WO2006125343A1 - A orthogonal frequency-time division multiplex transmitter, a receiver and methods - Google Patents
A orthogonal frequency-time division multiplex transmitter, a receiver and methodsInfo
- Publication number
- WO2006125343A1 WO2006125343A1 PCT/CN2005/000726 CN2005000726W WO2006125343A1 WO 2006125343 A1 WO2006125343 A1 WO 2006125343A1 CN 2005000726 W CN2005000726 W CN 2005000726W WO 2006125343 A1 WO2006125343 A1 WO 2006125343A1
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- oftdm
- sequence
- symbol
- data
- channel
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/26—Systems using multi-frequency codes
- H04L27/2601—Multicarrier modulation systems
- H04L27/2647—Arrangements specific to the receiver only
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/26—Systems using multi-frequency codes
- H04L27/2601—Multicarrier modulation systems
- H04L27/2626—Arrangements specific to the transmitter only
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
- H04L25/03006—Arrangements for removing intersymbol interference
- H04L25/03159—Arrangements for removing intersymbol interference operating in the frequency domain
Definitions
- Orthogonal frequency division time division transmitter Orthogonal frequency division time division transmitter, receiver and method thereof
- the present invention relates to wireless communication technologies, and more particularly to a technique for transmitting signals over a plurality of orthogonal carriers in a wireless communication system. Background technique
- the signal transmission technology of broadband mobile communication is mainly based on OFDM (Orthogonal Frequency Division Multiplexing) technology, and various variant technologies such as OFDMA (Orthogonal Frequency Division Multiple Access) and MC-CDMAC Multi-Carrier-Code are derived.
- OFDM Orthogonal Frequency Division Multiplexing
- OFDMA Orthogonal Frequency Division Multiple Access
- MC-CDMAC Multi-Carrier-Code are derived.
- MT-CDMA multi-tone-code division multiple access
- VSF-OFCDM orthogonal frequency division code division multiplexing
- OFDM Orthogonal Frequency Division Multiplexing
- SC/FDE single carrier-frequency domain equalization
- OFDM Orthogonal Frequency Division Multiplexing
- SC/FDE single carrier-frequency domain equalization
- the multi-carrier communication method of OFDM maps a sequence of symbols to be transmitted to a plurality of parallel sub-carriers for transmission; in the transmission process, symbols on each sub-carrier are only weighted by their corresponding sub-channel amplitude-frequency responses, and Gaussian additive noise Contamination; On the receiving side, as long as the amplitude-frequency response of the sub-channel is normalized, the symbols transmitted on the sub-carriers can be estimated, thereby estimating the transmission sequence.
- a cyclic prefix (CP) having a length of the channel maximum delay spread must be added at the front end of each OFDM transmission symbol, which is copied from the tail end of the OFDM symbol.
- the wireless transmitter 1 includes a serial to parallel conversion device 11 for converting and converting a serial symbol stream obtained by data modulation mapping into a plurality of parallel symbol streams; and an IFFT conversion device 12 for IDFT transforming to modulate the plurality of parallel symbol streams onto a plurality of orthogonal subcarriers and synthesizing into OFDM symbols; a CP adding device 13 for copying a portion of the OFDM symbol tail to a front end of the symbol to form The final OFDM symbol with CP, CP makes the transmitted symbol have periodicity.
- the wireless transmitter should further include: channel coding and modulating means for channel coding and data modulation of the input data; and performing D/A conversion and analog signal processing (eg, channel shaping filtering) on the OFDM symbol, and Modulation to the radio frequency and then transmission through the antenna, since these parts are not directly related to the present invention, they are omitted here for the sake of brevity.
- channel coding and modulating means for channel coding and data modulation of the input data
- D/A conversion and analog signal processing eg, channel shaping filtering
- the receiver 2 including a de-CP device 21, for removing the CP of the OFDM symbol front end obtained by down-converting to the baseband; an FFT device 22, for removing the CP by DFT transform After the OFDM symbol is correlated and demodulated, after demodulation is obtained Parallel symbol stream; a parallel to serial conversion device 23 for parallel-converting the demodulated parallel symbol stream into a serial symbol stream.
- a de-CP device 21 for removing the CP of the OFDM symbol front end obtained by down-converting to the baseband
- an FFT device 22 for removing the CP by DFT transform After the OFDM symbol is correlated and demodulated, after demodulation is obtained Parallel symbol stream
- a parallel to serial conversion device 23 for parallel-converting the demodulated parallel symbol stream into a serial symbol stream.
- the wireless receiver machine should further include a receiving antenna for receiving the radio frequency signal; a downconverting device for downconverting the radio frequency signal to the baseband; and a matching filtering device for performing matched filtering on the downconverted baseband signal; and, based on the transmitting end Channel coding and modulation rules for channel decoding and demodulation of the serial symbol stream to obtain channel decoding and demodulation means for the initially transmitted signal stream, since these portions are not directly related to the present invention, therefore, for the sake of brevity, it is omitted here.
- the OFDM system Compared with the traditional single-carrier communication system based on the transverse filter architecture, the OFDM system has low implementation complexity (sub-channel signal shaping and receive matching filtering based on IFFT/FFT), high frequency efficiency, and easy to be used in broadband.
- the spectrum utilization and power efficiency of OFDM decreases as the CP length of the CP is included in OFDM, and in order to maintain a high level of spectrum utilization and power efficiency, no more than (for example, at least 4 times), thus directly causing the number of subcarriers of the OFDM symbol to generally exhibit a large value (for example, 256 subcarriers) in a broadband wireless communication scenario, so that the equivalent bandwidth of the subcarrier is far Less than the coherence bandwidth of the channel improves the receiver's sensitivity to frequency synchronization accuracy and reduces the frequency domain diversity performance of the OFDM system.
- the time-domain superposition of a large number of subcarriers causes a large amplitude-to-average ratio of the transmitted signal.
- the upgrade also increases the transmitter's requirements for the linearity of the power amplification period.
- OFDM has strong adaptability to the channel time-frequency plane, its symbol design length is greatly affected by spectrum utilization, and frequency domain subcarrier division is redundant, which is not conducive to fast moving speed and carrier frequency.
- frequency domain subcarrier division is redundant, which is not conducive to fast moving speed and carrier frequency.
- the length of OFDM symbols cannot be lengthened appropriately to improve spectrum utilization. Therefore, the design of the entire OFDM system appears to be rather rigid, and its symbol length must be designed for the harsh scene of the communication scenario, resulting in potential capacity loss.
- the SC/FDE (single-carrier frequency-domain equalization) communication system is very close to the traditional single-carrier communication system, but it divides the transmitted symbol sequence into blocks of equal length and copies a cyclic prefix for each data block. (CP), the design principle of this CP is similar to the present invention.
- the OFDM orthogonal frequency division multiplexing system differs in that the data to be copied is the tail of each data block. In this way, the receiver side can equalize the channel according to the frequency domain equalization method, thereby repairing the damage of the channel to the transmitted symbol, and then estimating the corresponding transmitted symbol sequence.
- SC/FDE system has low implementation complexity (the receiving end is based on FFT/IFFT transform and single-point zero-forcing equalizer to complete frequency domain equalization), and has complete equalizer design criteria, signal peak-to-average ratio is not high, CP and data block length
- the design is flexible and easy to use in broadband wireless communication systems.
- the design of this scheme does not consider the adaptability to the channel time-frequency characteristics, making it difficult for the receiver to provide a large frequency domain diversity gain for channel decoding.
- the comprehensive performance is not high; at the same time, the single-carrier receiving algorithm is likely to cause the noise enhancement and proliferation, which will seriously affect the receiving error performance of the system.
- the invention is a novel orthogonal multi-carrier frequency division time division technique-OFTDM which is proposed based on combining the advantages and disadvantages of various conventional single-carrier and multi-carrier transmission technologies.
- the wireless transmitter of the present invention first converts the serial-parallel converted plurality of parallel modulation symbol streams into a sequence of data blocks of a corresponding length based on an inverse fast Fourier transform (IFFT), and chronologically processes the plurality of IFFT-transformed data blocks.
- IFFT inverse fast Fourier transform
- Performing block multiplexing defining a plurality of multiplexed data blocks as one OFTDM (orthogonal frequency division-time division multiplexing) symbol data portion; secondly, copying a plurality of data at the tail of the OFTDM symbol data portion as a loop a prefix (CP) portion to the forefront of the OFTDM symbol data portion to generate the OFTDM symbol; again, channel shaping filtering of the OFTDM symbol components (data portion and CP portion); and finally, the baseband of the OFTDM system
- the signal is converted to a radio frequency (RF) signal and radiated by the antenna system onto the wireless channel.
- RF radio frequency
- the wireless receiver of the present invention first converts the received wireless signal into a baseband signal, and performs matched filtering on the received signal to complete symbol timing and frequency synchronization; subsequently, removes the cyclic prefix of the OFTDM symbol front end, and then the data portion of the OFTDM symbol. Demultiplexing is performed to restore a plurality of data block sequences of the same length as the transmitting end; finally, the transmitting end data block is mapped to the corresponding modulation symbol stream based on the FFT Fourier transform.
- the OFTDM symbol level frequency domain equalization (FDE) is implemented based on channel estimation, FFT/IFFT forward and inverse Fourier transform equal to the length of the data portion of the OFTDM symbol, and channel equalizer.
- the frequency domain equalized OFTDM symbol data portion is provided to the demultiplexing step.
- the following control method for adjusting the IFFT transform matrix size, the cyclic prefix length, and the number of data block demultiplexing is also proposed:
- a wireless transmitter for transmitting signals over a plurality of orthogonal carriers in a wireless communication system, comprising: a serial to parallel conversion device for inputting serial symbol data sequences Serializing and converting a plurality of parallel symbol data sequences; an IFFT transforming apparatus, configured to perform IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks; and further comprising: a data block multiplexing device, configured to multiplex the plurality of time-domain data blocks that have undergone IFFT orthogonal transform into a baseband OFTDM symbol data sequence in a sequence of generation time; and a guard interval adding device, configured to The header or trailer of the baseband OFTDM symbol data sequence generates a guard interval of a specific length to generate a baseband OFTDM signal to be transmitted.
- a method for transmitting a signal over a plurality of orthogonal carriers in a wireless transmitter of a wireless communication system comprising the steps of: converting and converting an input serial symbol data sequence a plurality of parallel symbol data sequences; performing IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks; and generating the plurality of time domain data blocks subjected to the IFFT orthogonal transform according to a generation time Sequentially multiplexed into baseband OFTDM symbol data sequence; a guard interval of a specific length is added to the head or tail of the OFTDM symbol data sequence of the baseband.
- a wireless receiver for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless communication system, comprising: a guard interval removing means for removing a transform to a baseband a guard interval between guard sequences of OFTDM symbols; a data block demultiplexing apparatus for demultiplexing the guard interval-free OFTDM symbol sequence into a plurality of data block sequences; an FFT transform device, Performing FFT transformation on the plurality of data blocks in order of reception time, converting the plurality of data blocks into a plurality of parallel symbol data sequences; and a parallel to serial conversion device for converting the plurality of parallel symbol data sequences into strings Line symbol data sequence.
- the radio receiver further includes: a channel estimating apparatus, configured to estimate a channel response of the time domain according to the OFTDM symbol sequence converted to the baseband, to obtain an estimated value of the channel response; and a time/frequency a transforming apparatus, configured to transform the guard interval-removed OFTDM data block sequence into a frequency domain OFTDM data block sequence; a frequency domain equalizer, configured to convert the TOFTDM data block based on the estimated value of the channel response
- the frequency domain OFTDM data block sequence performs phase compensation and amplitude compensation of channel impairment to obtain a frequency domain equalized frequency domain OFTDM data block sequence; a frequency/time transform device for frequency domain OFTDM that has been frequency domain equalized
- the data block sequence is reconverted into a time domain OFTDM data block sequence for transmission to the data block demultiplexing device.
- a method for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless receiver of a wireless communication system comprising the steps of: removing a guard interval of a baseband OFTDM symbol; Demultiplexing the OFTDM symbol sequence of the removal guard interval into a plurality of data block sequences; performing FFT transformation on the plurality of data blocks in order of receiving time, and converting the plurality of data blocks into a plurality of parallel symbol data sequences; The plurality of parallel data symbol sequences are parallel-converted into a serial symbol data sequence.
- the receiving method further comprises the steps of: estimating a channel response of the time domain according to the OFTDM symbol sequence or the pilot training sequence transformed to the baseband, to obtain an estimated value of the channel response;
- the sequence of spaced OFTDM data blocks is transformed into a sequence of OFTDM data blocks in the frequency domain; based on the estimated value of the channel response,
- the OFTDM data block sequence transformed into the frequency domain performs phase compensation and amplitude compensation of the channel impairment to obtain a frequency domain equalized frequency domain OFTDM data block sequence; re-converts the frequency domain OFTDM data block sequence that has undergone frequency domain equalization to A sequence of OFTDM data blocks in the time domain for performing the data block demultiplexing operation.
- the wireless transmitter and receiver of the present invention are a novel combination and expansion scheme of a conventional cyclic prefix (CP) based orthogonal frequency division multiplexing (OFDM) system and a single carrier frequency domain equalization system (SC FDE), It has the advantages of low implementation complexity and high spectral efficiency of OFDM, and has the advantages of SC FDE frequency shift robustness and easy frequency synchronization; it has the same reception error performance characteristics as OFDM, and has much larger mobility than OFDM. Speed adapts to the range. Based on the OFTDM technology solution, the inherent advantages of multi-carrier communication and single-carrier communication can be simultaneously integrated on the same communication system. At the same time, their deficiencies can be avoided as much as possible, and the overall performance and complexity of the system can be better compromised.
- CP cyclic prefix
- SC FDE single carrier frequency domain equalization system
- the present invention has the spectrum adaptability of multi-carrier transmission technology (such as OFDM), the flexibility of single-carrier communication, and the transmission performance is equivalent to that of OFDM technology, and the implementation complexity is achieved.
- multi-carrier transmission technology such as OFDM
- the system can obtain a larger throughput gain and a wider range of mobile speed adaptability; design the transmitter IFFT based on the channel coherence bandwidth
- the size of the transform can improve the frequency shift robustness of the system; by introducing the CP prefix, the OFTDM can maintain the system and OFDM with similar timing robustness.
- 1 is a block diagram of a prior art OFDM radio transmitter and receiver.
- FIG. 2 is a block diagram of a wireless transmitter for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention
- FIG. 3 is a flow chart of a method for wireless transmission of signals transmitted over orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention
- FIG. 6 is a flowchart of a wireless receiving method for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network according to an embodiment of the present invention
- FIG. 7 shows a simulated schematic diagram based on the MATLAB/SIMULink simulation platform
- FIG. 8 shows three schemes of the OFTDM scheme of the present invention and the prior art OFDM and SC/FDE schemes on the simulation platform shown in FIG. The result of the simulation operation under the simulation parameters (bit error rate).
- the method includes a channel coding device 1 1 , a digital modulation device 12 , a serial to parallel conversion device 13 , an inverse Fourier transform (IDFT ) conversion device 14 , a data block multiplexing device 15 , a guard interval adding device 16 , and a shaping filter Apparatus 17, an RF inverter unit 18 and a transmitting antenna 19.
