilot channel signal is not taken into consideration, so that the interference between the transmitters is biased. In some cases, it is not possible to obtain stable unicast signal reception quality. Japanese Patent Application Laid-Open No. H10-228867 has not suggested anything about this problem.

  The present invention has been made in view of such a situation, and a plurality of multipliers to be multiplied by the same scrambling code arranged in the same subcarrier group while randomizing the inter-transmitter interference of pilot channel signals. In addition to improving the channel estimation accuracy of macro diversity reception suitably using the pilot subcarriers of the sub-carrier, the channel estimation accuracy of unicast reception can be improved when the macro diversity reception signal and the unicast reception signal are close to each other. A first object of the present invention is to provide an OFDM signal transmission method, an OFDM transmitter, and an OFDM receiver that can be preferably improved.

  Further, the present invention can easily create a copy of a pilot channel signal by using a data channel signal multiplied by the same scrambling code as a pilot subcarrier arranged in the same subcarrier group. A second object of the present invention is to provide an OFDM signal transmission method, an OFDM transmitter, and an OFDM receiver that can improve channel estimation accuracy as needed using a copy of a pilot channel signal.

  In order to solve the above-described problem, an OFDM signal transmission method according to the present invention modulates a bit string obtained by channel coding in a OFDM signal transmission method in which OFDM signals are transmitted from a plurality of transmitters. A data channel signal generation step for generating a signal, a pilot channel signal generation step for generating a pilot channel signal, a data channel signal generated by the processing of the data channel signal generation step, and a pilot generated by the pilot channel signal generation step An allocation step of allocating channel signals to the same pilot subcarrier and data subcarrier among a plurality of transmitters, a first pilot subcarrier, and a scrambling code identical to the first pilot subcarrier are multiplied by k. Shin The second pilot subcarrier located at a distance of n * k subcarriers after the first, the first pilot subcarrier, and the second pilot subcarrier are multiplied in time and frequency by the same scrambling code. A subcarrier group setting step for setting at least one subcarrier group including one or a plurality of data subcarriers, and n for each symbol with respect to a pilot channel signal and a data channel signal allocated to the pilot subcarrier and the data subcarrier. The scrambling code shifted by the index is multiplied, and the same subcarrier group is set for the first data channel signal and the pilot channel signal for which the subcarrier group is set by the subcarrier group setting step. While the same scrambling code is multiplied between a plurality of transmitters for which a carrier group has been set, a second data channel signal for which no subcarrier group has been set by the subcarrier group setting step among the data channel signals. On the other hand, a scrambling step of multiplying each transmitter by a scrambling code unique to an orthogonal or pseudo-orthogonal predetermined transmitter, and a complex value for each subcarrier group, the pilot channel signal and the first channel A complex data multiplication step for multiplying the data channel signal and a second data channel obtained by multiplying each transmitter by a scrambling code specific to a predetermined orthogonal or quasi-orthogonal transmitter by processing of the scrambling step Signal and complex value multiplication step OFDM signal generation step for generating an OFDM signal by performing OFDM modulation on the pilot channel signal and the first data channel signal multiplied by the complex value according to, and receiving the OFDM signal generated by the processing of the OFDM signal generation step Transmitting to the machine via one or more antennas.

  In order to solve the above-described problem, an OFDM transmitter according to the present invention includes a data channel signal generating unit that generates a data channel signal by modulating a bit string obtained by channel coding, and a pilot channel that generates a pilot channel signal. The signal generation means, the data channel signal generated by the data channel signal generation means, and the pilot channel signal generated by the pilot channel signal generation means are converted into the same pilot subcarrier and data subcarrier among a plurality of OFDM transmitters. Allocating means for allocating; a first pilot subcarrier; a second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the first pilot subcarrier; First pilot subcarrier Subcarrier group setting means for setting at least one subcarrier group including one or a plurality of data subcarriers that are close in time and frequency to the second pilot subcarrier and multiplied by the same scrambling code; The pilot channel signal and data channel signal assigned to the carrier and data subcarrier are multiplied by a scrambling code shifted by n indexes for each symbol, and the subcarrier group setting means of the data channel signal The first data channel signal and the pilot channel signal in which the group is set are multiplied by the same scrambling code among a plurality of OFDM transmitters in which the same subcarrier group is set, while the data Of the channel signals, the second data channel signal in which the subcarrier group is not set by the subcarrier group setting means is specific to a predetermined transmitter that is orthogonal or pseudo-orthogonal between the OFDM transmitters. Between each of the OFDM transmitters by the scrambling means for multiplying the scrambling code, the complex value multiplication means for multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group, and the scrambling means. A second data channel signal multiplied by a scrambling code specific to an orthogonal or pseudo-orthogonal predetermined OFDM transmitter, a pilot channel signal multiplied by a complex value by complex value multiplication means, and a first data OFDM modulation is applied to the channel signal, And OFDM signal generation means for generating a FDM signal, characterized in that it comprises a transmitting means for transmitting via one or more antennas to the receiver OFDM signal generated by the OFDM signal generating unit.

