JP4644978B2 - OFDM communication system, OFDM communication method, and OFDM communication apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an OFDM communication system that performs data transmission by OFDM (Orthogonal Frequency Division Multiplexing Digital Modulation / Demodulation Processing, Ortho-gon Frequency Division Multiplexing).,OFDM communication methodAnd OFDM communication apparatusIt is about.
[0002]
[Prior art]
First, conventional transmission communication by OFDM (OFDM communication) will be described with reference to FIG. FIG. 4 is a timing chart showing a transmission signal waveform in OFDM communication. In OFDM communication, one of multicarrier modulation schemes is used, and a transmission signal is a combination of a large number (tens to thousands) of digital modulation waves (carrier waves 1 to k). As a modulation method for each carrier, BPSK, QPSK, 16QAM, 64QAM, or the like is used.
[0003]
FIG. 5 is a timing diagram showing transmission symbols in OFDM communication. Data transmission in OFDM communication is performed in units of transmission symbols shown in FIG. Each transmission symbol is composed of an effective symbol period and a period called a guard interval. The effective symbol period is a signal period substantially required for data transmission, and is a combined wave of a plurality of carriers as shown in FIG. The guard interval is a redundant signal period for reducing the influence of multipath, and is a cyclic repetition of a signal waveform having an effective symbol period. That is, the guard interval is a meaningless section from the viewpoint of information transmission, and the transmission efficiency improves as the guard interval is shorter. As shown in FIG. 5, a waveform obtained by copying a waveform of a certain period of the effective symbol period is used as a guard interval waveform.
[0004]
FIGS. 6A and 6B are spectrum diagrams showing the frequency spectrum in OFDM communication. When the frequency interval between each carrier is made equal to the reciprocal of the length of the effective symbol period, as shown in FIG. 6A, the zero point of the frequency spectrum of each digital modulation wave matches the carrier frequency of the adjacent modulation wave. There is no mutual interference between the carrier waves. At this time, each carrier wave is said to be orthogonal. As shown in FIG. 6B, the spectrum of the OFDM signal has a shape close to a rectangle as a whole. When the length of the effective symbol period is T and the number of carriers is K, the frequency interval between the carriers is 1 / T and the transmission bandwidth is K / T.
[0005]
In OFDM communication, about several tens to several hundreds of transmission symbols in FIG. 5 are collected to form one transmission frame. FIG. 7 is a frame diagram illustrating a configuration example of an OFDM transmission frame. The OFDM transmission frame shown in FIG. 7 includes a frame synchronization symbol in addition to a data transmission symbol.
[0006]
FIG. 8 is a block diagram showing a communication apparatus to which the OFDM communication method is applied.
[0007]
In FIG. 8, A is a transmission unit, A1 is a series-parallel converter, A2 is an inverse discrete Fourier transform unit, A3 is a guard interval addition unit, A4 is a frequency converter, B is a reception unit, B1 is a frequency converter, and B2 is The discrete Fourier transform unit B3 is a parallel-serial converter.
[0008]
Functions and operations of the communication apparatus configured as described above will be described.
[0009]
First, in the transmission unit A, binary transmission data is divided into data blocks each having a certain number of bits, and each data block is input in a state of being converted into one complex value. Then, one complex value di (i = 1 to N) is given for each carrier frequency by the serial / parallel converter A1, and inverse discrete Fourier transform is performed on the time axis by the inverse discrete Fourier transform unit A2. As a result, sample values of the time axis waveform are generated, and a part of the waveform is copied by the guard interval adder A3 to generate a sample value series representing a transmission symbol. From this sample value series, a temporally continuous baseband analog signal is obtained. The baseband analog signal is converted to a transmission frequency signal by the frequency converter A4 and transmitted.
[0010]
Here, the number of sample values on the time axis generated by the inverse discrete Fourier transform is usually 2n (n is a positive integer) per effective symbol period. Therefore, if the sampling period is represented by Ts and the guard interval period is represented by Tg, 2n + Tg / Ts sample values are generated per transmission symbol. Note that a fixed value is set for the guard interval time in each transmission symbol, and the value is an integral multiple of the sampling period.