- IDFT inverse Fourier transform
- the channel coding apparatus, the digital modulation apparatus, the shaping and filtering apparatus, the RF frequency conversion apparatus, and the transmitting antenna shown in FIG. 2 are not directly related to the object of the present invention, and are only used as a preferred embodiment. And describe it.
- the channel coding rule may employ a concatenated code, such as an RS code and a convolutional code, a Turbo code, or an LDPC code, or an adaptive coding scheme composed of multiple technologies, such as adaptive coding. Modulation scheme (AMC);
- the digital modulation device 12 is used, for example, according to the Gray coding specification, to be channel coded
- the data sequence is mapped to the dot pattern of the modulation symbol.
- the selected modulation mode is determined by the system design, and can be determined as one of BPSK and QPSK QAM modulation modes, and can also be based on the bit error rate and the carrier-to-interference ratio. Multiple dynamic modulation methods for adaptive selection.
- An inverse Fourier transform (IDFT) transforming device 14 is preferably implemented by an inverse fast Fourier transform (IFFT) module for performing IDFT transform on each input parallel symbol data block to generate a corresponding plurality of time domain symbol data blocks.
- IDFT transform is equivalent to orthogonal multi-carrier modulation and synthesis of the input parallel data
- ⁇ also represents a column vector with the same number of elements and the size of the IFFT transform;
- the guard interval adding means 16 is configured to add a guard interval of a specific length to the head or the tail of the OFITM) symbol data portion after the data block multiplexing, for reducing inter-channel interference (the length of the guard interval should be greater than the channel maximum delay) Extended length).
- the guard interval adding means may employ a cyclic prefix (CP) adding means, that is, copy a part of the tail portion of the OFTDM symbol data portion to the front end of the OFTDM symbol data portion to form a final OFTDM symbol with CP, and the CP transmits the The symbol has periodicity.
- CP cyclic prefix
- ISI inter-symbol interference
- the channel signal shaping means 17 is configured to perform shaping filtering on the OFTDM signal waveform to be transmitted in accordance with the frequency template.
- the RF transform means 18 is operative to transform the baseband OFTDM symbol sequence into a radio frequency signal and transmit it to the radio channel via the transmit antenna.
- the wireless transmitter 1 further includes a control device 19 (not shown) for performing the following functions:
- FIG. 3 is a flow diagram of a method of wireless transmission for transmitting signals over orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention.
- the channel coding step, the digital modulation step, the shaping filtering step, the RF frequency conversion step, and the step of transmitting the wireless signal shown in FIG. 2 are not directly related to the purpose of the present invention, and are only a preferred embodiment. This is described together.
- .... ⁇ channel coding which is transformed into an output data sequence fc, 0, 1, 2, ..., where
- the channel coding rule may use a concatenated code, a turbo code, or an LDPC code, for example, an RS code and a convolutional code, or an adaptive coding scheme composed of multiple technologies, such as an adaptive coding modulation scheme (AMC);
- AMC adaptive coding modulation scheme
- step S102 the channel-coded data sequence is mapped to the bitmap of the modulation symbol according to the Gray coding specification, for example, and the selected modulation mode is determined by the system design, and can be determined as BPSK, QPSK, QAM modulation mode.
- One type can also be a plurality of dynamic modulation modes that are adaptively selected according to the bit error rate and the carrier frequency ratio.
- step S103 the serial symbol sequence after symbol modulation is divided into a plurality of serial symbol data blocks according to the size of the subsequent IFFT transformation matrix, and the serial-to-parallel conversion operation is performed on the plurality of serial symbol data blocks.
- step S104 IDFT transform is performed on each input parallel symbol data block to generate a corresponding plurality of time domain symbol data blocks (where the IDFT transform is equivalent to performing orthogonal multi-carrier modulation and synthesis on the input parallel data).
- the IDFT transform can be implemented by an inverse fast Fourier transform (IFFT) algorithm.
- IFFT inverse fast Fourier transform
- step S105 a specific number of IFFT-transformed data blocks are multiplexed into the data portion of the longer orthogonal frequency division time division multiplexing (OFTDM) symbol in the order of generation.
- OFTDM orthogonal frequency division time division multiplexing
- a guard interval of a specific length is added to the header or the tail of the OFITM) symbol data portion after the data block multiplexing, for reducing inter-channel interference (the length of the guard interval should be greater than the maximum delay spread length of the channel) ).
- the guard interval is a loop a prefix (CP), that is, a portion of the tail portion of the OFTDM symbol data portion is copied to the front end of the OFTDM symbol data portion to form a final OFTDM.
- dance number with the CP, and the CP causes the transmitted symbol to have periodicity, when the CP The length of the signal is longer than the maximum delay of the signal transmitted in the channel.
- ISI Inter-symbol interference
- a column vector of the same size as the symbol, and its structure is shown in Figure 4;
- step S107 the OFTDM signal waveform to be transmitted is shaped and filtered according to the frequency template.
- step S108 the OFTDM symbol sequence of the baseband is converted into a radio frequency signal; in step S109, it is transmitted to the radio channel via the transmitting antenna.
- the wireless transmitting method of the present invention further comprises the following control steps:
- 3) corresponding to the Doppler frequency shift (or channel coherence time) size change to expand or reduce the number of transmitter IFFT time domain multiplexing; and adjust the data block complex according to the channel coherence time length
- the number is used such that the equivalent time length of its OFTDM symbol is less than the channel coherence time length.
- the wireless receiver includes a matched filtering/synchronizing device 21, and Guard interval removing means 22, channel estimating means 23, frequency/time converting means 24, single-point frequency domain equalizing means 25, time/frequency converting means 26, block demultiplexing means 27, FFT converting means 28, parallel/serial conversion The device 29, the decoding device 30, and the channel decoding device 31.
- the matched filter device, the decoding device, and the channel decoding device for baseband processing are not directly related to the object of the present invention, and are merely described as a preferred embodiment.
- the wireless receiver should also include a receiving antenna for receiving wireless signals and a radio frequency converting device for downconverting the wireless signals to the baseband, which are not directly related to the object of the present invention, for the sake of simplicity, in the figure Not shown.
- the radio receiver 2 can obtain a baseband signal 3 ⁇ 4, O, l, 2, L ⁇ through the receiving antenna and the R radio frequency conversion module.
- the wireless receiver of the present invention will be described in detail with reference to FIG. 5 in conjunction with FIG. 6:
- the guard interval removal means 22 is used to remove the guard interval added to the OFTDM symbol sequence.
- the guard interval is a cyclic prefix
- it is used to remove the cyclic prefix (CP) of the OFTDM symbol front end, thereby eliminating interference between OFTDM symbols.
- the FFT transforms the same column vector size;
- the time/frequency conversion device 24 is configured to transform the received time-domain data block of a certain length into the frequency domain, so that the frequency domain equalizer can eliminate the influence of the channel on the data block.
- the time/frequency conversion device can It is implemented by algorithms such as DFT and FFT transform.
- the frequency domain equalization means 25 is operative based on the channel estimation value provided by the channel estimation means 23.
- the phase and amplitude compensation of the channel impairment is performed on the OFTDM symbol data of the removed cyclic prefix in the frequency domain.
- ZF single-point zero-forcing
- the frequency/time transforming means 26 is configured to recover the frequency domain subband signal synthesis that has undergone frequency domain equalization into the time domain for further processing.
- the frequency/time transforming apparatus may use an algorithm such as IDFT, IFFT transform or the like. achieve.
- IDFT IDFT
- IFFT transform IFFT transform
- the data block demultiplexing means 27 is for demultiplexing the data block of the same size as the data portion of the OFTDM symbol of the radio transmitter side into a data block sequence of the same size as the radio transmitter side IFFT transform matrix.
- the FFT transforming means 28 of the same size as the transform matrix of the OFTDM transmitter-side IFFT transforming apparatus is configured to perform an inverse operation corresponding to the transmitter-side IFFT transform on the plurality of symbol data blocks for inputting the time-domain data block. Remap to the frequency domain.
- FIG. 6 is a flow chart of a wireless receiving method for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention.
- step S201 receiving a wireless signal through the receiving antenna
- step S203 the received baseband OFTDM signal is matched and filtered, and at the same time, the time-frequency synchronization function of the received signal is completed.
- step S204 the guard interval added to the OFTDM symbol sequence is removed.
- the guard interval is a cyclic prefix, it is used to remove the cyclic prefix (CP) of the OFTDM symbol front end, thereby eliminating interference between OFTDM symbols.
- step S206 a certain length of the received data block is transformed into the frequency domain, so that the influence of the channel on the data block can be eliminated by frequency domain equalization.
- the step can be adopted. DFT, FFT transform and other algorithms to achieve.
- the OFTDM symbol data is used for phase and amplitude compensation of channel impairments.
- the frequency domain equalization device may use a single-point frequency-domain minimum mean square error MMSE equalizer or a single-point frequency-domain zero-forcing equalizer.
- the relationship is:
- step S208 the frequency domain subband signal synthesis that has undergone frequency domain equalization is restored to the time domain for further processing.
- it can be implemented by an algorithm such as IDFT, IFFT transform or the like.
- step S209 the data block of the same size as the OFTDM symbol data portion of the radio transmitter side is demultiplexed into a data block sequence of the same size as the radio transmitter side IFFT transform matrix.
- step S210 performing an inverse operation corresponding to the transmitter-side IFFT transformation on the plurality of symbol data blocks by using an FFT transformation matrix of the same size as the OFTDM transmitter-side IFFT transformation matrix, for inputting the time domain data.
- the block is remapped into the frequency domain.
- step S211 the input parallel symbol data block sequence is parallel/serial converted into serial Symbolic data sequence.
- step S212 the input data sequence is demodulated into a corresponding digital sequence according to the Gray coding rule of the transmitter. If the channel decoding algorithm to be executed is based on hard decision input information, the output hard information digital sequence is a random arrangement of ⁇ 0 ⁇ and ⁇ 1 ⁇ , otherwise, a corresponding soft information digital sequence based on digital quantization is output.
- step S213 the channel decoding algorithm is performed based on the channel coding rules of the transmitter.
- Figure 7 shows the simulation schematic based on the MATLAB/SIMULink simulation platform
- FIG. 8 shows the result (bit error rate) obtained by performing simulation operations on the simulation scheme of the present invention on the simulation platform shown in FIG. 6 and the prior art OFDM and SC/FDE schemes under the following simulation parameters.
- the error rate of the OFTDM of the present invention is significantly better than the error rate of the SC/FDE scheme, which is comparable to the error rate of OFDM, but due to the implementation complexity of the present invention (256 subcarriers) due to OFDM (2048 subcarriers), so the present invention achieves a good compromise between performance and implementation complexity.
- Channel bandwidth 10M
- channel model SUI-4
- channel coding convolutional code (coding: code rate 1/2, constraint length 7, generator polynomial [171, 133], decoding: 8 levels of 3 bit quantization, Viterbi soft translation Code, decoding depth 34)
- Frequency domain equalization points 2048, frequency domain equalization method: single point zero forcing (ZF) equalizer; Simulation schematic based on MATLAB/SIMULink simulation platform:
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Abstract
Techniques are provided to support orthogonal multiple carriers frequency-time division multiplex based on orthogonal frequency division multiplex and single carrier with frequency domain equalization in prior art. At a transmitter end, Serial to Parallel Transform and Inverse Fast Fourier Transform are performed for the input serial data stream, then data blocks after IFFT are multiplexed to be a OFTDM symbol data part in temporal sequence; and then a circulation prefix is added in its front-part to form a final OFTDM symbol. At a receiver end, the CP in the front-part of the OFTDM symbol down-converted to a baseband is removed, and after the operations of data de-multiplex, FFT and P/S corresponding to the transmitter end are performed, the original serial data stream is recovered. Except for including the advantage of said prior art, this disclosure can overcome their disadvantage, and a preferable tradeoff between the general performance and complexity of the system can be acquired.
Description
一种正交频分时分发射机、 接收机及其方法 技术领域 Orthogonal frequency division time division transmitter, receiver and method thereof
本发明涉及无线通信技术, 尤其涉及一种在无线通信系统中通过 多个正交载波来传输信号的技术。 背景技术 The present invention relates to wireless communication technologies, and more particularly to a technique for transmitting signals over a plurality of orthogonal carriers in a wireless communication system. Background technique
在无线通信系统中, 尤其在宽带移动通信系统中, 空中信号传输技 术正成为研究的焦点。 为了获得较高的, 例如高达 lObps/Hz的, 频谱效 率, 支持多种场景的通信需求, 支持各种自适应控制技术, 宽带移动通 信系统的信号传输技术必须支持比以往任何一种同类技术更好的性能, 同时维持可控制的实现复杂度。 现在, 宽带移动通信的信号传输技术主 要以 OFDM (正交频分复用)技术为基础, 并衍生出各种变种技术, 如 OFDMA (正交频分多址)、 MC-CDMAC多载波-码分多址)、 MT-CDMA (多音-码分多址)、 VSF-OFCDM (正交频分码分复用)等, 此外, 基 于滤波器组的广义多载波调制技术(GMC )和传统 CDMA的增强技术 CP-CDMA (循环前缀 -码分多址)等也受到人们的关注和重视。 In wireless communication systems, especially in broadband mobile communication systems, airborne signal transmission technology is becoming the focus of research. In order to obtain higher, for example, up to lObps/Hz, spectral efficiency, support communication requirements of multiple scenarios, and support various adaptive control technologies, the signal transmission technology of broadband mobile communication systems must support more than any similar technology in the past. Good performance while maintaining controllable implementation complexity. Now, the signal transmission technology of broadband mobile communication is mainly based on OFDM (Orthogonal Frequency Division Multiplexing) technology, and various variant technologies such as OFDMA (Orthogonal Frequency Division Multiple Access) and MC-CDMAC Multi-Carrier-Code are derived. Multiple access), MT-CDMA (multi-tone-code division multiple access), VSF-OFCDM (orthogonal frequency division code division multiplexing), etc. In addition, filter bank based generalized multi-carrier modulation (GMC) and traditional The enhanced technology of CDMA, CP-CDMA (Cyclic Prefix-Code Division Multiple Access), has also received attention and attention.
然而, 综合现有这些传输技术的性能, 它们在一定的条件下均表现 出优越的性能, 但是, 适用的场景仍然不够宽广, 例如, OFDM技术的 符号长度、 CP长度和频谱利用率直接相关,影响了它对不同地形和移动 场景的适应性设计, 而且由它衍生出来的其它技术也有这个缺点; 而单 载波技术, 如 CP-CDMA等技术对于信道频域的适应性不够, 直接影响 了它的频域分集性能; 而置于 OFDM技术和单载波技术之间的 GMC技 术, 则不具备象 OFDM和 CP - CDMA等技术那样的内在的、 对信道时 频平面的适应性, 在实现复杂度上显得人工痕迹很重, 设计不够自然, 同时, 它也存在和 OFDM技术一样的、 场景适应性较差的缺点。 However, combining the performance of existing transmission technologies, they show superior performance under certain conditions. However, the applicable scenarios are still not broad enough. For example, the symbol length, CP length and spectrum utilization of OFDM technology are directly related. It affects its adaptability to different terrain and mobile scenes, and other technologies derived from it also have this disadvantage; while single-carrier technology, such as CP-CDMA, has insufficient adaptability to the channel frequency domain, directly affecting it. Frequency domain diversity performance; the GMC technology placed between OFDM technology and single carrier technology does not have the inherent adaptability to the channel time-frequency plane like OFDM and CP-CDMA technology, in the implementation complexity It appears that the artificial trace is heavy and the design is not natural enough. At the same time, it also has the same shortcomings as the OFDM technology and the poor adaptability of the scene.