In order to solve the above-described problem, the OFDM receiver of the present invention provides n * k subcarriers after k symbols multiplied by a first pilot subcarrier and the same scrambling code as the first pilot subcarrier. A second pilot subcarrier at a distant location, one or more of the first pilot subcarrier and the second pilot subcarrier that are close in time and frequency and multiplied by the same scrambling code A scrambling code in which at least one subcarrier group including data subcarriers is set, and the pilot channel signal and the data channel signal allocated to the pilot subcarrier and the data subcarrier are shifted by n indexes for each symbol. And the data chart Among the plurality of transmitters in which the same subcarrier group is set for the first data channel signal and the pilot channel signal in which the subcarrier group is set in the subcarrier group setting step. While multiplying the same scrambling code, a second data channel signal in which no subcarrier group is set among the data channel signals is predetermined between each transmitter in advance. OFDM transmitted from the OFDM transmitter by multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group. Receiving means for receiving the signal and received by the receiving means OFDM demodulation means for performing OFDM demodulation on the OFDM signal and dividing the signal into signals for each subcarrier, and each of the signals divided for each subcarrier is assigned to at least one subcarrier in a subcarrier group. Separating means for separating the pilot channel signal and data channel signal, and averaging or interpolating the pilot channel signal separated by the separating means for each subcarrier group, and the first of the data channel signals separated by the separating means Channel estimation of one data channel signal and averaging or interpolation of adjacent pilot channel signals among the pilot channel signals separated by the separation means, and the first of the data channel signals separated by the separation means. Channel of 2 data channel signals Channel estimation means for performing estimation, equalization means for equalizing the first data channel signal and the second data channel signal using the channel estimation value estimated by the channel estimation means, and equalization by the equalization means And a data demodulating means for demodulating the first data channel signal and the second data channel signal.

  In order to solve the above-described problem, an OFDM signal transmission method according to the present invention is an OFDM signal transmission method for transmitting OFDM signals from a plurality of transmitters. In the OFDM signal transmission method, the first pilot subcarrier and the first pilot subcarrier are transmitted. A second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the carrier; time for the first pilot subcarrier and the second pilot subcarrier; The pilot channel signal assigned to the pilot subcarrier and the data subcarrier by setting at least one subcarrier group including one or a plurality of the data subcarriers having frequencies close to each other and multiplied by the same scrambling code; N symbols per symbol for the data channel signal A scrambling code shifted by an index is multiplied, and the same subcarrier group is set for the first data channel signal and the pilot channel signal in which the subcarrier group is set, among the data channel signals. While the same scrambling code is multiplied among the plurality of transmitters, the second data channel signal in which no subcarrier group is set among the data channel signals is transmitted between the transmitters. Multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group, multiplying by a predetermined scrambling code specific to the transmitter, which is orthogonal or pseudo-orthogonal. Features.

  According to the present invention, macro diversity reception is performed using a plurality of pilot subcarriers that are arranged in the same subcarrier group and are multiplied by the same scrambling code while randomizing inter-transmitter interference of pilot channel signals. The channel estimation accuracy of the unicast signal can be preferably improved when the macro diversity reception signal and the unicast reception signal are close to each other.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic configuration of a wireless communication system 1 according to an embodiment of the present invention. As shown in FIG. 1, the wireless communication system 1 includes a plurality of (N) OFDM transmitters 11-1, 11-2,... 11 -N, and different channels from each of the OFDM transmitters 11 to 11 -N. It consists of an OFDM receiver 12 that receives an OFDM signal transmitted via a propagation path. Each of the OFDM transmitters 11-1 to 11-N transmits an OFDM signal to the OFDM receiver 12. The OFDM transmitters 11-1 to 11-N do not necessarily have to be installed at different locations, and some of the OFDM transmitters may be installed at the same location. For example, two OFDM transmitters may be included in one wireless communication device. In such a case, the components of the OFDM transmitter such as the subcarrier allocation unit and the subcarrier group setting unit (both will be described later) are common components in all OFDM transmitters. These components may be shared by a plurality of OFDM transmitters.

  The OFDM transmitters 11-1 to 11-N in FIG. 1 are all base stations in a cellular system (mobile phone system), and the OFDM receiver 12 in FIG. 1 is a mobile device. In the following description, the OFDM transmitters 11-1 to 11-N are collectively referred to as the OFDM transmitter 11 when it is not necessary to individually distinguish them.

  FIG. 2 shows an internal configuration of the OFDM transmitter 11 shown in FIG. As shown in FIG. 2, the OFDM transmitter 11 includes a control unit 21, a pilot channel signal generation unit 22, a data channel signal generation unit 23, a subcarrier allocation unit 24, a subcarrier group setting unit 25, a scrambling unit 26, A complex value multiplication unit 27, an IFFT unit (frequency-time domain conversion unit) 28, a wireless transmission unit 29, and an antenna 30 are provided.

  The control unit 21 controls the OFDM transmitter 11 in an integrated manner, and a pilot channel signal generation unit 22, a data channel signal generation unit 23, a subcarrier allocation unit 24, a subcarrier group setting unit 25, a scrambling unit 26, a complex value The multiplier 27 and the IFFT unit 28 are controlled. The pilot channel signal generation unit 22 includes a pilot channel signal source bit string generation unit 31 and a pilot channel signal source bit string modulation unit 32. The pilot channel signal source bit string generation unit 31 generates a bit string that is the source of the pilot channel signal, and outputs the generated bit string to the pilot channel signal source bit string modulation unit 32. The pilot channel signal source bit string modulating unit 32 performs digital modulation such as quadrature phase shift keying (QPSK) on the pilot channel signal source bit string from the pilot channel signal source bit string generating unit 31 to generate a pilot channel signal.