[0011]
In the receiver B, the received signal is frequency-converted by the frequency converter B1 to obtain a baseband signal, and then sampled at the same sample rate as that of the transmitter A. The sample value series is subjected to discrete Fourier transform on the frequency axis by the discrete Fourier transform unit B2, and the received data value is obtained by calculating the phase and amplitude of each carrier frequency component, and serially converted by the parallel-serial converter B3. Convert and output.
[0012]
By the way, in OFDM communication, it is important to eliminate the influence of multipath by providing a guard interval in each symbol and to maintain orthogonality between each carrier. On the other hand, in the conventional OFDM communication method, the guard interval length of the data transmission symbol is fixed with the maximum delay time (worst value) of the expected transmission path, and even when the transmission path condition is good The transmission efficiency is suppressed by the worst value.
[0013]
[Problems to be solved by the invention]
Thus, in the conventional OFDM communication method, the guard interval length of the data transmission symbol cannot be set so as to be suitable for the state of the transmission path, and the maximum delay time of the multipath in the worst transmission path assumed in advance is assumed. I had to fix the guard interval length.
[0014]
  theseOFDM communication system,OFDM communication methodAnd OFDM communication apparatusTherefore, it is required to set the optimum guard interval length according to the state of the transmission path and realize the maximum transmission efficiency.
[0015]
  In order to satisfy this requirement, the present invention sets an optimum guard interval length according to the state of the transmission path and can realize the maximum transmission efficiency.,OFDM communication method for realizing maximum transmission efficiency by setting an optimum guard interval length according to the state of the transmission pathOFDM communication apparatus capable of realizing optimum transmission efficiency by setting an optimum guard interval length according to the state of the transmission pathThe purpose is to provide.
[0016]
[Means for Solving the Problems]
  In order to solve the above problems, an OFDM communication system according to the present invention includes a first transmitter, a receiver,HaveA first communication device;SecondTransmitter and receiverHaveAn OFDM communication system for performing data transmission by OFDM with a second communication device, wherein the first receiver receives a transmission signal from the second transmitter and multipaths the received signal. Estimate the maximum delay time ofWasA maximum delay time estimator that generates a guard interval length based on the maximum delay time; and a feedback unit that feeds back the generated guard interval length to the first transmission unit. The interval length is transmitted to the second communication device, the second reception unit detects the fed back guard interval length transmitted from the first transmission unit, and the second transmission unit detects the detected guard interval length. Send to the first communication device usingThe maximum delay time estimator obtains a correlation function value, estimates a point where the correlation function value is larger than a predetermined correlation function threshold value as a delay time, and the maximum delay time estimator determines the signal pair in each carrier of the received signal. Estimate the noise power ratio, and exclude carriers whose signal-to-noise power ratio is lower than the predetermined ratio from the correlation function calculationIt has a configuration.
[0017]
  As a result, an OFDM communication system capable of setting the optimum guard interval length according to the state of the transmission path and realizing the maximum transmission efficiency can be obtained.In addition, there is an effect that the influence can be reduced even under a transmission path in which high-level narrow-band noise such as power line communication is frequently generated.
[0018]
  In order to solve the above problems, an OFDM communication method of the present invention includes a first transmitter, a receiver,HaveA first communication device, a second transmitter and a receiver;HaveAn OFDM communication method for performing data transmission by OFDM with a second communication apparatus, wherein the first receiver receives a multipath from a received signal obtained by receiving a transmission signal from the second transmitter Estimate the maximum delay time ofWasA guard interval length based on the maximum delay time is generated, the generated guard interval length is fed back to the first transmitter, and the first transmitter transmits the fed back guard interval length to the second communication device, The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter uses the detected guard interval length to transmit to the first communication device. lineThe correlation function value is obtained, the point where the correlation function value is larger than the predetermined correlation function threshold is estimated as the delay time, the signal-to-noise power ratio in each carrier of the received signal is estimated, and the signal-to-noise power ratio is predetermined. Exclude carrier smaller than the ratio ofIt has a configuration.