与本发明密切相关的技术主要有 OFDM和 SC/FDE (单载波 -频域 均衡) 两种, 它们分别代表了两种不同的信息传输方法: 多载波通信和 单载波通信。
正交频分复用 (OFDM )是一种多载波调制技术, 它采用并行传输, 将所传送的高速数据分解并调制到多个重叠但又正交的子信道(频域) 中, 使得每个调制信号的周期大于多径时延扩展, 若'在调制符号之间增 加一定宽度的保护间隔, 则多径传输引起的符号间干扰基本上被消除, 因此 OFDM系统具有很高的频谱利用率,对多径传输引起的符号间干扰 具有很强的鲁棒性, 能够支持高速数据传输。 The technologies closely related to the present invention mainly include OFDM and SC/FDE (single carrier-frequency domain equalization), which respectively represent two different information transmission methods: multi-carrier communication and single-carrier communication. Orthogonal Frequency Division Multiplexing (OFDM) is a multi-carrier modulation technique that uses parallel transmission to decompose and modulate the transmitted high-speed data into multiple overlapping but orthogonal subchannels (frequency domain), such that each The period of the modulated signals is larger than the multipath delay spread. If a guard interval of a certain width is added between the modulation symbols, the intersymbol interference caused by the multipath transmission is basically eliminated, so the OFDM system has a high spectrum utilization rate. It is robust to inter-symbol interference caused by multipath transmission and can support high-speed data transmission.
OFDM这种多载波通信方法将要传输的符号序列映射到并行的多个 子载波上去发送; 在传输过程中, 每个子载波上的符号仅为其对应的子 信道幅频响应加权, 以及高斯加性噪声污染; 在接收侧, 只要将子信道 的幅频响应归一, 就可以估计出子载波上发送来的符号, 从而估计到发 送序列。 为了便于在接收侧无损地均衡子信道的幅频响应特性, 必须在 每个 OFDM发送符号的前端添加至少长度为信道最大时延扩展的循环 前缀(CP ), 它是从 OFDM符号的尾端拷贝来的。 The multi-carrier communication method of OFDM maps a sequence of symbols to be transmitted to a plurality of parallel sub-carriers for transmission; in the transmission process, symbols on each sub-carrier are only weighted by their corresponding sub-channel amplitude-frequency responses, and Gaussian additive noise Contamination; On the receiving side, as long as the amplitude-frequency response of the sub-channel is normalized, the symbols transmitted on the sub-carriers can be estimated, thereby estimating the transmission sequence. In order to facilitate the lossless equalization of the amplitude-frequency response characteristics of the subchannels on the receiving side, a cyclic prefix (CP) having a length of the channel maximum delay spread must be added at the front end of each OFDM transmission symbol, which is copied from the tail end of the OFDM symbol. Come.
图 1为现有技术中的 OFDM无线发射机和接收机的框图。 其中, 无 线发射机 1,包括一个串并转换装置 11,, 用于将经过数据调制映射得到 的串行符号流串并转换为多个并行符号流; 一个 IFFT变换装置 12,, 用 于通过逆 IDFT变换来将所述多个并行符号流调制到多个正交子载波上 并合成为 OFDM符号; 一个加 CP装置 13,, 用于将所述 OFDM符号尾 部的一部分复制到符号的前端, 形成最终的带 CP的 OFDM符号, CP 使所传输的符号具有周期性, 当 CP的长度比信号在信道中传输的延迟 时间长, 则码间干扰(ISI )仅仅会影响 OFDM符号前端的 CP, 从而在 接收机端可以简单通过去除 CP就可消除 ISI。 当然, 该无线发射机还应 包括: 用于对输入的数据进行信道编码和数据调制的信道编码和调制装 置; 以及将 OFDM符号进行 D/A变换和模拟信号处理(例如信道成形 滤波), 并调制到射频, 然后通过天线发送出去, 由于这些部分与本发 明并无直接关系, 因此为简明起见, 在此省略。 1 is a block diagram of a prior art OFDM radio transmitter and receiver. The wireless transmitter 1 includes a serial to parallel conversion device 11 for converting and converting a serial symbol stream obtained by data modulation mapping into a plurality of parallel symbol streams; and an IFFT conversion device 12 for IDFT transforming to modulate the plurality of parallel symbol streams onto a plurality of orthogonal subcarriers and synthesizing into OFDM symbols; a CP adding device 13 for copying a portion of the OFDM symbol tail to a front end of the symbol to form The final OFDM symbol with CP, CP makes the transmitted symbol have periodicity. When the length of the CP is longer than the delay time of the signal transmitted in the channel, the inter-symbol interference (ISI) only affects the CP of the OFDM symbol front end. ISI can be eliminated at the receiver by simply removing the CP. Of course, the wireless transmitter should further include: channel coding and modulating means for channel coding and data modulation of the input data; and performing D/A conversion and analog signal processing (eg, channel shaping filtering) on the OFDM symbol, and Modulation to the radio frequency and then transmission through the antenna, since these parts are not directly related to the present invention, they are omitted here for the sake of brevity.
相应地, 在接收机 2,中, 包括一个去 CP装置 21,, 用于将下变频到 基带所获得的 OFDM符号前端的 CP去除; 一个 FFT装置 22,, 用于通 过 DFT变换来对去除 CP后的 OFDM符号进行相关解调, 获得解调后
的并行符号流; 一个并串转换装置 23,, 用于将所解调得到的并行符号 流并串转换为串行符号流。 当然, 该无线接收机机还应包括接收射频信 号的接收天线; 将射频信号下变频到基带的下变频装置和对下变频后的 基带信号进行匹配滤波的匹配滤波装置等; 以及, 基于发射端的信道编 码和调制规则来对所述串行符号流进行相应的信道译码和解调, 从而获 得最初传输的信号流的信道译码和解调装置, 由于这些部分与本发明并无 直接关系, 因此为简明起见, 在此省略。 Correspondingly, in the receiver 2, including a de-CP device 21, for removing the CP of the OFDM symbol front end obtained by down-converting to the baseband; an FFT device 22, for removing the CP by DFT transform After the OFDM symbol is correlated and demodulated, after demodulation is obtained Parallel symbol stream; a parallel to serial conversion device 23 for parallel-converting the demodulated parallel symbol stream into a serial symbol stream. Of course, the wireless receiver machine should further include a receiving antenna for receiving the radio frequency signal; a downconverting device for downconverting the radio frequency signal to the baseband; and a matching filtering device for performing matched filtering on the downconverted baseband signal; and, based on the transmitting end Channel coding and modulation rules for channel decoding and demodulation of the serial symbol stream to obtain channel decoding and demodulation means for the initially transmitted signal stream, since these portions are not directly related to the present invention, Therefore, for the sake of brevity, it is omitted here.
与传统的基于横向滤波器架构的接收机的单载波通信系统相比, OFDM系统的实现复杂度低(基于 IFFT/FFT实现子信道信号成形和接 收匹配滤波), 频语效率高, 便于在宽带无线通信系统中的应用, 但是, OFDM的频谱利用率和功率效率随着 CP在 OFDM中包含的 CP长度的 增长而下降, 并且, 为了保持较高水平的频谱利用率和功率效率, 不得 数以上(例如, 至少为 4倍), 这样, 就直接导致了 OFDM符号的子载 波数量在宽带无线通信场景下一般呈现较大的数值(例如, 256 个子载 波), 致使子载波的等效带宽远远小于信道的相干带宽, 提升了接收机 对频率同步精度的敏感度, 并且降低了 OFDM系统的频域分集性能; 同 时, 因大数量子载波的时域叠加造成了发送信号峰均比的大幅度提升, 又提高了发射机对功率放大期线形度的指标要求。 总之, OFDM虽然对 信道时频平面的适应性较强, 但是, 它的符号设计长度受频谱利用率的 影响太大, 频域子载波划分富有冗余, 非常不利于在移动速度快、 载波 频率高、多普勒 (Doppler)频移大的通信场景中使用;反之,在低速移动、 载波频率低、 Doppler频移小的通信场景中, OFDM符号的长度又不能 适当加长, 以提升频谱利用率, 因此, 整个 OFDM系统的设计显得比较 呆板, 其符号长度必须针对通信场景的恶劣场景设计, 从而导致了潜在 的容量损失。 Compared with the traditional single-carrier communication system based on the transverse filter architecture, the OFDM system has low implementation complexity (sub-channel signal shaping and receive matching filtering based on IFFT/FFT), high frequency efficiency, and easy to be used in broadband. Applications in wireless communication systems, however, the spectrum utilization and power efficiency of OFDM decreases as the CP length of the CP is included in OFDM, and in order to maintain a high level of spectrum utilization and power efficiency, no more than (for example, at least 4 times), thus directly causing the number of subcarriers of the OFDM symbol to generally exhibit a large value (for example, 256 subcarriers) in a broadband wireless communication scenario, so that the equivalent bandwidth of the subcarrier is far Less than the coherence bandwidth of the channel improves the receiver's sensitivity to frequency synchronization accuracy and reduces the frequency domain diversity performance of the OFDM system. At the same time, the time-domain superposition of a large number of subcarriers causes a large amplitude-to-average ratio of the transmitted signal. The upgrade also increases the transmitter's requirements for the linearity of the power amplification period. In short, although OFDM has strong adaptability to the channel time-frequency plane, its symbol design length is greatly affected by spectrum utilization, and frequency domain subcarrier division is redundant, which is not conducive to fast moving speed and carrier frequency. In high-Doppler communication scenarios with large frequency shifts; conversely, in low-speed mobile, low carrier frequency, and small Doppler frequency shift scenarios, the length of OFDM symbols cannot be lengthened appropriately to improve spectrum utilization. Therefore, the design of the entire OFDM system appears to be rather rigid, and its symbol length must be designed for the harsh scene of the communication scenario, resulting in potential capacity loss.
SC/FDE (单载波频域均衡)通信系统与传统的单载波通信系统非常 接近, 但是, 它将发送的符号序列划分成一块块等长的数据块, 并为每 个数据块拷贝一个循环前缀(CP ),这个 CP的设计原则类同于本发明的
OFDM正交频分复用系统, 所不同的是待拷贝的数据是各个数据块的尾 部。 这样, 接收机侧就可以基于频域均衡方法对信道相应进行均衡, 从 而修复信道对发送符号的损伤, 进而估计出相应的发送符号序列。 SC/FDE系统实现复杂度低(接收端基于 FFT/IFFT变换和单点迫零均衡 器完成频域均衡), 有完备的均衡器设计准则, 信号峰均比不高, CP和 数据块的长度设计比较灵活,便于在宽带无线通信系统中的应用,但是, 这种方案的设计没有考虑对信道时频特性的适应性, 致使接收机很难提 供给信道译码较大的频域分集增益, 综合性能不高; 同时, 单载波接收 算法容易造成噪声增强和扩散的后果, 这也会严重影响系統的接收误码 性能。 The SC/FDE (single-carrier frequency-domain equalization) communication system is very close to the traditional single-carrier communication system, but it divides the transmitted symbol sequence into blocks of equal length and copies a cyclic prefix for each data block. (CP), the design principle of this CP is similar to the present invention. The OFDM orthogonal frequency division multiplexing system differs in that the data to be copied is the tail of each data block. In this way, the receiver side can equalize the channel according to the frequency domain equalization method, thereby repairing the damage of the channel to the transmitted symbol, and then estimating the corresponding transmitted symbol sequence. SC/FDE system has low implementation complexity (the receiving end is based on FFT/IFFT transform and single-point zero-forcing equalizer to complete frequency domain equalization), and has complete equalizer design criteria, signal peak-to-average ratio is not high, CP and data block length The design is flexible and easy to use in broadband wireless communication systems. However, the design of this scheme does not consider the adaptability to the channel time-frequency characteristics, making it difficult for the receiver to provide a large frequency domain diversity gain for channel decoding. The comprehensive performance is not high; at the same time, the single-carrier receiving algorithm is likely to cause the noise enhancement and proliferation, which will seriously affect the receiving error performance of the system.
本发明正是为了解决现有技术中存在的上述问题而提出的。 发明内容 The present invention has been made to solve the above problems existing in the prior art. Summary of the invention
本发明是在综合各种传统单载波和多载波传输技术优缺点的基础上 提出的一种新型的正交多载波频分时分技术 - OFTDM。 The invention is a novel orthogonal multi-carrier frequency division time division technique-OFTDM which is proposed based on combining the advantages and disadvantages of various conventional single-carrier and multi-carrier transmission technologies.
本发明的无线发射机首先基于快速傅立叶逆变换(IFFT )将经过串 并转换后的多个并行调制符号流变换成相应长度的数据块序列, 并对多 个经过 IFFT变换的数据块按照时间顺序进行数据块复用, 将复用后的 多个数据块定义为一个 OFTDM (正交频分一时分复用)符号数据部分;其 次,将该 OFTDM符号数据部分的尾部多个数据拷贝,作为循环前缀( CP ) 部分, 到该 OFTDM符号数据部分的最前部, 从而生成该 OFTDM符号 的; 再次, 对 OFTDM符号的组成部分(数据部分和 CP部分)进行信 道成形滤波; 最后,将 OFTDM系统的基带信号变换成射频(RF )信号, 并由天线系统辐射到无线信道上去。 The wireless transmitter of the present invention first converts the serial-parallel converted plurality of parallel modulation symbol streams into a sequence of data blocks of a corresponding length based on an inverse fast Fourier transform (IFFT), and chronologically processes the plurality of IFFT-transformed data blocks. Performing block multiplexing, defining a plurality of multiplexed data blocks as one OFTDM (orthogonal frequency division-time division multiplexing) symbol data portion; secondly, copying a plurality of data at the tail of the OFTDM symbol data portion as a loop a prefix (CP) portion to the forefront of the OFTDM symbol data portion to generate the OFTDM symbol; again, channel shaping filtering of the OFTDM symbol components (data portion and CP portion); and finally, the baseband of the OFTDM system The signal is converted to a radio frequency (RF) signal and radiated by the antenna system onto the wireless channel.