  The data channel signal generation unit 23 includes a data coding unit 33 and a post-coding data signal modulation unit 34. The data coding unit 33 performs channel coding on a transmission data bit sequence (downlink transmission data bit sequence) generated by a transmission data bit sequence generation unit (not shown) at a channel coding rate instructed by the control unit 21, thereby The obtained coded data signal is output to the coded data signal modulation unit 34. The post-coding data signal modulation unit 34 performs digital modulation such as quadrature phase shift keying (QPSK) on the coded data signal using the modulation method instructed by the control unit 21 to generate a transmission data channel signal. To do.

  The pilot channel signal generated by the pilot channel signal generation unit 22 and the data channel signal generated by the data channel signal generation unit 23 are both represented by complex values. The pilot channel signal is used for channel estimation (channel response estimation) in the OFDM receiver 12, for example. The pilot channel signal may be used for timing synchronization and frequency synchronization of the OFDM receiver 12. In the following embodiment, a case where a pilot channel signal is used for channel estimation of the OFDM receiver 12 will be described.

  The subcarrier allocating unit 24 uses the pilot channel signal from the pilot channel signal generating unit 22 and the data channel signal from the data channel signal generating unit 23 as subcarriers corresponding to the pilot channel signal and the data channel signal, that is, pilots. Assign to subcarriers and data subcarriers, respectively. Here, “assign a signal to a subcarrier” adds a subcarrier index indicating a position on a time axis and a frequency axis of a subcarrier corresponding to this signal to a signal represented by a complex value. Means that. A more specific allocation method will be described below with reference to FIG.

  FIG. 3 shows a state of subcarrier allocation by the subcarrier allocation unit 24 of FIG. 2 and a state of subcarrier group setting by the subcarrier group setting unit 25. As shown in FIG. 3, OFDM symbols are arranged along the vertical time axis, and a plurality of subcarriers forming each OFDM symbol are arranged along the horizontal frequency axis. 0, 1, 2,... Described along the time axis indicate OFDM symbol numbers. 0, 1, 2,... Written along the frequency axis indicate subcarrier numbers.

  For example, a subcarrier index of (3, 0) is added to the data channel signal 300 in FIG. The subcarrier allocation unit 24 outputs the pilot channel signal and the data channel signal respectively allocated to the pilot subcarrier and the data subcarrier to the subcarrier group setting unit 25.

  In the embodiment of the present invention, as shown in FIG. 3, the scrambling code for randomizing the transmission signal from each OFDM transmitter 11 is shifted by one index for each symbol and multiplied by each subcarrier. This is a prerequisite. That is, a subcarrier shifted to the left by N subcarriers after N symbols is multiplied by a scrambling code consisting of the same complex value.

  The subcarrier group setting unit 25 includes at least one pilot subcarrier to which the pilot channel signal is assigned and one or more data subcarriers to which the data channel signal is assigned, and is multiplied by the same scrambling code. Grouping is performed so that the subcarriers belong to the same group, and at least one subcarrier group is set. In FIG. 3, a plurality of subcarrier groups surrounded by black frames are set. “Setting a subcarrier group” means adding an index (referred to as a group index) to a pilot channel signal and a data channel signal to which a subcarrier index is added. A group index is not added to a signal that does not belong to any subcarrier group. Specifically, in the case of FIG. 3, the group index is not added to the data channel signal 300 to which the subcarrier index of (3, 0) is added. On the other hand, specifically, in the case of FIG. 3, the group index is added to the pilot channel signal 302 to which the subcarrier index of (10, 5) is added.

  In the subcarrier group including the subcarriers to which pilot channel signals 301 and 302 to which the same scrambling code 15 is multiplied are respectively assigned (subcarrier groups indicated by hatching in FIG. 3), other subcarriers are used. Is a data subcarrier, to which a data channel signal is assigned. The same applies to other drawings shown below.

  Note that a signal in which a subcarrier group is set by the subcarrier group setting unit 25, that is, a data channel signal to which a group index is added is defined as a “first data channel signal”, and a signal in which a subcarrier group is not set, that is, a group A data channel signal to which no index is added is defined as a “second data channel signal”.

  Here, the OFDM transmitters 11-1 to 11 -N in FIG. 1 set the same at least one subcarrier group between the OFDM transmitters 11 by the subcarrier group setting unit 25. That is, at least one of the subcarrier groups set by each subcarrier group setting unit 25 of the OFDM transmitters 11-1 to 11-N is common. In the common subcarrier group, a pilot channel signal and a data channel signal common to the OFDM transmitters 11-1 to 11-N are allocated to the pilot subcarrier and the data subcarrier, respectively. That is, it can be interpreted that the first data channel signal is applied with macro diversity reception, and the second data channel signal is a signal not applied with macro diversity reception.

  The scrambling unit 26 first multiplies the second data channel signal by a predetermined scrambling code specific to the OFDM transmitter, which is orthogonal or pseudo-orthogonal, between the OFDM transmitters 11. In contrast, the scrambling unit 26 multiplies the pilot channel signal and the first data channel signal by the same scrambling code between the OFDM transmitters 11 in which the same subcarrier group is set. The purpose of scrambling is to randomize modulated data symbols and pilot symbols between adjacent OFDM transmitters 11 or between groups of OFDM transmitters 11 that perform macro diversity communication.