[0019]
  As a result, an OFDM communication method for setting the optimum guard interval length according to the state of the transmission path and realizing the maximum transmission efficiency can be obtained.In addition, there is an effect that the influence can be reduced even under a transmission path in which high-level narrow-band noise such as power line communication is frequently generated.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
  According to the first inventionAn OFDM communication system includes a first transmitter, a receiver,HaveA first communication device;SecondTransmitter and receiverHaveAn OFDM communication system for performing data transmission by OFDM with a second communication device, wherein the first receiver receives a transmission signal from the second transmitter and multipaths the received signal. Estimate the maximum delay time ofWasA maximum delay time estimator that generates a guard interval length based on the maximum delay time; and a feedback unit that feeds back the generated guard interval length to the first transmission unit. The interval length is transmitted to the second communication device, the second reception unit detects the fed back guard interval length transmitted from the first transmission unit, and the second transmission unit detects the detected guard interval length. Send to the first communication device usingThe maximum delay time estimator obtains a correlation function value, estimates a point where the correlation function value is larger than a predetermined correlation function threshold value as a delay time, and the maximum delay time estimator determines the signal pair in each carrier of the received signal. Estimate the noise power ratio, and exclude carriers whose signal-to-noise power ratio is lower than the predetermined ratio from the correlation function calculationIs.
[0021]
  With this configuration, the guard interval length of each OFDM symbol in communication can be changed to the length with the best transmission efficiency according to the state of the transmission line, so that the maximum transmission efficiency in the transmission line state can be obtained in any transmission line In particular, the maximum transmission efficiency suitable for the transmission path formed by each communication apparatus can be obtained even with respect to a change in the transmission path state between the communication apparatuses in the multipoint-to-multipoint communication.In addition, there is an effect that the influence can be reduced even under a transmission path in which high-level narrow-band noise such as power line communication is frequently generated.
[0022]
  According to the second inventionThe OFDM communication systemAccording to the first inventionIn an OFDM communication system, the maximum delay time estimator performs inverse discrete Fourier transform on multiplication data obtained by multiplying a complex conjugate of data obtained by performing discrete Fourier transform on a synchronization symbol waveform and data obtained by performing discrete Fourier transform on a received signal. To obtain the correlation function valueTurnIs.
[0023]
With this configuration, there is an effect that the guard interval length of each OFDM symbol in communication can be reliably changed to the length with the best transmission efficiency according to the state of the transmission path.
[0026]
  According to the third inventionThe OFDM communication systemAccording to the first inventionIn the OFDM communication system, the maximum delay time estimator estimates the delay time using the correlation of only a few carrier waves in the received signal.
[0027]
With this configuration, the hardware scale can be greatly reduced as compared with the cross-correlation value calculation by FFT.
[0028]
  According to the fourth inventionThe OFDM communication systemFirst1 toInvention of 3EitherRelated to the inventionIn the OFDM communication system, the feedback unit classifies the maximum delay time for each predetermined range, and sets an information sequence corresponding to the predetermined range in advance between the first communication device and the second communication device. .
[0029]
With this configuration, information regarding the maximum delay time can be transmitted with a small number of bits, and the storage capacity necessary for storing the guard interval length can be reduced.
[0030]
  According to the fifth inventionThe OFDM communication systemFirst1 to4 inventionsEitherRelated to the inventionIn the OFDM communication system, the feedback unit transmits the update guard interval length to the first transmission unit only when the reception performance of the first reception unit deteriorates.
[0031]
This configuration has the effect of increasing the amount of information transmitted in the OFDM transmission frame, and can detect that the transmission path has changed on the receiving side. Therefore, it is possible to add a guard interval in consideration of the influence of the multipath received by the receiver, and to prevent the influence of the multipath upon reception at the partner side from exceeding the guard interval length.