本发明的无线接收机首先将接收到的无线信号变换成基带信号 , 并 对接收信号进行匹配滤波, 完成符号定时和频率同步; 随后, 去除 OFTDM符号前端的循环前缀, 再对 OFTDM符号的数据部分进行解复 用, 恢复成和发送端长度一样的多个数据块序列; 最后, 基于 FFT傅立 叶变换将发送端数据块映射为相应的调制符号流。 优选地, 还可在进行
OFTDM符号数据部分的解复用之前, 基于信道估计、 与 OFTDM符号 的数据部分长度相等的 FFT/IFFT正反傅立叶变换、 信道均衡器等实现 OFTDM符号级别的频域均衡(FDE ), 再将经过频域均衡的 OFTDM符 号数据部分提供给解复用步骤。 The wireless receiver of the present invention first converts the received wireless signal into a baseband signal, and performs matched filtering on the received signal to complete symbol timing and frequency synchronization; subsequently, removes the cyclic prefix of the OFTDM symbol front end, and then the data portion of the OFTDM symbol. Demultiplexing is performed to restore a plurality of data block sequences of the same length as the transmitting end; finally, the transmitting end data block is mapped to the corresponding modulation symbol stream based on the FFT Fourier transform. Preferably, it can also be carried out Before demultiplexing the OFTDM symbol data portion, the OFTDM symbol level frequency domain equalization (FDE) is implemented based on channel estimation, FFT/IFFT forward and inverse Fourier transform equal to the length of the data portion of the OFTDM symbol, and channel equalizer. The frequency domain equalized OFTDM symbol data portion is provided to the demultiplexing step.
优选地,在本发明的无线发射机中,还提出如下用于对 IFFT变换矩 阵大小、 循环前缀长度以及数据块解复用的数目进行调整的控制方法: Preferably, in the wireless transmitter of the present invention, the following control method for adjusting the IFFT transform matrix size, the cyclic prefix length, and the number of data block demultiplexing is also proposed:
1 )根据信道带宽和信道时延长度来调整所述 IFFT变换装置的变换 矩阵的大小; 1) adjusting the size of the transform matrix of the IFFT transform device according to the channel bandwidth and the channel time extension;
2 )根据信道时延扩展的长度和 IFFT 变换矩阵的大小来调整所述循 环前缀的长度, 使其大于等于信道时延扩展的长度, 和小于等于所述 IFFT变换矩阵的大小; 也即, 循环前缀(CP ) 必须大于信道 展长度; 发射机 IFFT变换长度至少大于 CP长度(在通信过程中保持不变); 2) adjusting the length of the cyclic prefix according to the length of the channel delay spread and the size of the IFFT transform matrix to be greater than or equal to the length of the channel delay spread, and less than or equal to the size of the IFFT transform matrix; that is, the loop The prefix (CP) must be greater than the channel spread length; the transmitter IFFT transform length is at least greater than the CP length (which remains unchanged during communication);
3 ) 与多普勒 (Doppler )频移 (或者信道相干时间) 的大小变化相 应地调整发射机 IFFT变换数据块时域复用的数量, 以使其 OFTDM符 号的等效时间长度小于所述信道相干时间长度。 3) adjusting the number of time domain multiplexing of the transmitter IFFT transform data block according to the change of the Doppler frequency shift (or channel coherence time), so that the equivalent time length of the OFTDM symbol is smaller than the channel Coherence time length.
根据本发明的第一方面, 提供了一种在无线通信系统中用于通过多个 正交载波传输信号的无线发射机, 包括: 一个串并转换装置, 用于将输入 的串行符号数据序列串并转换多个并行的符号数据序列; 一个 IFFT 变 换装置, 用于对所述多个并行符号数据序列中进行 IFFT正交变换, 生 成多个时域数据块; 其特征在于, 还包括: 一个数据块复用装置, 用于将 所述经过 IFFT正交变换后的多个时域数据块按生成时间的先后顺序复 用为基带的 OFTDM符号数据序列; 和一个保护间隔添加装置, 用于在 所述基带的 OFTDM符号数据序列头部或尾部生成特定长度的保护间 隔, 以生成待传输的基带 OFTDM信号。 According to a first aspect of the present invention, there is provided a wireless transmitter for transmitting signals over a plurality of orthogonal carriers in a wireless communication system, comprising: a serial to parallel conversion device for inputting serial symbol data sequences Serializing and converting a plurality of parallel symbol data sequences; an IFFT transforming apparatus, configured to perform IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks; and further comprising: a data block multiplexing device, configured to multiplex the plurality of time-domain data blocks that have undergone IFFT orthogonal transform into a baseband OFTDM symbol data sequence in a sequence of generation time; and a guard interval adding device, configured to The header or trailer of the baseband OFTDM symbol data sequence generates a guard interval of a specific length to generate a baseband OFTDM signal to be transmitted.
根据本发明的第二方面, 提供了一种在无线通信系统的无线发射机 中用于通过多个正交载波发送信号的方法, 其包括以下步骤: 将输入的 串行符号数据序列串并转换多个并行符号数据序列; 对所述多个并行符 号数据序列进行 IFFT正交变换,生成多个时域数据块;将所述经过 IFFT 正交变换后的多个时域数据块按生成时间的先后顺序复用为基带的
OFTDM符号数据序列; 在所述基带的 OFTDM符号数据序列头部或尾 部添加特定长度的保护间隔。 According to a second aspect of the present invention, there is provided a method for transmitting a signal over a plurality of orthogonal carriers in a wireless transmitter of a wireless communication system, comprising the steps of: converting and converting an input serial symbol data sequence a plurality of parallel symbol data sequences; performing IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks; and generating the plurality of time domain data blocks subjected to the IFFT orthogonal transform according to a generation time Sequentially multiplexed into baseband OFTDM symbol data sequence; a guard interval of a specific length is added to the head or tail of the OFTDM symbol data sequence of the baseband.
根据本发明的第三方面, 提供了一种在无线通信系统中用于接收通 过多个正交载波传输的 OFTDM信号的无线接收机,其包括:一个保护间 隔去除装置, 用于去除变换到基带的具有保护间隔的 OFTDM符号序列 之间的保护间隔; 一个数据块解复用装置, 用于将所述去除保护间隔的 OFTDM符号序列解复用为多个数据块序列; 一个 FFT变换装置, 用于 按接收时间的先后顺序对所述多个数据块进行 FFT变换,将其变换为多 个并行符号数据序列; 和一个并串转换装置, 用于将所述多个并行符号 数据序列变换为串行符号数据序列。 According to a third aspect of the present invention, there is provided a wireless receiver for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless communication system, comprising: a guard interval removing means for removing a transform to a baseband a guard interval between guard sequences of OFTDM symbols; a data block demultiplexing apparatus for demultiplexing the guard interval-free OFTDM symbol sequence into a plurality of data block sequences; an FFT transform device, Performing FFT transformation on the plurality of data blocks in order of reception time, converting the plurality of data blocks into a plurality of parallel symbol data sequences; and a parallel to serial conversion device for converting the plurality of parallel symbol data sequences into strings Line symbol data sequence.
优选地, 所述无线接收机还包括: 一个信道估计装置, 用于根据所 述变换到基带的 OFTDM符号序列来对时域的信道响应进行估计, 以获 得信道响应的估计值; 一个时 /频变换装置, 用于将所述去除保护间隔的 OFTDM数据块序列变换为频域的 OFTDM数据块序列; 一个频域均衡 器,用于基于所述信道响应的估计值,来对所述被变换到频域的 OFTDM 数据块序列进行信道损伤的相位补偿和幅度补偿 , 以获得经过频域均衡 的频域 OFTDM数据块序列; 一个频 /时变换装置, 用于将已经过频域均 衡的频域 OFTDM数据块序列重新变换为时域的 OFTDM数据块序列, 传输给所述数据块解复用装置。 Preferably, the radio receiver further includes: a channel estimating apparatus, configured to estimate a channel response of the time domain according to the OFTDM symbol sequence converted to the baseband, to obtain an estimated value of the channel response; and a time/frequency a transforming apparatus, configured to transform the guard interval-removed OFTDM data block sequence into a frequency domain OFTDM data block sequence; a frequency domain equalizer, configured to convert the TOFTDM data block based on the estimated value of the channel response The frequency domain OFTDM data block sequence performs phase compensation and amplitude compensation of channel impairment to obtain a frequency domain equalized frequency domain OFTDM data block sequence; a frequency/time transform device for frequency domain OFTDM that has been frequency domain equalized The data block sequence is reconverted into a time domain OFTDM data block sequence for transmission to the data block demultiplexing device.
根据本发明的第四方面, 提供了一种在无线通信系统的无线接收机 中用于接收通过多个正交载波传输的 OFTDM信号的方法, 其包括以下 步驟: 去除基带 OFTDM 符号的保护间隔; 将所述去除保护间隔的 OFTDM符号序列解复用为多个数据块序列; 按接收时间的先后顺序对 所述多个数据块进行 FFT变换,将其变换为多个并行符号数据序列;和, 将所述多个并行数据符号序列并串变换为串行符号数据序列。 According to a fourth aspect of the present invention, a method for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless receiver of a wireless communication system, comprising the steps of: removing a guard interval of a baseband OFTDM symbol; Demultiplexing the OFTDM symbol sequence of the removal guard interval into a plurality of data block sequences; performing FFT transformation on the plurality of data blocks in order of receiving time, and converting the plurality of data blocks into a plurality of parallel symbol data sequences; The plurality of parallel data symbol sequences are parallel-converted into a serial symbol data sequence.
优选地, 所述接收方法还包括以下步骤: 根据所述变换到基带的 OFTDM符号序列或导频训练序列来对时域的信道响应进行估计, 以获 得信道响应的估计值; 将所述去除保护间隔的 OFTDM数据块序列变换 为频域的 OFTDM数据块序列; 基于所述信道响应的估计值, 来对所述
被变换到频域的 OFTDM数据块序列进行信道损伤的相位补偿和幅度补 偿, 以获得经过频域均衡的频域 OFTDM数据块序列; 将已经过频域均 衡的频域 OFTDM数据块序列重新变换为时域的 OFTDM数据块序列, 用于进行所述数据块解复用操作。 Preferably, the receiving method further comprises the steps of: estimating a channel response of the time domain according to the OFTDM symbol sequence or the pilot training sequence transformed to the baseband, to obtain an estimated value of the channel response; The sequence of spaced OFTDM data blocks is transformed into a sequence of OFTDM data blocks in the frequency domain; based on the estimated value of the channel response, The OFTDM data block sequence transformed into the frequency domain performs phase compensation and amplitude compensation of the channel impairment to obtain a frequency domain equalized frequency domain OFTDM data block sequence; re-converts the frequency domain OFTDM data block sequence that has undergone frequency domain equalization to A sequence of OFTDM data blocks in the time domain for performing the data block demultiplexing operation.
本发明的无线发射机和接收机是传统基于循环前缀(CP ) 的正交频 分复用系统(OFDM )和单载波频域均衡系统(SC FDE )的一种新颖的 结合和扩展方案, 既具有 OFDM的低实现复杂度、 高频谱效率的优点, 又具有 SC FDE的频移稳健、 易于频率同步的优点; 既具有和 OFDM等 同的接收误码性能特性, 又具有比 OFDM大得多的移动速度适应范围。 基于 OFTDM技术方案, 可以在同一种通信系统上同时集成多载波通信 和单载波通信的内在优势, 同时, 又可以尽量避免它们的不足, 使系统 总体性能和复杂度达到较好的折衷。 The wireless transmitter and receiver of the present invention are a novel combination and expansion scheme of a conventional cyclic prefix (CP) based orthogonal frequency division multiplexing (OFDM) system and a single carrier frequency domain equalization system (SC FDE), It has the advantages of low implementation complexity and high spectral efficiency of OFDM, and has the advantages of SC FDE frequency shift robustness and easy frequency synchronization; it has the same reception error performance characteristics as OFDM, and has much larger mobility than OFDM. Speed adapts to the range. Based on the OFTDM technology solution, the inherent advantages of multi-carrier communication and single-carrier communication can be simultaneously integrated on the same communication system. At the same time, their deficiencies can be avoided as much as possible, and the overall performance and complexity of the system can be better compromised.
更具体地, 与现有技术相比, 本发明既具有多载波传输技术(如 OFDM ) 的频谱适应性, 又具有单载波通信的灵活性, 并且在传输性能 上与 OFDM技术相当, 实现复杂度较低。 更为重要的是, 通过控制发射 机 IFFT变换数据块时域复用数量的大小, 系统可以获得较大的吞吐量 增益, 范围更加宽广的移动速度适应性; 通过基于信道相干带宽设计发 射机 IFFT变换的大小,可以提升系统的频移鲁棒性;通过引进 CP前缀, 可以使 OFTDM保持系统与 OFDM在定时方面类似的稳健性能。 附图说明 More specifically, compared with the prior art, the present invention has the spectrum adaptability of multi-carrier transmission technology (such as OFDM), the flexibility of single-carrier communication, and the transmission performance is equivalent to that of OFDM technology, and the implementation complexity is achieved. Lower. More importantly, by controlling the number of time domain multiplexing of the transmitter IFFT transform data block, the system can obtain a larger throughput gain and a wider range of mobile speed adaptability; design the transmitter IFFT based on the channel coherence bandwidth The size of the transform can improve the frequency shift robustness of the system; by introducing the CP prefix, the OFTDM can maintain the system and OFDM with similar timing robustness. DRAWINGS
下面参照附图对本发明进行详细描述, 其中相同或相似的附图标 记代表相同的部件。 The invention is described in detail below with reference to the drawings, wherein the same or similar reference numerals represent the same parts.
图 1为现有技术中的 OFDM无线发射机和接收机的框图。 1 is a block diagram of a prior art OFDM radio transmitter and receiver.
图 2为根据本发明一个具体实施方式的在宽带移动通信网絡中用 于经由正交多载波传输信号的无线发射机的框图; 2 is a block diagram of a wireless transmitter for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention;
图 3为根据本发明一个具体实施方式的在宽带移动通信网络中用 于经由正交多载波传输信号的无线发射方法的流程图; 3 is a flow chart of a method for wireless transmission of signals transmitted over orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention;
图 4为添加了循环前缀的 OFTDM符号序列的构造示意图;
图 5为根据本发明一个具体实施方式的在宽带移动通信网络中用 于经由正交多载波传输信号的无线接收机的框图; 4 is a schematic structural diagram of an OFTDM symbol sequence to which a cyclic prefix is added; 5 is a block diagram of a wireless receiver for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention;
图 6为根据本发明一个具体实施方式的在宽带移动通信网络中用 于经由正交多载波传输信号的无线接收方法的流程图; 6 is a flowchart of a wireless receiving method for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network according to an embodiment of the present invention;
图 7示出了基于 MATLAB/SIMULink仿真平台的仿 原理图; 图 8示出在图 6所示仿真平台上对本发明的 OFTDM方案与现有技术 的 OFDM和 SC/FDE方案等三种方案在如下仿真参数条件下进行仿真 运算获得的结果 (误码率) 。 具体实施方式 FIG. 7 shows a simulated schematic diagram based on the MATLAB/SIMULink simulation platform; FIG. 8 shows three schemes of the OFTDM scheme of the present invention and the prior art OFDM and SC/FDE schemes on the simulation platform shown in FIG. The result of the simulation operation under the simulation parameters (bit error rate). detailed description
下面参考附图, 并结合具体实施例对本发明作详细描述。 应当理 解, 本发明并不限于具体实施例。 The present invention will be described in detail below with reference to the accompanying drawings. It should be understood that the invention is not limited to the specific embodiments.