  FIG. 4 shows an example of a scrambling code sequence generator (generator polynomial x ^ 15 + x ^ 14 + 1) in the scrambling unit 26. By changing the initial value of the shift register, a unique scrambling code sequence w (k) can be obtained. In the embodiment of the present invention, each symbol is multiplied by the same scrambling code sequence. However, it is assumed that each subcarrier is multiplied by n index for each symbol. Specifically, each symbol is multiplied by a scrambling code sequence w (k), but the first symbol is multiplied by w (k) k = 0, ..., N-1 (N: number of subcarriers). On the other hand, the m-th symbol is multiplied by w (k) k = m * n, ..., N-1 + m * n. FIG. 3 shows an example where n = 1. The same scrambling code is multiplied to subcarriers having the same number assigned to the subcarrier. Here, pilot subcarriers to which pilot channel signals 301 and 302 are respectively assigned are multiplied by the same scrambling code 15. The pilot channel signals 301 and 302 are added with subcarrier indexes (6, 9) and (10, 5).

  In general, when the same scrambling code is multiplied for each symbol, interference of pilot channel signals becomes equal between adjacent OFDM transmitters 11, and channel estimation accuracy may deteriorate. As the premise of the embodiment of the present invention, the interference between the OFDM transmitters 11 of the pilot channel signal can be randomized by shifting the scrambling code by a certain amount every symbol. In addition to this, interference between OFDM transmitters 11 can also be avoided by changing each symbol or scrambling code sequence itself, or by changing pilot positions between adjacent OFDM transmitters 11.

  The scrambling unit 26 outputs the scrambled pilot channel signal and the first data channel signal to the complex value multiplication unit 27, while the scrambled second data channel signal is converted into an IFFT unit (inverse high speed) that is an OFDM modulator. (Fourier transform unit, that is, frequency-time domain transform unit) 28 directly. The complex value multiplier 27 is uniquely defined between the OFDM transmitters 11 for each pilot channel signal and data channel signal having the same group index with respect to the pilot channel signal and the first data channel signal to which the group index is added. Multiply by complex values. The complex values determined for each subcarrier group may all have the same absolute value. By making the absolute values the same, it is possible to avoid a power difference between subcarrier groups. Here, the complex value includes a real value, and may be a real value such as ± 1, for example. The complex value multiplier 27 outputs the pilot channel signal and the data channel signal multiplied by the complex value to the IFFT unit 28.

  At this time, the complex value multiplied for each group by the complex value multiplication unit 27 is the same as the predetermined scrambling code specific to the OFDM transmitter in which the phase of the pilot channel signal is orthogonal or pseudo-orthogonal between the OFDM transmitters 11. This is a complex value. That is, when multiplying a complex value for each group, the complex value multiplier 27 obtains (selects) and multiplies a complex value such that the phase of the pilot channel signal is the same as the scrambling code unique to the OFDM transmitter. As a result, the pilot channel signal can be used for channel estimation of the first data channel signal in the OFDM receiver 12 and can also be reused for channel estimation of the second data channel signal.

  The IFFT unit 28 performs OFDM modulation on the signals from the scrambling unit 26 and the complex value multiplication unit 27 to generate an OFDM signal that is a sequence of a plurality of OFDM symbols. That is, the IFFT unit 28 generates an OFDM signal by converting a frequency domain signal into a time domain signal. The OFDM signal generated by the IFFT unit 28 is added with a guard interval (GI) by a GI adding unit (not shown), and then wirelessly transmitted by a wireless transmitting unit 29 including a digital-analog converter, an up-converter, a power amplifier, and the like. It is converted into a signal (RF signal) and transmitted from the antenna 30.

  Next, FIG. 5 shows an internal configuration of the OFDM receiver 12 of FIG. FIG. 5 shows a configuration related to macro diversity reception and unicast reception of the OFDM receiver 12. As shown in FIG. 5, the OFDM receiver 12 includes a control unit 41, an antenna 42, a radio reception unit 43, an FFT unit (time-frequency domain conversion unit) 44, a frequency channel separation unit 45, a descrambling unit 46, a channel. An estimation unit 47, a channel equalization unit 48, a data channel signal demodulation unit 49, and a data signal decoding unit 50 are provided.

  The control unit 41 comprehensively controls the OFDM receiver 12, and includes a frequency channel separation unit 45, a descrambling unit 46, a channel estimation unit 47, a channel equalization unit 48, a data channel signal demodulation unit 49, and a data signal decoding The unit 50 is controlled.

  A radio signal received by the antenna 42 is converted into a baseband digital signal by a radio reception unit 43 including a low noise amplifier, a down converter, an analog-digital converter (all not shown), and the like. After the guard interval is removed by a GI removal unit (not shown), the baseband digital signal is converted from a time domain signal to a frequency domain signal by an FFT unit 44 (fast Fourier transform unit, that is, a time-frequency domain transformation unit). That is, it is divided into signals for each subcarrier. The FFT unit 44 outputs the output signal divided for each subcarrier to the frequency channel separation unit 45. The frequency channel separation unit 45 separates pilot channel signals and data channel signals respectively assigned to subcarriers in the subcarrier group. The frequency channel separation unit 45 outputs each separated signal (pilot channel signal and data channel signal) to the descrambling unit 46. The descrambling unit 46 performs descrambling for each signal using the scrambling code sequence applied by the OFDM transmitter 11, and outputs the descrambled signal to the channel equalization unit 48. It is assumed that the scrambling code sequence applied by the OFDM transmitter 11 is known on the OFDM receiver 12 side.