[0032]
  According to the sixth inventionAn OFDM communication method includes a first transmitter, a receiver,HaveA first communication device, a second transmitter and a receiver;HaveAn OFDM communication method for performing data transmission by OFDM with a second communication apparatus, wherein the first receiver receives a multipath from a received signal obtained by receiving a transmission signal from the second transmitter Estimate the maximum delay time ofWasA guard interval length based on the maximum delay time is generated, the generated guard interval length is fed back to the first transmitter, and the first transmitter transmits the fed back guard interval length to the second communication device, The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter uses the detected guard interval length to transmit to the first communication device. lineThe correlation function value is obtained, the point where the correlation function value is larger than the predetermined correlation function threshold is estimated as the delay time, the signal-to-noise power ratio in each carrier of the received signal is estimated, and the signal-to-noise power ratio is predetermined. Exclude carrier smaller than the ratio ofIs.
[0033]
With this configuration, the guard interval length of each OFDM symbol in communication can be changed to the length with the best transmission efficiency according to the state of the transmission line, so that the maximum transmission efficiency in the transmission line state can be obtained in any transmission line In particular, the maximum transmission efficiency suitable for the transmission path formed by each communication apparatus can be obtained even with respect to a change in the transmission path state between the communication apparatuses in the multipoint-to-multipoint communication.
[0034]
Hereinafter, embodiments of the present invention will be described with reference to FIGS.
[0035]
(Embodiment 1)
First, an idea point of the OFDM communication system according to the first embodiment of the present invention will be described. Normally, an OFDM transmission frame includes a frame synchronization symbol in addition to a data transmission symbol at the start of the frame. This frame synchronization symbol section is composed of known data on the receiving side, and the same symbol is transmitted continuously several symbols. That is, in this section, orthogonality is not lost due to multipath generated in the transmission path, and a relatively stable signal can be received.
[0036]
Therefore, in the present embodiment, the maximum delay time of the multipath can be estimated using this frame synchronization symbol section.
[0037]
FIG. 1 is a block diagram showing an OFDM communication apparatus constituting an OFDM communication system according to Embodiment 1 of the present invention.
[0038]
In FIG. 1, reference numeral 100 denotes a transmission unit, and reference numeral 200 denotes a reception unit. The transmitting unit 100 includes a modulation / serial / parallel converter 101, an inverse discrete Fourier transformer 102, a parallel / serial converter 103, a synchronization / data transmission symbol switch 104, a synchronization symbol waveform storage device 105, A guard interval adder 106, a guard interval length storage device 107, a D / A converter 108, a band pass filter 109, and a frequency converter 110 are provided. The receiving unit 200 includes a band pass filter 201, a frequency converter 202, an A / D converter 203, a synchronization symbol waveform storage device 204, a synchronization symbol position detector 205, and a maximum delay time estimator. A multipath delay time estimator 206, a guard interval length storage device 207, a guard interval deleter 208, a serial-parallel converter 209, a discrete Fourier transformer 210, a demodulation / parallel-serial converter 211, and a feedback Unit 212.
[0039]
The operation of the OFDM communication apparatus configured as described above will be described.
[0040]
Modulation / serial / parallel converter 101 converts serial transmission data into parallel transmission data, and assigns it to each OFDM carrier. The inverse discrete Fourier transformer 102 determines the phase and amplitude of each carrier in the symbol period of the transmission data from the transmission data assigned to each carrier, considers the phase and amplitude as complex data on the frequency axis, and performs inverse processing. A discrete Fourier transform is performed, and a sample value of the transmission waveform on the time axis is output. The parallel-serial converter 103 converts the time sample value series output in parallel for each symbol into a serial sample value series.
[0041]
On the other hand, the synchronization symbol waveform storage device 105 outputs a sample value of the frame synchronization symbol waveform. The synchronization / data transmission symbol switcher 104 includes a time sample value sequence of data transmission symbols output from the parallel-serial converter 103 and a waveform sample value of frame synchronization symbols output from the synchronization symbol waveform storage device 105. By switching the sequence, it is converted into a time sample value sequence of the baseband OFDM signal and output.