图 2示出根据本发明一个具体实施方式的在无线通信网络, 尤其 是宽带移动通信网络中用于通过多个正交载波发送信号的无线发射 机 1的框图。其中包括一个信道编码装置 1 1、一个数字调制装置 12、 一个串并转换装置 13、 一个逆傅立叶 (IDFT ) 变换装置 14、 一个数 据块复用装置 15、一个保护间隔添加装置 16、一个成形滤波装置 17、 一个 RF变频装置 18和一个发射天线 19。 2 shows a block diagram of a wireless transmitter 1 for transmitting signals over a plurality of orthogonal carriers in a wireless communication network, particularly a broadband mobile communication network, in accordance with an embodiment of the present invention. The method includes a channel coding device 1 1 , a digital modulation device 12 , a serial to parallel conversion device 13 , an inverse Fourier transform (IDFT ) conversion device 14 , a data block multiplexing device 15 , a guard interval adding device 16 , and a shaping filter Apparatus 17, an RF inverter unit 18 and a transmitting antenna 19.
需要说明的是, 图 2中所示出的信道编码装置、 数字调制装置、 成形滤波装置、 RF 变频装置和发射天线与本发明的目的并无直接关 系, 仅作为一个优选实施方式, 在此一并进行描述。 It should be noted that the channel coding apparatus, the digital modulation apparatus, the shaping and filtering apparatus, the RF frequency conversion apparatus, and the transmitting antenna shown in FIG. 2 are not directly related to the object of the present invention, and are only used as a preferred embodiment. And describe it.
假定 ,A = o,i,2....}为输入无线发射机的输出数字序列,下面参照图 2 并结合图 3来对本发明的无线发射机进行详细说明: Assuming that A = o, i, 2....} is the output digital sequence of the input wireless transmitter, the wireless transmitter of the present invention will be described in detail below with reference to FIG. 2 in conjunction with FIG.
信道编码装置 11 用于釆用预定的信道编码规则来对输入数据序列 ,t- 0,l,2....}信道编码,将其变换成输出数据序列 fe ^ = 0,l,2....},其中所述 信道编码规则可以采用例如 RS码和卷积码组成的级联码, Turbo码,或 者 LDPC码, 也可以为多种技术组成的自适应编码方案, 如自适应编码 调制方案 (AMC ); The channel coding apparatus 11 is configured to perform channel coding on the input data sequence, t-0, 1, 2, . . . using a predetermined channel coding rule, and convert it into an output data sequence fe ^ = 0, l, 2. The channel coding rule may employ a concatenated code, such as an RS code and a convolutional code, a Turbo code, or an LDPC code, or an adaptive coding scheme composed of multiple technologies, such as adaptive coding. Modulation scheme (AMC);
数字调制装置 12用于, 例如依据 Gray编码规范, 将经过信道编码
的数据序列映射到调制符号的点阵图上去, 所选择的调制方式由系统设 计决定, 可以确定为 BPSK、 QPSK QAM调制方式中的一种, 也可以 为才艮据误码率和载扰比自适应选择的多种动态调制方式。 经过数字调制 装置 12, 输入数据序列 fe = o,i,2....}变换成输出符号序列 fc , Α = 0,1,2....} ; 串 /并转换装置 13 用于将数字调制映射得到的串行符号序列按照其 后的 IFFT变换矩阵的大小分为多个串行符号数据块, 并对所述多个串 行符号数据块进行串并转换操作, 以形成相应多个并行符号数据块。 经 过串 /并转换装置 13, 输入的串行符号序列 ¾, = 0,1,2....}变换成多个并行 的符号数据块 {et , A = 0,1,2....} , 这里, ^表示一个元素数量和 IFFT变换大 小一样的列向量; The digital modulation device 12 is used, for example, according to the Gray coding specification, to be channel coded The data sequence is mapped to the dot pattern of the modulation symbol. The selected modulation mode is determined by the system design, and can be determined as one of BPSK and QPSK QAM modulation modes, and can also be based on the bit error rate and the carrier-to-interference ratio. Multiple dynamic modulation methods for adaptive selection. After the digital modulation device 12, the input data sequence fe = o, i, 2....} is transformed into an output symbol sequence fc, Α = 0, 1, 2, ....}; the serial/parallel conversion device 13 is used for The serial symbol sequence obtained by the digital modulation mapping is divided into a plurality of serial symbol data blocks according to the size of the subsequent IFFT transformation matrix, and the serial-to-parallel conversion operation is performed on the plurality of serial symbol data blocks to form a corresponding plurality of Parallel symbol data block. After serial/parallel conversion means 13, the input serial symbol sequence 3⁄4, = 0, 1, 2....} is transformed into a plurality of parallel symbol data blocks {e t , A = 0, 1, 2... .} , where ^ denotes a column vector with the same number of elements as the IFFT transform size;
逆傅立叶(IDFT )变换装置 14, 优选地, 可由逆快速傅立叶变换 ( IFFT )模块来实现, 用于对输入的每个并行符号数据块进行 IDFT变 换, 生成相应的多个时域符号数据块, 其中该 IDFT变换等同于对所述 输入的并行数据进行正交多载波调制和合成, 经过 IFFT 变换模块, 输 入并行的数据块序列 = 0, 1, 2,L }变换成相应的时域数据块序列 {/„A: = 0,1,2,L } , 相互之间的关系服从 = JF r(e 这里, Λ也表示一个元 素数量和 IFFT变换大小一样的列向量; An inverse Fourier transform (IDFT) transforming device 14 is preferably implemented by an inverse fast Fourier transform (IFFT) module for performing IDFT transform on each input parallel symbol data block to generate a corresponding plurality of time domain symbol data blocks. Wherein the IDFT transform is equivalent to orthogonal multi-carrier modulation and synthesis of the input parallel data, and the input parallel data block sequence = 0, 1, 2, L } is transformed into a corresponding time domain data block by an IFFT transform module. The sequence {/„A: = 0,1,2,L } , the relationship between them obeys = JF r(e Here, Λ also represents a column vector with the same number of elements and the size of the IFFT transform;
数据块复用装置 15用于将特定数目的经过 IFFT变换后的数据块按 照产生的先后次序复用成长度更长的正交频分时分复用 (OFTDM )符 号的数据部分。 经过数据块复用, 输入的数据块序列 {A = 0,1,2,L }变换 成 OFTDM符号的数据部分的序列 , 0,l,2,L } , 这里, 表示一个元 素数量和 OFTDM符号数据部分大小一样的列向量; The data block multiplexing means 15 is adapted to multiplex a certain number of IFFT-transformed data blocks into a data portion of a longer-length orthogonal frequency division time division multiplexing (OFTDM) symbol in accordance with the generated order. After data block multiplexing, the input data block sequence {A = 0, 1, 2 , L } is transformed into a sequence of data portions of the OFTDM symbol, 0, l, 2, L } , where an element number and OFTDM symbol are represented. a column vector of the same size as the data portion;
保护间隔添加装置 16用于在经过数据块复用后的 OFTDM )符号数 据部分的头或尾部添加一个特定长度的保护间隔, 用于减少信道间干扰 (该保护间隔的长度应大于信道最大时延扩展长度)。 优选地, 保护间 隔添加装置可采用循环前缀( CP )添加装置, 也即将所述 OFTDM符号 数据部分尾部的一部分复制到 OFTDM符号数据部分的前端, 形成最终 的带 CP的 OFTDM符号, CP使所传输的符号具有周期性, 当 CP的长 度比信号在信道中传输的最大延迟时间长, 则码间干扰(ISI )仅仅会影
响 OFTDM符号前端的 CP,从而在接收机端可以简单通过去除 CP就可 消除 ISI。 经过循环前缀添加装置, 输入序列 { ,/t = 0,i,2,L }变换成完整的 0?10]^符号序列{ , = 0,1,2山} , 这里, 表示一个元素数量和 OFTDM 符号大小一样的列向量, 其构造示意图如图 4所示; The guard interval adding means 16 is configured to add a guard interval of a specific length to the head or the tail of the OFITM) symbol data portion after the data block multiplexing, for reducing inter-channel interference (the length of the guard interval should be greater than the channel maximum delay) Extended length). Preferably, the guard interval adding means may employ a cyclic prefix (CP) adding means, that is, copy a part of the tail portion of the OFTDM symbol data portion to the front end of the OFTDM symbol data portion to form a final OFTDM symbol with CP, and the CP transmits the The symbol has periodicity. When the length of the CP is longer than the maximum delay time of the signal transmitted in the channel, inter-symbol interference (ISI) only affects The CP at the front end of the OFTDM symbol is used, so that ISI can be eliminated at the receiver end simply by removing the CP. After the cyclic prefix adding means, the input sequence { , /t = 0, i, 2, L } is transformed into a complete 0? 10] ^ symbol sequence { , = 0, 1, 2 mountain }, where, represents the number of elements and The OFTDM symbol size is the same as the column vector, and its structure is shown in Figure 4.
信道信号成形装置 17用于按照频 i普模板对待发送的 OFTDM信号波 形进行成形滤波。 经过信号成形装置 17, 输入的 OFTDM符号序列 {hk,k = 0, 1, 2,L }变换成输出波形序列 {ik,k = 0, 1, 2,L }; The channel signal shaping means 17 is configured to perform shaping filtering on the OFTDM signal waveform to be transmitted in accordance with the frequency template. Through the signal shaping device 17, the input OFTDM symbol sequence {h k , k = 0, 1, 2, L } is transformed into an output waveform sequence {i k , k = 0, 1, 2, L };
RF变换装置 18用于将基带的 OFTDM符号序列变换成射频信号, 并经由发射天线发射到无线信道中去。 The RF transform means 18 is operative to transform the baseband OFTDM symbol sequence into a radio frequency signal and transmit it to the radio channel via the transmit antenna.
优选地, 无线发射机 1还包括一个控制装置 19 (图中未示出) , 用 于执行以下功能: Preferably, the wireless transmitter 1 further includes a control device 19 (not shown) for performing the following functions:
1 )根据信道带宽和信道时延长度来调整所述 IFFT变换装置的变换 矩阵的大小; 1) adjusting the size of the transform matrix of the IFFT transform device according to the channel bandwidth and the channel time extension;
2 )根据信道时延扩展的长度和 IFFT 变换矩阵的大小来调整所述循 环前缀的长度, 使其大于等于信道时延扩展的长度, 和小于等于所述 IFFT变换矩阵的大小; 也即, 循环前缀(CP ) 必须大于信道扩展长度; 发射机 IFFT变换长度至少大于 CP长度(在通信过程中保持不变); 2) adjusting the length of the cyclic prefix according to the length of the channel delay spread and the size of the IFFT transform matrix to be greater than or equal to the length of the channel delay spread, and less than or equal to the size of the IFFT transform matrix; that is, the loop The prefix (CP) must be greater than the channel extension length; the transmitter IFFT transform length is at least greater than the CP length (which remains unchanged during communication);
3 ) 与多普勒 (Doppler )频移 (或者信道相干时间) 的大小变化成 反向地扩大或者缩小发射机 IFFT时域复用的数量; 并根据信道相干时 间长度来调整所述数据块复用的数量, 以使其 OFTDM符号的等效时间 长度小于所述信道相干时间长度。 3) expanding or reducing the number of transmitter IFFT time domain multiplexing in reverse with the Doppler frequency shift (or channel coherence time); and adjusting the data block according to the channel coherence time length The number is used such that the equivalent time length of its OFTDM symbol is less than the channel coherence time length.
图 3为根据本发明一个具体实施方式的在宽带移动通信网络中用 于经由正交多载波传输信号的无线发射方法的流程图。 3 is a flow diagram of a method of wireless transmission for transmitting signals over orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention.
需要说明的是, 图 2中所示出的信道编码步骤、 数字调制步骤、 成形滤波步骤、 RF 变频步骤和发射无线信号的步骤与本发明的目的 本无直接关系, 仅作为一个优选实施方式, 在此一并进行描述。 It should be noted that the channel coding step, the digital modulation step, the shaping filtering step, the RF frequency conversion step, and the step of transmitting the wireless signal shown in FIG. 2 are not directly related to the purpose of the present invention, and are only a preferred embodiment. This is described together.