  The frequency channel separation unit 45 outputs the separated pilot channel signal to the channel estimation unit 47. When performing channel estimation of the first data channel signal, the channel estimation unit 47 performs channel estimation by averaging or interpolating the pilot channel signal for each subcarrier group. On the other hand, when performing channel estimation of the second data channel signal, the channel estimation unit 47 performs channel estimation by averaging or interpolating adjacent pilot channel signals. The channel estimation unit 47 outputs a channel estimation value indicating the channel response to the channel equalization unit 48. The channel equalization unit 48 performs channel equalization on each data channel signal using the channel estimation value from the channel estimation unit 47. The data channel signal after channel equalization is demodulated by the data channel signal demodulator 49, and the bit string that is the source of the data signal is reproduced.

  Here, the processing operation of the channel estimation unit 47 will be described in more detail. For simplicity of explanation, it is assumed that the width of the subcarrier group in the time direction and the frequency direction is sufficiently smaller than the fluctuation period of the channel in the time direction and the frequency direction. In this case, the channel response to signals assigned to the subcarriers in the subcarrier group can be regarded as almost constant. As described in FIG. 2, all the pilot channel signals and the first data channel signals respectively assigned to the subcarriers in the subcarrier group set by the subcarrier group setting unit 25 are supplied to the complex value multiplication unit 27. A complex value determined for each subcarrier group is multiplied. Assuming that the complex value is R and the channel response is H, the pilot channel signal and the data channel signal respectively assigned to the subcarriers in the same subcarrier group are commonly subjected to distortion represented by H * R. As a result, it can be considered that the OFDM signal transmitted from the OFDM transmitter 11 is equivalent to receiving a channel response represented by H * R.

  That is, in the OFDM receiver 12, when signals assigned to subcarriers in the same subcarrier group are transmitted from the OFDM transmitters 11-1 to 11-N after being multiplied by different complex values, respectively. Can be handled in the same manner as when transmitted without being multiplied by a complex value. Therefore, the channel estimation unit 27 obtains a channel estimation value by dividing the received pilot channel signal by the original pilot channel signal, regardless of the complex value multiplied by the OFDM transmitters 11-1 to 11-N. Can do. The original pilot channel signal is a known signal in the OFDM receiver 12.

  In the embodiment of the present invention, each symbol is multiplied by the same scrambling code sequence. However, it is assumed that each subcarrier is multiplied by n index for each symbol. Therefore, as shown in FIG. 3, a plurality of pilot subcarriers can be arranged in one group (subcarrier group). For example, pilot subcarriers to which pilot channel signals 301 and 302 are respectively allocated can be arranged in one subcarrier group. As a result, by having a plurality of pilot subcarriers in the subcarrier group, it is possible to obtain a highly accurate channel estimation value by averaging the channel estimation values obtained from each pilot channel signal. Further, when a plurality of pilot subcarriers are arranged apart from each other in the subcarrier group, a high-accuracy channel estimation value is obtained by performing interpolation using the channel estimation value obtained for each pilot subcarrier. Can be obtained.

  Further, according to the embodiment of the present invention, even if the pilot subcarriers are distant from the subcarrier group, the same scrambling code is used to improve the accuracy of the channel estimation value of the first data channel signal. be able to. For example, in the case of FIG. 6, the scrambling code of the pilot subcarrier to which the pilot channel signal 303 is assigned is applied to the pilot subcarrier of the subcarrier group (the pilot subcarrier to which the pilot channel signals 301 and 302 are respectively assigned). Therefore, pilot subcarriers to which the pilot channel signal 303 is assigned can be used for channel estimation. The pilot channel signal 303 is added with a subcarrier index of (14, 1), and is 4 subcarriers away from the pilot channel signal 302 to which a subcarrier index of (10, 5) is added. However, when pilot subcarriers separated from the subcarrier group are used to improve the accuracy of the channel estimation value of the first data channel signal, the pilot subcarriers separated from the subcarrier group have some correlation with the subcarrier group. (Having a correlation greater than or equal to a predetermined reference value).

The channel estimation and channel equalization process for a certain data subcarrier in the subcarrier group will be described using mathematical expressions. In the following description, a data signal is D, a pilot signal assigned to a pilot subcarrier in the subcarrier group is P, a pilot signal assigned to a subcarrier in the subcarrier group in the nth OFDM transmitter 1n, and _Let R _n be a complex value multiplied by the data signal.

For the sake of simplicity of explanation, it is assumed that the channel distortion received by the pilot signal and data signal assigned to the subcarriers in the subcarrier group can be regarded as constant, and the channel from the OFDM transmitter 1n to the OFDM receiver 20 _Let channel distortion be represented as Hn. In this case, the pilot signal and data signal transmitted from the OFDM transmitter 1n are each given by P · R _n and D · R _n. Since P · R _n and D · R _{n are} combined by the antenna 42 of the OFDM receiver 20 after being subjected to channel distortion, the received pilot signal P _rx is expressed by the following equation.

On the other hand, the received data signal _Drx is expressed by the following equation.

In this case, as shown in the following equation, by multiplying the reciprocal and the original pilot signal P is a known pilot signal P _rx received the data signal D _rx, it is possible to restore the data signal D.