[0042]
The guard interval length storage device 107 stores the guard interval length together with the transmission destination address, and outputs the corresponding guard interval length according to the transmission destination address. At this time, the stored guard interval length is a value fed back from the communication partner at the previous communication. Note that an assumed worst value is given as an initial value of the guard interval length (a guard interval length corresponding to a communication partner address having no previous communication history). The guard interval adder 106 adds a guard interval to the time sample value series output from the synchronization / data transmission symbol switch 104 according to the guard interval length output from the guard interval length storage device 107.
[0043]
The D / A converter 108 converts the time sample value series output from the guard interval adder 106 into an analog signal, and the band pass filter 109 removes an unnecessary frequency component of the analog signal and converts the analog baseband OFDM signal into an analog signal. Output. The frequency converter 110 up-converts the analog baseband OFDM signal to an intermediate frequency or a radio frequency and outputs it as a transmission signal.
[0044]
In receiving section 200, bandpass filter 201 removes out-of-band components of the received signal, and frequency converter 202 downconverts the intermediate frequency or radio frequency OFDM signal to baseband. The A / D converter 203 samples the baseband OFDM signal and converts it into a digital sample value series. The output is supplied to the guard interval deleter 208 and also to the synchronization symbol position detector 205 and the multipath delay time estimator 206.
[0045]
The synchronization symbol position detector 205 calculates the cross-correlation value between the sample value sequence of the baseband OFDM signal and the sample value sequence of the synchronization symbol waveform stored in the synchronization symbol waveform storage device 204 to calculate the frame head position. , And the transmission symbol switching position and FFT window position are determined.
[0046]
Similarly, the multipath delay time estimator 206 serving as the maximum delay time estimator is configured to calculate the sample value sequence of the baseband OFDM signal and the sample value sequence of the synchronization symbol waveform stored in the synchronization symbol waveform storage device 204. By calculating the cross-correlation value and detecting the peak value, the multipath delay time included in the received signal is estimated. At this time, the largest peak interval is the multipath maximum delay time. This maximum delay time is rounded to a value that is an integral multiple of the sampling period, and stored in the guard interval length storage device 207 together with the source address.
[0047]
The guard interval deleting unit 208 searches the guard interval length storage device 207 for the guard interval length based on the transmission source address, and removes the guard interval portion data from the sample value series with the value. At this time, the guard interval length stored in the guard interval length storage device 207 stores the guard interval information transmitted to the transmission source when the previous communication was performed. The serial / parallel converter 209 converts the baseband sample value series into parallel data and supplies the parallel data to the discrete Fourier transformer 210. The discrete Fourier transformer 210 converts a baseband sample value on the time axis into a spectrum for each carrier frequency. The demodulator / parallel converter 211 estimates the phase and amplitude of each carrier wave from the value of the frequency spectrum, obtains the value of received data from the value of the phase and amplitude, further converts it to a serial received data sequence and outputs it. .
[0048]
In the above OFDM communication apparatus, the guard interval length determined by the receiving unit 200 and stored in the guard interval length storage device 207 is converted into an appropriate transmission data sequence by the feedback unit 212 in the subsequent communication, and then transmitted. OFDM processing is similarly performed as part of the data series, and is fed back to the corresponding transmission source (the counterpart OFDM communication apparatus) as one piece of information in the OFDM transmission frame.
[0049]
That is, in the first communication, communication is performed with a preset guard interval added regardless of the state of the transmission line, but in the second and subsequent communication, the maximum transmission rate according to the transmission line state Can be obtained.
[0050]
Therefore, if an OFDM communication system using the OFDM communication apparatus according to the present embodiment is constructed, communication can be performed at an optimum transmission rate according to the transmission path state. Furthermore, when one-channel packet communication is performed using the OFDM communication apparatus according to the present embodiment, if there is a means for knowing the source address even if they are not in communication with each other, Since the multipath state from the transmission source can be estimated, the guard interval length can be transmitted to the other party even if it is the first communication at the next data transfer to the other party.