同样, 假定 k,A = o,i,2....}为输入无线发射机的输出数字序列; 在步骤 S101 中, 采用预定信道编码规则来对输入数据序列 fe, = o,i,2....}信道编码,将其变换成输出数据序列 fc, 0,1,2....} ,其中所述
信道编码规则可以采用例如 RS码和卷积码组成的级联码, Turbo码, 或 者 LDPC码, 也可以为多种技术组成的自适应编码方案, 如自适应编码 调制方案(AMC ); , Similarly, assume that k, A = o, i, 2..} are the output digital sequences of the input wireless transmitter; in step S101, the input data sequence fe, = o, i, 2 is applied using predetermined channel coding rules. ....} channel coding, which is transformed into an output data sequence fc, 0, 1, 2, ..., where The channel coding rule may use a concatenated code, a turbo code, or an LDPC code, for example, an RS code and a convolutional code, or an adaptive coding scheme composed of multiple technologies, such as an adaptive coding modulation scheme (AMC);
在步骤 S102中, 例如依据 Gray编码规范, 将经过信道编码的数据 序列映射到调制符号的点阵图上去, 所选择的调制方式由系统设计决 定, 可以确定为 BPSK、 QPSK、 QAM调制方式中的一种, 也可以为才艮 据误码率和载扰比自适应选择的多种动态调制方式。 经过调制操作, 输 入数据序列 ¾, = 0,1,2....}变换成输出符号序列 ¾^ = 0,1,2....}; In step S102, the channel-coded data sequence is mapped to the bitmap of the modulation symbol according to the Gray coding specification, for example, and the selected modulation mode is determined by the system design, and can be determined as BPSK, QPSK, QAM modulation mode. One type can also be a plurality of dynamic modulation modes that are adaptively selected according to the bit error rate and the carrier frequency ratio. After the modulation operation, the input data sequence 3⁄4, = 0, 1, 2....} is transformed into the output symbol sequence 3⁄4^ = 0,1,2....};
在步骤 S103 中, 将符号调制之后的串行符号序列按照其后的 IFFT 变换矩阵的大小分为多个串行符号数据块, 并对所述多个串行符号数据 块进行串并转换操作, 以形成相应多个并行符号数据块。 经过串 /并转换 操作, 输入的串行符号序列 fc , ^ 0,i,2....}变换成多个并行的符号数据块 {e, , l = 0,1,2....} , 这里, 表示一个元素数量和 IFFT变换大小一样的列向 量; In step S103, the serial symbol sequence after symbol modulation is divided into a plurality of serial symbol data blocks according to the size of the subsequent IFFT transformation matrix, and the serial-to-parallel conversion operation is performed on the plurality of serial symbol data blocks. To form a corresponding plurality of parallel symbol data blocks. After the serial/parallel conversion operation, the input serial symbol sequence fc, ^ 0, i, 2....} is transformed into a plurality of parallel symbol data blocks {e, , l = 0, 1, 2, .... } , here, represents a column vector with the same number of elements and the size of the IFFT transform;
在步骤 S104中,对输入的每个并行符号数据块进行 IDFT变换,生 成相应的多个时域符号数据块(其中该 IDFT变换等同于对所述输入的 并行数据进行正交多载波调制和合成), 优选地, IDFT变换可由逆快速 傅立叶变换(IFFT )算法来实现。 经过 IFFT变换操作, 输入并行的数 据块序列 ¾, fc = 0,l,2,L }变换成相应的时域数据块序列 {/¾,& = 0,1,2 } ,相互 之间的关系服从 Λ = IFFT(ek) , 这里, Λ也表示一个元素数量和 IFFT变换 大小一样的列向量; In step S104, IDFT transform is performed on each input parallel symbol data block to generate a corresponding plurality of time domain symbol data blocks (where the IDFT transform is equivalent to performing orthogonal multi-carrier modulation and synthesis on the input parallel data). Preferably, the IDFT transform can be implemented by an inverse fast Fourier transform (IFFT) algorithm. After the IFFT transform operation, input parallel data block sequence 3⁄4, fc = 0, l, 2 , L } is transformed into the corresponding time domain data block sequence {/ 3⁄4 , & = 0,1, 2 }, the relationship between each other Obey Λ = IFFT(e k ), where Λ also denotes a column vector with the same number of elements as the IFFT transform;
在步骤 S105中, 将特定数目的经过 IFFT变换后的数据块按照产生 的先后次序复用成长度更长的正交频分时分复用 (OFTDM )符号的数 据部分。 经过数据块复用操作, 输入的数据块序列 {/ = 0,1,2 }变换成 OFTDM符号的数据部分的序列 { ,^: = 0,1,2山} ,这里, ^表示一个元素数 量和 OFTDM符号数据部分大小一样的列向量; In step S105, a specific number of IFFT-transformed data blocks are multiplexed into the data portion of the longer orthogonal frequency division time division multiplexing (OFTDM) symbol in the order of generation. After the data block multiplexing operation, the input data block sequence {/ = 0, 1, 2 } is transformed into the sequence of the data portion of the OFTDM symbol { , ^: = 0, 1, 2 mountain }, where ^ represents the number of elements a column vector of the same size as the OFTDM symbol data portion;
在步驟 S106中, 在经过数据块复用后的 OFTDM )符号数据部分的 头或尾部添加一个特定长度的保护间隔, 用于减少信道间干扰(该保护 间隔的长度应大于信道最大时延扩展长度)。 优选地, 保护间隔为循环
前缀(CP), 也即, 将所述 OFTDM符号数据部分尾部的一部分复制到 OFTDM符号数据部分的前端, 形成最终的带 CP的 OFTDM.舞号, CP 使所传输的符号具有周期性, 当 CP的长度比信号在信道中传输的最大 延迟时间长, 则码间干扰 (ISI)仅仅会影响 OFTDM符号前端的 CP, 从而在接收机端可以简单通过去除 CP就可消除 ISI。 经过循环前缀添加 步骤, 输入序列 { , ;==0,1,2,L}变换成完整的 OFTDM 符号序列 {¾,l = 0,l,2,L},这里, 表示一个元素数量和 OFTDM符号大小一样的列 向量, 其构造示意图如图 4所示; In step S106, a guard interval of a specific length is added to the header or the tail of the OFITM) symbol data portion after the data block multiplexing, for reducing inter-channel interference (the length of the guard interval should be greater than the maximum delay spread length of the channel) ). Preferably, the guard interval is a loop a prefix (CP), that is, a portion of the tail portion of the OFTDM symbol data portion is copied to the front end of the OFTDM symbol data portion to form a final OFTDM. dance number with the CP, and the CP causes the transmitted symbol to have periodicity, when the CP The length of the signal is longer than the maximum delay of the signal transmitted in the channel. Inter-symbol interference (ISI) only affects the CP of the OFTDM symbol front end, so that the ISI can be eliminated at the receiver end simply by removing the CP. After the cyclic prefix addition step, the input sequence { , ;==0,1,2,L} is transformed into a complete OFTDM symbol sequence {3⁄4,l = 0,l,2,L}, where an element number and OFTDM are represented. A column vector of the same size as the symbol, and its structure is shown in Figure 4;
在步驟 S107中,按照频 i普模板对待发送的 OFTDM信号波形进行成 形滤波。 经过信号成形操作, 输入的 OFTDM符号序列 { ,/ = 0,l,2,L}变 换成输出波形序列 , = 0,1,2山 }; In step S107, the OFTDM signal waveform to be transmitted is shaped and filtered according to the frequency template. After the signal shaping operation, the input OFTDM symbol sequence { , / = 0, l, 2, L} is converted into an output waveform sequence, = 0, 1, 2 mountain };
在步骤 S108中, 将基带的 OFTDM符号序列变换成射频信号; 在步骤 S109中, 经由发射天线发射到无线信道中去。 In step S108, the OFTDM symbol sequence of the baseband is converted into a radio frequency signal; in step S109, it is transmitted to the radio channel via the transmitting antenna.
优选地, 本发明的无线发射方法还包括如下控制步骤: Preferably, the wireless transmitting method of the present invention further comprises the following control steps:
1 )根据信道带宽和信道时延长度来调整所述 IFFT变换装置的变换 矩阵的大小; 1) adjusting the size of the transform matrix of the IFFT transform device according to the channel bandwidth and the channel time extension;
2)根据信道时延扩展的长度和 IFFT 变换矩阵的大小来调整所述循 环前缀的长度, 使其大于等于信道时延扩展的长度, 和小于等于所述 IFFT变换矩阵的大小; 也即, 循环前缀(CP)必须大于信道扩展长度; 发射机 IFFT变换长度至少大于 CP长度(在通信过程中保持不变); 2) adjusting the length of the cyclic prefix according to the length of the channel delay spread and the size of the IFFT transform matrix to be greater than or equal to the length of the channel delay spread, and less than or equal to the size of the IFFT transform matrix; that is, the loop The prefix (CP) must be greater than the channel extension length; the transmitter IFFT transform length is at least greater than the CP length (which remains unchanged during communication);
3) 与多普勒 (Doppler)频移 (或者信道相干时间) 的大小变化相 应地扩大或者缩小发射机 IFFT时域复用的数量; 并才艮据信道相干时间 长度来调整所述数据块复用的数量, 以使其 OFTDM符号的等效时间长 度小于所述信道相干时间长度。 3) corresponding to the Doppler frequency shift (or channel coherence time) size change to expand or reduce the number of transmitter IFFT time domain multiplexing; and adjust the data block complex according to the channel coherence time length The number is used such that the equivalent time length of its OFTDM symbol is less than the channel coherence time length.
图 5为根据本发明一个具体实施方式的在无线通信网络, 尤其是 宽带移动通信网络中用于接收经由多个正交载波传输的信号的无线 接收机 2的框图。 其中, 无线接收机包括匹配滤波 /同步装置 21、 保
护间隔去除装置 22、 信道估计装置 23、 频 /时变换装置 24、 单点频域 均衡装置 25、 时 /频变换装置 26、 数据块解复用装置 27、 FFT变换装 置 28、 并 /串变换装置 29、 解码装置 30、 信道译码装置 31。 5 is a block diagram of a wireless receiver 2 for receiving signals transmitted via a plurality of orthogonal carriers in a wireless communication network, particularly a broadband mobile communication network, in accordance with an embodiment of the present invention. Wherein, the wireless receiver includes a matched filtering/synchronizing device 21, and Guard interval removing means 22, channel estimating means 23, frequency/time converting means 24, single-point frequency domain equalizing means 25, time/frequency converting means 26, block demultiplexing means 27, FFT converting means 28, parallel/serial conversion The device 29, the decoding device 30, and the channel decoding device 31.
其中, 需要说明的是, 用于基带处理的匹配滤波装置、 解码装置、 信道译码装置与本发明的目的并无直接关系, 仅作为一个优选实施方 式, 在此一并进行描述。 另外, 无线接收机还应包括用于接收无线信 号的接收天线和用于将无线信号下变频到基带的射频变频装置, 它们 与本发明的目的也无直接关系, 由于为简明起见, 在图中未示出。 It should be noted that the matched filter device, the decoding device, and the channel decoding device for baseband processing are not directly related to the object of the present invention, and are merely described as a preferred embodiment. In addition, the wireless receiver should also include a receiving antenna for receiving wireless signals and a radio frequency converting device for downconverting the wireless signals to the baseband, which are not directly related to the object of the present invention, for the sake of simplicity, in the figure Not shown.
假定经过接收天线和 R 射频转换模块, 无线接收机 2可以获得一 个基带信号 ¾, O,l,2,L }。下面,参照图 5并结合图 6来对本发明的无线 接收机进行详细说明: It is assumed that the radio receiver 2 can obtain a baseband signal 3⁄4, O, l, 2, L } through the receiving antenna and the R radio frequency conversion module. Hereinafter, the wireless receiver of the present invention will be described in detail with reference to FIG. 5 in conjunction with FIG. 6:
匹配滤波与同步装置 21用于对接收到的基带信号进行匹配滤波,同 时, 完成接收信号的时频同步功能。 经过匹配滤波与同步装置 21, 输入 数据序列、lk , k = 0,1,2,L }变换成输出数据序列 = 0,1, 2,L }; The matched filtering and synchronizing device 21 is configured to perform matched filtering on the received baseband signal, and at the same time, complete the time-frequency synchronization function of the received signal. After the matched filtering and synchronizing device 21, the input data sequence, l k , k = 0, 1, 2, L } is transformed into an output data sequence = 0, 1, 2, L };
保护间隔去除装置 22用于去除添加在 OFTDM符号序列上的保护间 隔。 当保护间隔为循环前缀时, 其用于去除 OFTDM符号前端的循环前 缀(CP ), 从而可以消除 OFTDM符号间的干扰。 经过去除循环前缀, 输入数据序歹 {m : = 0,l,2,L }变换成输出数据块序歹 { ^ = 0,1,2,L }, 这里, 表示一个元素数量和 3-5中的 FFT变换大小一样的列向量; The guard interval removal means 22 is used to remove the guard interval added to the OFTDM symbol sequence. When the guard interval is a cyclic prefix, it is used to remove the cyclic prefix (CP) of the OFTDM symbol front end, thereby eliminating interference between OFTDM symbols. After removing the cyclic prefix, the input data sequence 歹{m : = 0,l,2,L } is transformed into the output data block sequence 歹 { ^ = 0,1,2,L }, where, represents the number of elements and 3-5 The FFT transforms the same column vector size;
信道估计装置 23用于基于所述 OFTDM符号序列或导频训练序列来 在时域对信道响应进行估计。 经过信道估计装置 23, 可以获得信道响应 的估计值 {Wi = o,l,2,L 1}, 这里, L为时域响应的最大时延; Channel estimation means 23 is operative to estimate the channel response in the time domain based on the OFTDM symbol sequence or the pilot training sequence. Through the channel estimation means 23, an estimated value of the channel response { Wi = o, l, 2, L 1} can be obtained, where L is the maximum delay of the time domain response;
时 /频变换装置 24用于将所接收的一定长度的时域数据块变换到频 域中去, 以便频域均衡器能够消除信道对该数据块的影响, 具体地, 时 /频变换装置可通过 DFT、 FFT变换等算法来实现。 经过时 /频变换装置, 输入数据块序列、nk , k = 0,1, 2,L }变换成输出数据块序列、ok, k = 0,1,2,L } ,相互 之间的关系服从 = FFT(nk) , 这里 , 表示一个元素数量和 FFT变换大 小一样的列向量; The time/frequency conversion device 24 is configured to transform the received time-domain data block of a certain length into the frequency domain, so that the frequency domain equalizer can eliminate the influence of the channel on the data block. Specifically, the time/frequency conversion device can It is implemented by algorithms such as DFT and FFT transform. After the time/frequency conversion device, the input data block sequence, n k , k = 0, 1, 2, L } is transformed into an output data block sequence, o k , k = 0, 1, 2 , L } The relationship obeys = FFT(n k ), where a column vector representing the same number of elements as the FFT transform size;
频域均衡装置 25用于基于信道估计装置 23所提供的信道估计值来
在频域对所述去除循环前缀的 OFTDM符号数据进行信道损伤的相位和 幅度补偿。 其中, 频域均衡装置可以采用单点频域最小均方误差 MMSE 均衡器或者单点频域迫零均衡器。 具体地, 如果通迚单点迫零(ZF)方 法来完成频域均衡, 则经过频域均衡装置 25, 输出数据块序列 {pk,k = 0,l,2,L }和输入数据块序歹l {ok,k = 0,l,2,L }之间的关系为:The frequency domain equalization means 25 is operative based on the channel estimation value provided by the channel estimation means 23. The phase and amplitude compensation of the channel impairment is performed on the OFTDM symbol data of the removed cyclic prefix in the frequency domain. The frequency domain equalization device may adopt a single-point frequency domain minimum mean square error MMSE equalizer or a single-point frequency domain zero-forcing equalizer. Specifically, if the frequency domain equalization is completed by the single-point zero-forcing (ZF) method, the frequency domain equalization device 25 outputs the data block sequence {p k , k = 0, l, 2, L } and the input data block. The relationship between the order 歹l {o k , k = 0,l,2,L } is:
Pk=
,ilwx,L ,i/wL_{]}ok ,这里, diagO表示对某个矢量的对角化操作, Pk = , ilw x , L , i / w L _ { ]} o k , where diagO represents the diagonalization operation of a vector,
[W0 Wx L WL_xf =FFT(w) , 而后者 w = [w。 w, L
, 即信道响应列向 量。 [W 0 W x LW L _ x f = FFT(w) , and the latter w = [w. w, L , that is, the channel response column vector.