  Next, channel estimation for the second data channel signal will be described. As described in the above-described configuration of the OFDM transmitter 11, the pilot channel signal is multiplied by a predetermined orthogonal or pseudo-orthogonal scrambling code specific to each transmitter by the complex value multiplier 27. In the case of channel estimation for two data channel signals, the channel estimation unit 47 averages or interpolates adjacent pilot channel signals. That is, depending on the correlation between the data channel subcarrier and pilot subcarrier for which channel estimation is to be performed, weighting averaging is performed by assigning a large weight to a nearby pilot channel signal and applying a small weight to a distant pilot channel signal. I do. As a result, the power of the pilot channel signals transmitted from the OFDM transmitters 11 having different scrambling patterns can be reduced, and the accuracy of the desired channel estimation value can be improved.

  As described above, according to the embodiment of the present invention, when the OFDM receiver 12 performs macro diversity reception on the signals transmitted from the OFDM transmitters 11-1 to 11-N, each subcarrier group Since the transmission path can be decorrelated between them, it is possible to obtain an additional diversity gain and to randomize the interference between the transmitters of the pilot channel signal, while using the shift of the scrambling code to High-accuracy transmission path estimation can be performed using the channel signal. Also, these pilot channel signals can be reused for channel estimation when macro diversity reception is not performed (during unicast reception). That is, when the macro diversity reception signal and the unicast reception signal are close to each other, the accuracy of channel estimation for unicast reception can be preferably improved.

  Accordingly, even when the first data channel signal and the second data channel signal are FDM multiplexed as shown in FIG. 7, a pilot dedicated to each data channel is not required and a flexible data channel arrangement is performed. The broadcast data can be transmitted and received between the OFDM transmitter 11 and the OFDM receiver 12 while maintaining the unicast frame format.

  In addition, the subcarrier group setting unit 25 of the OFDM transmitter 11 distributes the first data channel signal to which the same scrambling code sequence is applied to the same subcarrier group when the subcarrier groups are grouped. For example, a signal having the same phase as the pilot channel signal, such as 1 + j, may be set as the channel signal. Thus, a copy of the pilot channel signal can be easily created by applying the scrambling code as usual by the subsequent scrambling unit 26. This copy of the pilot channel signal can also be reused for channel estimation of the unicast signal. In the case of FIG. 8, the subcarrier group setting unit 25 sets (maps), for example, 1 + j to the data subcarrier to which the data channel signal 304 is assigned. Thereby, a copy of the pilot channel signal of the subcarrier group can be easily generated. Thereby, the precision of the channel estimation of a macro diversity signal can be improved as needed.

  For example, in the case of FIG. 3, pilot channel signals 301 and 302 are added with subcarrier indexes (6, 9) and (10, 5), which are separated by 4 subcarriers. The same applies to other pilot channel signals, and the intervals between the pilot channel signals are set to be uniform. However, the present invention is not limited to such a case. For example, as shown in FIG. 9, the interval between pilot channel signals may be set locally uneven. In the case of FIG. 9, there are pilot channel signal intervals of 4 subcarriers and those of 2 subcarriers. Thereby, more flexible data channel arrangement can be performed.

  3, 6, and 8, it is assumed that the OFDM transmitter 11 is provided with one transmission antenna 30. However, the present invention is not limited to such a case, and the OFDM transmitter 11 is configured for transmission. For example, as shown in FIG. 10, a pilot channel signal used for the first transmission antenna 30 and a pilot used for the second transmission antenna 30 are provided. The channel signal may be allocated to each subcarrier. As described in the embodiment of the present invention for each transmission antenna, the effect of the present invention can be enjoyed by defining a subcarrier group, and transmission antenna diversity and spatial multiplexing can be applied. Of course, the OFDM transmitter 11 may be provided with three or more antennas 30 for transmission.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  The series of processes described in the embodiments of the present invention can be executed by software, but can also be executed by hardware.

The figure which shows schematic structure of the radio | wireless communications system which concerns on this invention. The block diagram which shows the internal structure of the OFDM transmitter of FIG. The figure which shows the mode of the subcarrier allocation by the subcarrier allocation part of FIG. 2, and the mode of the setting of the subcarrier group by the subcarrier group setting part. The figure which shows the example (generator polynomial x ^ 15 + x ^ 14 + 1) of the scrambling code sequence generator in the scrambling part of FIG. The block diagram which shows the internal structure of the OFDM receiver of FIG. Explanatory drawing explaining the utilization method of the pilot channel signal in a distant position. The figure which shows a mode that the 1st data channel signal and the 2nd data channel signal are FDM multiplexed. Explanatory drawing explaining the copy creation method of a pilot channel signal. Explanatory drawing explaining the arrangement | positioning space | interval of a pilot channel signal. The figure which shows a mode that the some pilot channel signal utilized for two antennas for transmission is arrange | positioned.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Wireless communication system, 11 (11-1 thru | or 11-N) ... OFDM transmitter, 12 ... OFDM receiver, 21 ... Control part, 22 ... Pilot channel signal generation part, 23 ... Data channel signal generation part, 24 ... Subcarrier allocation unit, 25 ... subcarrier group setting unit, 26 ... scrambling unit, 27 ... complex value multiplication unit, 28 ... IFFT unit, 29 ... radio transmission unit, 30 ... antenna, 31 ... pilot channel signal source bit string generation unit 32 ... Pilot channel signal source bit string modulating unit, 33 ... Data coding unit, 34 ... Post-coding data signal modulating unit, 41 ... Control unit, 42 ... Antenna, 43 ... Radio receiving unit, 44 ... FFT unit, 45 ... Frequency channel Separation unit, 46 ... descrambling unit, 47 ... channel estimation unit, 48 ... channel equalization unit, 49 ... Tachaneru signal demodulator, 50 ... data signal decoding unit.