频 /时变换装置 26用于将将已经经过频域均衡的频域子带信号合成 恢复到时域中去, 以便进一步处理, 具体地, 频 /时变换装置可以通过 IDFT, IFFT变换等算法来实现。 经过频 /时变换装置 26, 输入数据块序 列 {;¾ = 0,1,2,L }变换成输出数据块序列 ,A: = 0,1,2,L } ,这里, qk=IFF Pk、, 而且, A和 表示元素数量和 IFFT变换大小一样的列向量; The frequency/time transforming means 26 is configured to recover the frequency domain subband signal synthesis that has undergone frequency domain equalization into the time domain for further processing. Specifically, the frequency/time transforming apparatus may use an algorithm such as IDFT, IFFT transform or the like. achieve. After the frequency/time conversion means 26, the input data block sequence {;3⁄4 = 0,1,2,L } is transformed into an output data block sequence, A: = 0,1,2,L } , where q k =IFF Pk And, and, A and a column vector indicating the same number of elements and the size of the IFFT transform;
数据块解复用装置 27用于将与无线发射机端的 OFTDM符号的数据 部分大小相同的数据块解复用成与无线发射机端 IFFT 变换矩阵大小相 同的数据块序列。 经过数据块解复用装置 27, 输入的 OFTDM符号数据 ^ = 0,1,2山}被变换成多个数据块序列 ,^; = 0,1,2山}, 这里, ^表示一个 元素数量和发射机端 IFFT变换大小一样的列向量; The data block demultiplexing means 27 is for demultiplexing the data block of the same size as the data portion of the OFTDM symbol of the radio transmitter side into a data block sequence of the same size as the radio transmitter side IFFT transform matrix. After the data block demultiplexing means 27, the input OFTDM symbol data ^ = 0, 1, 2 mountain} is transformed into a plurality of data block sequences, ^; = 0, 1, 2 mountain}, where ^ represents an element number a column vector of the same size as the transmitter-side IFFT transform;
与上述 OFTDM发射机端 IFFT变换装置的变换矩阵大小一样的 FFT 变换装置 28用于对所述多个符号数据块执行与发射机端 IFFT变换对应 的逆操作, 用于将输入的时域数据块重新映射到频域中去。 经过 FFT变 换装置 28, 输入 OFTDM数据块序列 {^-0,l,2,L }变换成并行的符号数 据块块序列 { = (U2,L} , 表示一个元素数量和 FFT变换大小一样的 列向量; The FFT transforming means 28 of the same size as the transform matrix of the OFTDM transmitter-side IFFT transforming apparatus is configured to perform an inverse operation corresponding to the transmitter-side IFFT transform on the plurality of symbol data blocks for inputting the time-domain data block. Remap to the frequency domain. After the FFT transform means 28, the input OFTDM data block sequence {^-0, l, 2, L} is transformed into a parallel symbol data block block sequence { = (U2, L}, indicating that the number of elements is the same as the FFT transform size) Vector
并 /串变换装置 29用于将输入的并行符号数据块序列变换成串行的 符号数据序列。 经过并 /串变换装置 29, 输入的符号数据块序列 {¾^ = 0,1,2,L }变换成串行数据序列 , 0,1,2,L }; The parallel/serial conversion means 29 is for converting the input parallel symbol data block sequence into a serial symbol data sequence. After the parallel/serial conversion means 29, the input symbol data block sequence { 3⁄4 ^ = 0, 1, 2, L } is transformed into a serial data sequence, 0, 1, 2, L };
数字解调装置 30用于依据发射机端的 Gray编码规则将输入的数据 序列解调成相应的数字序列。 如果即将执行的信道译码算法基于硬判决
输入信息, 则输出的硬信息数字序列是 {0}和 {1}的随机排列, 否则, 符 号解调装置 30将提供相应的基于数比特量化的软信息数字序列。 经过 数字解调装置 30, 输入的数据序列 , = 0,1,2,1^变换成输 的数字信息The digital demodulating device 30 is configured to demodulate the input data sequence into a corresponding digital sequence according to the Gray encoding rule of the transmitter. If the channel decoding algorithm to be executed is based on hard decision The input information, then the sequence of hard information digital sequences is a random arrangement of {0} and {1}, otherwise the symbol demodulating means 30 will provide a corresponding sequence of soft information digits based on the quantization of the bits. After the digital demodulation device 30, the input data sequence, = 0, 1, 2, 1^ is transformed into the input digital information.
{uk,k = 0,l,2,L } ; {u k ,k = 0,l,2,L } ;
信道译码装置 31 用于基于发射机端的信道编码规则来执行信道译 码算法。 经过信道译码装置 31 , 输入数字序列 = 0,1, 2,L }变换成输出 数字序列 , = 0,1,2山}。 The channel decoding means 31 is operative to perform a channel decoding algorithm based on channel coding rules at the transmitter side. After channel decoding means 31, the input digital sequence = 0, 1, 2, L } is transformed into an output digital sequence, = 0, 1, 2 mountains}.
图 6为根据本发明一个具体实施方式的在宽带移动通信网络中用 于经由正交多载波传输信号的无线接收方法的流程图。 6 is a flow chart of a wireless receiving method for transmitting signals via orthogonal multi-carriers in a broadband mobile communication network, in accordance with an embodiment of the present invention.
需要说明的是, 图中所示出的接收无线信号的步骤、 将无线信号 下变频到基带的步驟、 匹配滤波步骤、 数字解调步驟、 信道译码步骤 与本发明的目的本无直接关系, 仅作为一个优选实施方式, 在此一并 进行描述。 It should be noted that the steps of receiving a wireless signal, down-converting a wireless signal to a baseband, matching filtering step, digital demodulating step, and channel decoding step are not directly related to the purpose of the present invention. Only as a preferred embodiment, the description will be made here.
其中, 在步骤 S201中, 通过接收天线接收无线信号; In step S201, receiving a wireless signal through the receiving antenna;
在步骤 S202中, 将无线信号下变频为基带 OFTDM信号, 假定经 过接收步骤和下变频步骤, 获得基带 OFTDM信号 = 0,1,2,L }; In step S202, the wireless signal is down-converted to a baseband OFTDM signal, and it is assumed that the baseband OFTDM signal = 0, 1, 2 , L } is obtained after the receiving step and the down-conversion step;
在步骤 S203中,对接收到的基带 OFTDM信号进行匹配滤波,同时, 完成接收信号的时频同步功能。 经过匹配滤波与同步步骤, 输入数据序 列 {lk,k = 0,1,2,L }变换成 OFTDT符号数据序列 mk,k = 0,1, 2,L }; In step S203, the received baseband OFTDM signal is matched and filtered, and at the same time, the time-frequency synchronization function of the received signal is completed. After the matched filtering and synchronization steps, the input data sequence {l k , k = 0, 1, 2, L } is transformed into the OFTDT symbol data sequence m k , k = 0, 1, 2, L };
在步骤 S204中,去除添加在 OFTDM符号序列上的保护间隔。 当保 护间隔为循环前缀时, 其用于去除 OFTDM符号前端的循环前缀(CP ), 从而可以消除 OFTDM符号间的干扰。 经过所述去除循环前缀步骤, 输 入数据序列 { , = 0,1,2,]:}变换成输出数据块序列 { = 0,1,2,L } , 这里, nk 表示一个元素数量和 3-5中的 FFT变换大小一样的列向量; In step S204, the guard interval added to the OFTDM symbol sequence is removed. When the guard interval is a cyclic prefix, it is used to remove the cyclic prefix (CP) of the OFTDM symbol front end, thereby eliminating interference between OFTDM symbols. After the step of removing the cyclic prefix, the input data sequence { , = 0, 1, 2, ]:} is transformed into an output data block sequence { = 0, 1, 2, L } , where n k represents the number of elements and 3 FFT transforms the same size column vector in -5;
在步骤 S205中,基于所述 OFTDM符号序列或导频训练序列来在时 域对信道响应进行估计, 以获得信道估计值 {^^ = 0,1,2山 - 1} , 这里, L 为时域响应的最大时延; In step S205, the channel response is estimated in the time domain based on the OFTDM symbol sequence or the pilot training sequence to obtain a channel estimation value {^^ = 0, 1, 2, mountain - 1}, where L is The maximum delay of the domain response;
在步骤 S206中,将一定长度的接收数据块变换到频域中去, 以便能 够通过频域均衡来消除信道对该数据块的影响, 具体地, 该步骤可通过
DFT、 FFT 变换等算法来实现。 经过时 /频转换步骤, 输入数据块序列 {"^ = 0,1,2山 }变换成输出数据块序列 { = o,i,2,L } ,相互之间的关系服从 ok = FFT{nk) , 这里, 表示一个元素数量和 FFT变换大 d、一样的列向量; 在步骤 S207中, 用于基于上述信道估计值, 通过单点频域均衡来在 频域对所述去除循环前缀的 OFTDM符号数据进行信道损伤的相位和幅 度补偿。 其中, 频域均衡装置可以采用单点频域最小均方误差 MMSE 均衡器或者单点频域迫零均衡器。 具体地, 如果通过单点迫零(ZF )方 法来完成频域均衡,则经过频域均衡操作,输出数据块序列 ^ = 0,1,2山} 和 输 入 数 据 块 序 列 {Ot = 0,l,2,L } 之 间 的 关 系 为 :In step S206, a certain length of the received data block is transformed into the frequency domain, so that the influence of the channel on the data block can be eliminated by frequency domain equalization. Specifically, the step can be adopted. DFT, FFT transform and other algorithms to achieve. After the time/frequency conversion step, the input data block sequence {"^ = 0, 1, 2 mountain} is transformed into an output data block sequence { = o, i, 2, L }, and the relationship between them obeys o k = FFT { n k ) , here, represents a column vector having the same number of elements as the FFT transform large d; in step S207, for removing the cyclic prefix in the frequency domain by single-point frequency domain equalization based on the above channel estimation value The OFTDM symbol data is used for phase and amplitude compensation of channel impairments. The frequency domain equalization device may use a single-point frequency-domain minimum mean square error MMSE equalizer or a single-point frequency-domain zero-forcing equalizer. Zero (ZF) method to complete the frequency domain equalization, after the frequency domain equalization operation, the output data block sequence ^ = 0,1,2 mountain} and the input data block sequence { Ot = 0,l,2,L } The relationship is:
Λ
,这里, diag()表示对某个矢量的对角化操作, [W0 W L WL_}]T = FFT(w) , 而后者 1T , 即信道响应列向 量。 Λ Here, diag() represents the diagonalization operation on a vector, [W 0 WLW L _ } ] T = FFT(w) , and the latter 1 T , the channel response column vector.
在步骤 S208中,将已经经过频域均衡的频域子带信号合成恢复到时 域中去, 以便进一步处理, 具体地, 其可以通过 IDFT, IFFT变换等算 法来实现。 经过频 /时变换装置 26, 输入数据块序列 {A = 0,U,L }变换成 输出数据块序歹 ^^^。,^^!^ , 这里, qk = IFFnPk) , 而且, A和 表示 元素数量和 IFFT变换大小一样的列向量; In step S208, the frequency domain subband signal synthesis that has undergone frequency domain equalization is restored to the time domain for further processing. Specifically, it can be implemented by an algorithm such as IDFT, IFFT transform or the like. After the frequency/time conversion means 26, the input data block sequence { A = 0, U, L} is transformed into an output data block sequence ^^^^. , ^^!^ , where q k = IFFn Pk ) , and, A and the column vector indicating the number of elements and the size of the IFFT transform;
在步骤 S209中, 将与无线发射机端的 OFTDM符号数据部分大小 相同的数据块解复用成与无线发射机端 IFFT 变换矩阵大小相同的数据 块序列。 经过所述数据块解复用步驟, 输入 OFTDM 符号数据序列 { , t = 0,l,2,L }变换成多个符号数据块序列 {r^ = 0,l,2,L }, 这里, rA表示一 个元素数量和发射机端 IFFT变换大小一样的列向量; In step S209, the data block of the same size as the OFTDM symbol data portion of the radio transmitter side is demultiplexed into a data block sequence of the same size as the radio transmitter side IFFT transform matrix. After the data block demultiplexing step, the input OFTDM symbol data sequence { , t = 0, l, 2, L } is transformed into a plurality of symbol data block sequences {r^ = 0, l, 2, L }, where r A denotes a column vector having the same number of elements as the transmitter-side IFFT transform;
在步骤 S210中, 通过与上述 OFTDM发射机端 IFFT变换矩阵大小 一样的 FFT变换矩阵来对所述多个符号数据块执行与发射机端 IFFT变 换对应的逆操作, 用于将输入的时域数据块重新映射到频域中去。 经过 所述 FFT变换步驟,输入的多个 OFTDM符号数据块序列 \xk,k- o,i,2,L }变 换成多个并行的符号数据块块序列 = 0,1,2,L } , 表示一个元素数量和 FFT变换大小一样的列向量; In step S210, performing an inverse operation corresponding to the transmitter-side IFFT transformation on the plurality of symbol data blocks by using an FFT transformation matrix of the same size as the OFTDM transmitter-side IFFT transformation matrix, for inputting the time domain data. The block is remapped into the frequency domain. After the FFT transform step, the input OFTDM symbol data block sequence \x k , k- o, i, 2, L } is transformed into a plurality of parallel symbol data block block sequences = 0, 1, 2, L } , representing a column vector with the same number of elements as the FFT transform size;
在步骤 S211 中, 将输入的并行符号数据块序列并 /串变换成串行的
符号数据序列。 经过并 /串变换操作, 输入的多个符号数据块序列 {sk , k = 0, l, 2,L }变换成串行数据序列 {tA = 0,l,2,L }; In step S211, the input parallel symbol data block sequence is parallel/serial converted into serial Symbolic data sequence. After the parallel/serial conversion operation, the input sequence of multiple symbol data blocks {s k , k = 0, l, 2, L } is transformed into a serial data sequence {t A = 0, l, 2, L };
在步驟 S212中, 依据发射机端的 Gray编码规则将输入的数据序列 解调成相应的数字序列。 如果即将执行的信道译码算法基于硬判决输入 信息, 则输出的硬信息数字序列是 {0}和 {1 }的随机排列, 否则, 将输出 相应的基于数比特量化的软信息数字序列。 经过符号解调步骤, 输入的 数据序列 , = 0,1,2,L }变换成输出的数字信息 {"A.,it = 0,l,2,L } ; In step S212, the input data sequence is demodulated into a corresponding digital sequence according to the Gray coding rule of the transmitter. If the channel decoding algorithm to be executed is based on hard decision input information, the output hard information digital sequence is a random arrangement of {0} and {1 }, otherwise, a corresponding soft information digital sequence based on digital quantization is output. After the symbol demodulation step, the input data sequence, = 0, 1, 2, L } is transformed into the output digital information {" A ., it = 0, l, 2, L };
在步驟 S213 中, 基于发射机端的信道编码规则来执行信道译码算 法。 经过信道译码步骤, 输入数字序列 {^ = o,i,2,L }变换成输出数字序 歹' j {v„/c = 0,l,2,L }。 In step S213, the channel decoding algorithm is performed based on the channel coding rules of the transmitter. After the channel decoding step, the input digital sequence {^ = o, i, 2, L } is transformed into an output digital sequence 歹 ' j {v„/c = 0, l, 2, L }.
图 7示出了基于 MATLAB/SIMULink仿真平台的仿真原理图; Figure 7 shows the simulation schematic based on the MATLAB/SIMULink simulation platform;
图 8示出在图 6所示仿真平台上对本发明的 OFTDM方案与现有技术 的 OFDM和 SC/FDE方案等三种方案在如下仿真参数条件下进行仿真 运算获得的结果(误码率) , 由图 7可以看出, 本发明的 OFTDM的 误码率明显优于 SC/FDE方案的误码率, 与 OFDM的误码率相当,但 由于本发明的实现复杂性 (256 个子载波)由于 OFDM ( 2048 个子载 波) , 因此本发明在性能和实现复杂度之间获得了一个良好的折中。 8 shows the result (bit error rate) obtained by performing simulation operations on the simulation scheme of the present invention on the simulation platform shown in FIG. 6 and the prior art OFDM and SC/FDE schemes under the following simulation parameters. It can be seen from FIG. 7 that the error rate of the OFTDM of the present invention is significantly better than the error rate of the SC/FDE scheme, which is comparable to the error rate of OFDM, but due to the implementation complexity of the present invention (256 subcarriers) due to OFDM (2048 subcarriers), so the present invention achieves a good compromise between performance and implementation complexity.
设定仿真环境参数如下: Set the simulation environment parameters as follows:
信道带宽: 10M, 信道模型: SUI-4, 信道编码: 卷积码(编码: 码率 1/2, 约束长度 7, 生成多项式 [171, 133], 译码: 8级 3bit量化, Viterbi软 译码, 译码深度 34 ) Channel bandwidth: 10M, channel model: SUI-4, channel coding: convolutional code (coding: code rate 1/2, constraint length 7, generator polynomial [171, 133], decoding: 8 levels of 3 bit quantization, Viterbi soft translation Code, decoding depth 34)
设定系统仿真参数: Set system simulation parameters:
OFTDM子载波个数: 256,数据块复用个数: 8, 频域均衡点数: 2048, 频域均衡方法: 单点迫零 ( ZF )均衡器 Number of OFTDM subcarriers: 256, number of data block multiplexing: 8, frequency domain equalization points: 2048, frequency domain equalization method: single point zero forcing (ZF) equalizer
设定参与比较的系统参数: Set the system parameters to participate in the comparison:
OFDM: OFDM:
子载波个数: 2048,频域均衡点数: 2048,频域均衡方法:单点迫零(ZF ) 均衡器; Number of subcarriers: 2048, frequency domain equalization points: 2048, frequency domain equalization method: single point zero forcing (ZF) equalizer;
SC-FDE/LE: SC-FDE/LE:
频域均衡点数: 2048, 频域均衡方法: 单点迫零 ( ZF )均衡器;
基于 MATLAB/SIMULink仿真平台的仿真原理图: Frequency domain equalization points: 2048, frequency domain equalization method: single point zero forcing (ZF) equalizer; Simulation schematic based on MATLAB/SIMULink simulation platform:
以上对本发明的具体实施例进行了描述。 需要理解对是, 本发明 并不局限于上述特定对实施方式, 本领域技术人员可以在所附权利要 求的范围内做出各种变形或修改。
The specific embodiments of the present invention have been described above. It is to be understood that the invention is not limited to the specific embodiments described above, and various modifications and changes can be made by those skilled in the art within the scope of the appended claims.
Claims
1. 一种在无线通信系统中用于通过多个正交载波传输信号的无线发射 机, 包括: A wireless transmitter for transmitting signals over a plurality of orthogonal carriers in a wireless communication system, comprising:
一个串并转换装置, 用于将输入的串行符号数据序列串并转换多个 并行的符号数据序列; a serial to parallel conversion device for serially converting the input serial symbol data sequence into a plurality of parallel symbol data sequences;
一个 IFFT变换装置,用于对所述多个并行符号数据序列中进行 IFFT 正交变换, 生成多个时域数据块; An IFFT transforming apparatus, configured to perform IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks;
其特征在于, 还包括: It is characterized in that it further comprises:
一个数据块复用装置,用于将所述经过 IFFT正交变换后的多个时域 数据块按生成时间的先后顺序复用为基带的 OFTDM符号数据序列; 和 一个保护间隔添加装置, 用于在所述基带的 OFTDM符号数据序列 头部或尾部生成特定长度的保护间隔, 以生成待传输的基带 OFTDM信 号。 a data block multiplexing device, configured to multiplex the plurality of time-domain data blocks that have undergone IFFT orthogonal transform into a baseband OFTDM symbol data sequence in a sequence of generation time; and a guard interval adding device, configured to A guard interval of a specific length is generated at the head or tail of the OFTDM symbol data sequence of the baseband to generate a baseband OFTDM signal to be transmitted.
2. 根据权利要求 1所述的无线发射机, 其特征在于, 还包括: 所述保护间隔添加装置为一个循环前缀生成装置, 其用于将所述 OFTDM符号数据序列的尾部的特定数量数据, 作为循环前缀, 复制到 所述 OFTDM数据序列的头部, 生成具有循环前缀的正交频分时分符号 序列。 2. The wireless transmitter according to claim 1, further comprising: the guard interval adding means is a cyclic prefix generating means for using a specific amount of data of a tail portion of the OFTDM symbol data sequence, As a cyclic prefix, it is copied to the head of the OFTDM data sequence to generate a sequence of orthogonal frequency division time division symbols having a cyclic prefix.
3. 根据权利要求 1或 2所述的无线发射机, 其特征在于, 还包括: 一个控制装置, 还用于根据信道带宽, 信道相干带宽和信道时延长 度来调整所述 IFFT变换装置的变换矩阵的大小。 The wireless transmitter according to claim 1 or 2, further comprising: a control device, configured to adjust a transform of the IFFT transform device according to a channel bandwidth, a channel coherence bandwidth, and a channel time extension The size of the matrix.
4. 根据权利要求 3所述的无线发射机, 其特征在于, 4. The wireless transmitter of claim 3, wherein
所述控制装置还用于根据信道时延扩展的长度和 IFFT 变换矩阵的 大小来调整所述循环前缀的长度, 使其大于等于信道时延扩展的长度, 和小于等于所述 IFFT变换矩阵的大小。 The control device is further configured to adjust the length of the cyclic prefix to be greater than or equal to the length of the channel delay spread, and less than or equal to the size of the IFFT transform matrix, according to the length of the channel delay spread and the size of the IFFT transform matrix. .
5. 根据权利要求 4所述的无线发射机, 其特征在于, 5. The wireless transmitter of claim 4, wherein
所述控制装置还用于与多普勒频移或信道相干时间的大小变化相应 地调整所述数据块复用的数量, 以使其 OFTDM符号的等效时间长度小
于所述信道相干时间长度。 The control device is further configured to adjust the number of multiplexing of the data block according to a change in the size of the Doppler shift or the channel coherence time, so that the equivalent time length of the OFTDM symbol is small. The length of the channel coherence time.
6. 一种在无线通信系统的无线发射机中用于通过多个正交载波发送 信号的方法, 其包括以下步骤: 6. A method for transmitting a signal over a plurality of orthogonal carriers in a wireless transmitter of a wireless communication system, comprising the steps of:
将输入的串行符号数据序列串并转换多个并行符号数据序列; 对所述多个并行符号数据序列进行 IFFT正交变换,生成多个时域数 据块; And serially converting the input serial symbol data sequence into a plurality of parallel symbol data sequences; performing IFFT orthogonal transform on the plurality of parallel symbol data sequences to generate a plurality of time domain data blocks;
将所述经过 IFFT正交变换后的多个时域数据块按生成时间的先后 顺序复用为基带的 OFTDM符号数据序列; And multiplexing the plurality of time domain data blocks subjected to the IFFT orthogonal transform into a baseband OFTDM symbol data sequence in order of generation time;
在所述基带的 OFTDM符号数据序列头部或尾部添加特定长度的保 护间隔。 A guard interval of a specific length is added to the head or tail of the OFTDM symbol data sequence of the baseband.
7. 根据权利要求 6的方法, 其特征在于, 所述生成保护间隔的步骤 包括: 7. The method according to claim 6, wherein the step of generating a guard interval comprises:
将所述 OFTDM符号数据序列的尾部的特定数量数据, 作为循环前 缀, 复制到所述 OFTDM符号数据序列的头部, 生成具有循环前缀的 OFTDM符号序列。 A specific amount of data at the end of the OFTDM symbol data sequence is copied as a cyclic prefix to the header of the OFTDM symbol data sequence to generate an OFTDM symbol sequence having a cyclic prefix.
8.根据权利要求 6或 7所述的方法,其特征在于,还包括如下步骤: 根据信道带宽和信道时延长度来调整所述 IFFT 变换装置的变换矩 阵的大小。 The method according to claim 6 or 7, further comprising the step of: adjusting a size of the transform matrix of the IFFT transform device according to a channel bandwidth and a channel time extension.
9. 根据权利要求 8所述的方法, 其特征在于, 9. The method of claim 8 wherein:
根据信道时延扩展的长度和 IFFT 变换矩阵的大小来调整所述循环 前缀的长度, 使其大于等于信道时延扩展的长度, 和小于等于所述 IFFT 变换矩阵的大小自适应地调整所述 IFFT 变换装置的变换矩阵的长度, 使其大于等于所述循环前缀的长度。 Adjusting the length of the cyclic prefix to be greater than or equal to the length of the channel delay spread according to the length of the channel delay spread and the size of the IFFT transform matrix, and adaptively adjusting the IFFT less than or equal to the size of the IFFT transform matrix Transforming the length of the transformation matrix of the device to be greater than or equal to the length of the cyclic prefix.
10. 根据权利要求 9所述的方法, 其特征在于, 还包括以下步骤: 与多普勒偏移或信道相干时间的大小变化相应地调整所述 IFFT 变 换装置的数量, 以使其 OFTDM符号的等效时间长度小于所述信道相千 时间长度 10. The method according to claim 9, further comprising the step of: adjusting the number of the IFFT transform devices corresponding to a change in magnitude of a Doppler shift or a channel coherence time to make the OFTDM symbol The equivalent time length is less than the length of the channel phase
11. 一种在无线通信系统中用于接收通过多个正交载波传输的 OFTDM信号的无线接收机, 其包括
一个保护间隔去除装置, 用于去除变换到基带的具有保护间隔的11. A wireless receiver for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless communication system, comprising a guard interval removing device for removing guarded intervals that are converted to baseband
OFTDM符号序列之间的保护间隔; The guard interval between OFTDM symbol sequences;
一个数据块解复用装置, 用于将所述去除保护间隔的 OFTDM符号 序列解复用为多个数据块序列; a data block demultiplexing apparatus, configured to demultiplex the guard interval-removed OFTDM symbol sequence into a plurality of data block sequences;
一个 FFT变换装置, 用于按接收时间的先后顺序对所述多个数据块 进行 FFT变换, 将其变换为多个并行符号数据序列; An FFT transforming apparatus, configured to perform FFT transform on the plurality of data blocks in order of receiving time, and transform the plurality of data blocks into a plurality of parallel symbol data sequences;
一个并串转换装置, 用于将所述多个并行符号数据序列变换为串行 符号数据序列。 A parallel-to-serial conversion device for transforming the plurality of parallel symbol data sequences into serial symbol data sequences.
12. 根据权利要求 11所述的无线接收机, 其特征在于, 还包括 一个信道估计装置, 用于根据所述变换到基带的 OFTDM符号序列 来对时域的信道响应进行估计, 以获得信道响应的估计值; The radio receiver according to claim 11, further comprising a channel estimating means for estimating a channel response of the time domain according to the OFTDM symbol sequence converted to the baseband to obtain a channel response Estimated value;
一个时 /频变换装置, 用于将所述去除保护间隔的 OFTDM数据块序 列变换为频域的 OFTDM数据块序列; a time/frequency transforming apparatus, configured to transform the OFTDM data block sequence of the guard interval to a frequency domain OFTDM data block sequence;
一个频域均衡器, 用于基于所述信道响应的估计值, 来对所述被变 换到频域的 OFTDM数据块序列进行信道损伤的相位补偿和幅度补偿, 以获得经过频域均衡的频域 OFTDM数据块序列; a frequency domain equalizer, configured to perform phase compensation and amplitude compensation of the channel impairment on the OFTDM data block sequence transformed into the frequency domain based on the estimated value of the channel response, to obtain a frequency domain that is subjected to frequency domain equalization. OFTDM data block sequence;
一个频 /时变换装置, 用于将已经过频域均衡的频域 OFTDM数据块 序列重新变换为时域的 OFTDM数据块序列, 传输给所述数据块解复用 装置。 And a frequency/time transforming apparatus, configured to re-transform the frequency domain OFTDM data block sequence that has undergone frequency domain equalization into a time domain OFTDM data block sequence, and transmit the sequence to the data block demultiplexing device.
13. 根据权利要求 11或 12所述的无线接收机, 其特征在于, 所述频域均衡器包括: 单点频域最小均方误差 MMSE均衡器。 The wireless receiver according to claim 11 or 12, wherein the frequency domain equalizer comprises: a single point frequency domain minimum mean square error MMSE equalizer.
14. 根据权利要求 11或 12所述的无线接收机, 其特征在于, 所述频域均衡器为单点频域迫零均衡器。 The wireless receiver according to claim 11 or 12, wherein the frequency domain equalizer is a single-point frequency domain zero-forcing equalizer.
15. —种在无线通信系统的无线接收机中用于接收通过多个正交载 波传输的 OFTDM信号的方法, 其包括以下步驟: 15. A method for receiving an OFTDM signal transmitted over a plurality of orthogonal carriers in a wireless receiver of a wireless communication system, comprising the steps of:
去除基带 OFTDM符号的保护间隔; Removing the guard interval of the baseband OFTDM symbol;
将所述去除保护间隔的 OFTDM符号序列解复用为多个数据块序 列; Demultiplexing the guard interval-removed OFTDM symbol sequence into a plurality of data block sequences;
按接收时间的先后顺序对所述多个数据块进行 FFT变换, 将其变换
为多个并行符号数据序列; Performing FFT transformation on the plurality of data blocks in order of reception time, and transforming the same a sequence of multiple parallel symbol data;
将所述多个并行数据符号序列并串变换为串行符夸数据序列。 The plurality of parallel data symbol sequences are parallel-converted into a serial-characterized data sequence.
16. 根据权利要求 15所述的方法, 其特征在于, 还包括以下步驟: 根据所述变换到基带的 OFTDM符号序列或导频训练序列来对时域 的信道响应进行估计, 以获得信道响应的估计值; 16. The method according to claim 15, further comprising the step of: estimating a channel response of the time domain according to the OFTDM symbol sequence or the pilot training sequence transformed to the baseband to obtain a channel response. estimated value;
将所述去除保护间隔的 OFTDM数据块序列变换为频域的 OFTDM 数据块序列; Transforming the guard interval-removed OFTDM data block sequence into a frequency domain OFTDM data block sequence;
基于所述信道响应的估计值, 来对所述被变换到频域的 OFTDM数 据块序列进行信道损伤的相位补偿和幅度补偿, 以获得经过频域均衡的 频域 OFTDM数据块序列; Performing phase compensation and amplitude compensation of the channel impairment on the OFTDM data block sequence transformed into the frequency domain based on the estimated value of the channel response to obtain a frequency domain equalized frequency domain OFTDM data block sequence;
将已经过频域均衡的频域 OFTDM 数据块序列重新变换为时域的 OFTDM数据块序列, 用于进行所述数据块解复用操作。 The frequency domain OFTDM data block sequence that has undergone frequency domain equalization is reconverted into a time domain OFTDM data block sequence for performing the data block demultiplexing operation.
17. 根据权利要求 15或 16所述的方法, 其特征在于, 17. Method according to claim 15 or 16, characterized in that
所述频域均衡步驟为单点频域最小均方误差 MMSE均衡方法。 The frequency domain equalization step is a single point frequency domain minimum mean square error MMSE equalization method.
18. 根据权利要求 15或 16所述的方法, 其特征在于, 18. Method according to claim 15 or 16, characterized in that
所述频域均衡步骤为单点频域迫零均衡方法。
The frequency domain equalization step is a single point frequency domain zero forcing equalization method.
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