Claims (17)

In an OFDM signal transmission method for transmitting OFDM signals from a plurality of transmitters,
A data channel signal generation step of generating a data channel signal by modulating a bit string obtained by channel coding;
A pilot channel signal generating step for generating a pilot channel signal;
The data channel signal generated by the processing of the data channel signal generation step and the pilot channel signal generated by the pilot channel signal generation step are converted into the same pilot subcarrier and data subcarrier among the plurality of transmitters. An assignment step to assign,
A first pilot subcarrier, a second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the first pilot subcarrier, and the first pilot subcarrier, A subcarrier group that sets at least one subcarrier group including one or a plurality of the data subcarriers that are close in time and frequency to the pilot subcarrier and the second pilot subcarrier and are multiplied by the same scrambling code Configuration steps;
The pilot channel signal and the data channel signal allocated to the pilot subcarrier and the data subcarrier are multiplied by a scrambling code shifted by n indexes for each symbol, and the subcarrier of the data channel signal Multiplying the same scrambling code between the plurality of transmitters set with the same subcarrier group for the first data channel signal and the pilot channel signal set with the subcarrier group in the group setting step On the other hand, among the data channel signals, a second data channel signal in which a subcarrier group is not set by the subcarrier group setting step is determined in advance between each of the transmitters as orthogonal or pseudo-orthogonal. A scrambling step of multiplying a scrambling code unique to the transmitter;
Complex value multiplication step of multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group;
The second data channel signal multiplied by a predetermined scrambling code that is orthogonal or pseudo-orthogonal between each of the transmitters by the processing of the scrambling step, and the complex value multiplication step An OFDM signal generation step of generating an OFDM signal by performing OFDM modulation on the pilot channel signal and the first data channel signal multiplied by the complex value by the processing of
A transmission step of transmitting the OFDM signal generated by the processing of the OFDM signal generation step to a receiver via one or a plurality of antennas.   The complex value multiplied by the pilot channel signal and the first data channel signal for each subcarrier group by the processing of the complex value multiplication step is such that the phase of the pilot channel signal is orthogonal between the transmitters or 2. The OFDM signal transmission method according to claim 1, wherein the pseudo-orthogonal predetermined scrambling code is a complex value that is the same as that of the transmitter.   When the subcarrier group is set by the processing of the subcarrier group setting step, the first data channel signal to which the same scrambling code is applied is arranged in the same subcarrier group, and the first data 2. The OFDM signal transmission method according to claim 1, wherein a signal having the same phase as the pilot channel signal is set in the channel signal.   When the OFDM signal is transmitted to the receiver via at least a first antenna and a second antenna by the process of the transmission step, a part of the OFDM signal corresponding to the pilot channel signal after OFDM modulation is The part of the OFDM signal transmitted through the first antenna and corresponding to the pilot channel signal after OFDM modulation is transmitted through the second antenna. OFDM signal transmission method. Data channel signal generating means for generating a data channel signal by modulating a bit string obtained by channel coding;
Pilot channel signal generating means for generating a pilot channel signal;
Allocation for assigning the data channel signal generated by the data channel signal generation means and the pilot channel signal generated by the pilot channel signal generation means to the same pilot subcarrier and data subcarrier among a plurality of OFDM transmitters Means,
A first pilot subcarrier, a second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the first pilot subcarrier, and the first pilot subcarrier, A subcarrier group that sets at least one subcarrier group including one or a plurality of the data subcarriers that are close in time and frequency to the pilot subcarrier and the second pilot subcarrier and are multiplied by the same scrambling code Setting means;
The pilot channel signal and the data channel signal allocated to the pilot subcarrier and the data subcarrier are multiplied by a scrambling code shifted by n indexes for each symbol, and the subcarrier of the data channel signal Multiplying the same scrambling code between the plurality of OFDM transmitters set with the same subcarrier group for the first data channel signal set with the subcarrier group by the group setting means and the pilot channel signal On the other hand, among the data channel signals, a second data channel signal in which a subcarrier group is not set by subcarrier group setting means is preliminarily orthogonal or pseudo-orthogonal between the OFDM transmitters. Scrambling means for multiplying a defined scrambling code specific to the transmitter;
Complex value multiplication means for multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group;
The second data channel signal multiplied by the scrambling code specific to the OFDM transmitter predetermined orthogonal or pseudo-orthogonal between the OFDM transmitters by the scrambling means, and the complex value multiplication means OFDM signal generating means for generating an OFDM signal by performing OFDM modulation on the pilot channel signal and the first data channel signal multiplied by the complex value by:
An OFDM transmitter comprising: transmission means for transmitting the OFDM signal generated by the OFDM signal generation means to a receiver via one or a plurality of antennas.   The complex value multiplied by the complex value multiplication means for each subcarrier group by the pilot channel signal and the first data channel signal is such that the phase of the pilot channel signal is orthogonal or pseudo between the OFDM transmitters. 6. The OFDM transmitter according to claim 5, wherein the OFDM transmitter is a complex value that is the same as an orthogonal predetermined scrambling code unique to the OFDM transmitter.   When the subcarrier group is set by the subcarrier group setting means, the first data channel signal to which the same scrambling code is applied is arranged in the same subcarrier group, and the first data channel signal 6. The OFDM transmitter according to claim 5, wherein a signal having the same phase as that of the pilot channel signal is set in the transmitter.   When the OFDM signal is transmitted by the transmitting means to the receiver via at least a first antenna and a second antenna, the transmitting means transmits the OFDM signal corresponding to the pilot channel signal after OFDM modulation. 6. A part is transmitted through the first antenna, and a part of the OFDM signal corresponding to the pilot channel signal after OFDM modulation is transmitted through the second antenna. The OFDM transmitter described in 1. A first pilot subcarrier, a second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the first pilot subcarrier, and the first pilot subcarrier, At least one subcarrier group including one or a plurality of the data subcarriers that are close in time and frequency and multiplied by the same scrambling code is set to the pilot subcarrier and the second pilot subcarrier, and the pilot Multiplying the pilot channel signal and the data channel signal allocated to the subcarrier and the data subcarrier by a scrambling code shifted by n indexes for each symbol, and setting a subcarrier group in the data channel signal Step by step The first data channel signal with the subcarrier group set and the pilot channel signal are multiplied by the same scrambling code between the plurality of transmitters with the same subcarrier group set, Of the data channel signals, a scrambling code specific to a predetermined transmitter that is orthogonal or pseudo-orthogonal between the transmitters for a second data channel signal for which no subcarrier group is set Receiving means for receiving the OFDM signal transmitted from the OFDM transmitter by multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group ,
OFDM demodulation means for performing OFDM demodulation on the OFDM signal received by the receiving means, and dividing the OFDM signal into signals for each subcarrier;
Separating means for separating a pilot channel signal and a data channel signal respectively assigned to the subcarriers in at least one subcarrier group from the signal divided for each subcarrier;
The pilot channel signals separated by the separation means are averaged or interpolated for each subcarrier group, and the channel estimation of the first data channel signal among the data channel signals separated by the separation means is performed. And averaging or interpolating adjacent pilot channel signals among the pilot channel signals separated by the separating means, and second data channel signals among the data channel signals separated by the separating means Channel estimation means for performing channel estimation of
Equalization means for equalizing the first data channel signal and the second data channel signal using the channel estimation value estimated by the channel estimation means;
An OFDM receiver comprising: data demodulating means for demodulating the first data channel signal and the second data channel signal equalized by the equalizing means.   The first data channel signal is a data channel signal in which the subcarrier group is set in the data channel signal, and the second data channel signal is the sub channel in the data channel signal. The OFDM receiver according to claim 9, wherein the OFDM receiver is a data channel signal in which no carrier group is set.   All the pilot channel signals and the first data channel signals respectively assigned to the subcarriers in the subcarrier group are multiplied by complex values determined for each subcarrier group. The phase of the pilot channel signal is a complex value that is the same as a predetermined scrambling code specific to the OFDM transmitter that is orthogonal or pseudo-orthogonal between the OFDM transmitters. 10. The OFDM receiver according to 10.   The channel estimation means uses, in addition to the pilot channel signal assigned to a pilot subcarrier in the subcarrier group, the pilot channel signal assigned to another pilot subcarrier separated from the subcarrier group. The OFDM receiver according to claim 9, wherein channel estimation of the first data channel signal is performed.   The other pilot subcarriers apart from the subcarrier group used for channel estimation of the first data channel signal have a correlation greater than a predetermined reference with the subcarrier group. 12. The OFDM receiver according to 12.   In addition to the pilot channel signal assigned to the pilot subcarriers in the subcarrier group, the channel estimation means includes the first data channel signal arranged in the same subcarrier group as the pilot channel signal. The channel estimation of the first data channel signal is performed using the data channel signal allocated to a data subcarrier to which a signal having the same phase as the pilot channel signal is mapped. The OFDM receiver according to 1. In an OFDM signal transmission method for transmitting OFDM signals from a plurality of transmitters,
A first pilot subcarrier, a second pilot subcarrier at a position separated by n * k subcarriers after k symbols multiplied by the same scrambling code as the first pilot subcarrier, and the first pilot subcarrier, Setting at least one subcarrier group including one or a plurality of the data subcarriers that are close in time and frequency to the pilot subcarrier and the second pilot subcarrier and are multiplied by the same scrambling code;
The pilot channel signal and the data channel signal allocated to the pilot subcarrier and the data subcarrier are multiplied by a scrambling code shifted by n indexes for each symbol, and the subcarrier of the data channel signal The first data channel signal in which a group is set and the pilot channel signal are multiplied by the same scrambling code among the plurality of transmitters in which the same subcarrier group is set, while the data channel signal The second data channel signal for which no subcarrier group is set is multiplied by a scrambling code specific to the transmitter that is orthogonal or pseudo-orthogonal between the transmitters. ,
An OFDM signal transmission method characterized by multiplying the pilot channel signal and the first data channel signal by a complex value for each subcarrier group.   The complex value that is multiplied by the pilot channel signal and the first data channel signal for each subcarrier group is the predetermined value in which the phase of the pilot channel signal is orthogonal or pseudo-orthogonal between the transmitters. The OFDM signal transmission method according to claim 15, wherein the transmission value is a complex value that is the same as a scrambling code unique to the transmitter.   When the subcarrier group is set, the first data channel signal to which the same scrambling code is applied is arranged in the same subcarrier group, and the first data channel signal is the same as the pilot channel signal The method of claim 15, wherein a phase signal is set.

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