[0051]
By the way, the multipath delay time estimator 206 in FIG. 1 uses a cross-correlation value between the sample value sequence of the baseband OFDM signal and the sample value sequence of the synchronization symbol waveform stored in the synchronization symbol waveform storage device 204. However, it is also possible to perform cross-correlation calculation by FFT using a demodulated complex symbol for each carrier frequency after discrete Fourier transform and a complex symbol obtained by performing discrete Fourier transform on the synchronization symbol waveform.
[0052]
FIG. 2 is a block diagram showing a multipath delay time estimator 206 to which the above cross correlation calculation is applied. The multipath delay time estimator 206 includes a discrete Fourier transformer 301, a demodulation / parallel serial converter 302, a known symbol storage device 303, a multiplier 304, an inverse discrete Fourier transformer 305, and a maximum delay time detection. Device 306. The discrete Fourier transformer 301 and the demodulation / parallel / serial converter 302 in FIG. 2 are the same as the discrete Fourier transformer 210 and the demodulation / parallel / serial converter 211 in FIG. The discrete Fourier transformer 301 performs a Fourier transform on the sample value of the received signal to obtain complex data. The output is supplied to the demodulator / parallel converter 302 and also to the multiplier 304.
[0053]
On the other hand, the known symbol storage device 303 stores a complex conjugate of data obtained by discrete Fourier transform of the synchronization symbol waveform. The multiplier 304 multiplies the output from the discrete Fourier transformer 301 and the output from the known symbol storage device 303, and the inverse discrete Fourier transformer 305 performs an inverse discrete Fourier transform on the output from the multiplier 304. As a result, a correlation value at each time in the sampling cycle interval can be obtained. The maximum delay time detector 306 estimates the maximum delay time by calculating the maximum interval between points at which peaks appear in the correlation value, and determines the guard interval length.
[0054]
In the configuration of FIG. 2, the discrete Fourier transformer 301 and the inverse discrete Fourier transformer 305 are used separately, but even one can be realized by using a Fourier transformer that can perform Fourier transformation in both forward and reverse directions. It is.
[0055]
Usually, a Fourier transformer is indispensable for OFDM processing, so a communication device using OFDM transmission is equipped with a Fourier transformer. Therefore, by using this method, the hardware installed in the conventional OFDM communication device can be used effectively, and the cost can be reduced.
[0056]
Furthermore, if cross-correlation calculation by FFT is used, tolerance against high level narrowband noise can be improved. To explain this, in FIG. 2, it is expected to be received before multiplying the demodulated complex symbol for each carrier frequency after discrete Fourier transform by the conjugate complex of the complex symbol obtained by discrete Fourier transform of the synchronization symbol waveform. A level comparator is provided for comparing the level of the desired signal and the level of the actually received signal for each carrier wave. In this level comparator, when the difference between the desired signal level and the received signal level is larger than a certain threshold value, no multiplication is performed between symbols in the carrier wave, and the value is set to zero. Thereafter, an inverse discrete Fourier transform may be performed on the complex value after multiplication as described above. According to this method, it is possible to reduce the influence even under a transmission line in which high-level narrow-band noise such as power line communication frequently occurs.
[0057]
In FIG. 2, all the carriers are used in the cross-correlation calculation. However, in a transmission line that has been known to have few delay waves to some extent, the correlation value is obtained using complex symbols of several carriers at most. May be. Because the influence of multipath is considered to be the same in attenuation rate and delay time between adjacent carriers, the demodulated data is subjected to amplitude / phase distortion proportional to these parameters and the frequency of each carrier. From this, for example, assuming that the influential delayed wave is n waves, 2n with the attenuation rate and delay time associated with each of the n delayed waves as variables and the demodulated complex symbol of each carrier wave of n waves as a constant part. The original simultaneous quadratic equation holds. When the value of n is small, that is, when the number of arriving delayed waves is small, it is relatively easy to solve the simultaneous equations, and the hardware scale can be greatly reduced as compared with the cross-correlation value calculation by FFT.
[0058]
FIG. 3 is a block diagram showing a multipath delay time estimator 206 to which the cross correlation calculation is applied. The multipath delay time estimator 206 includes a discrete Fourier transformer 401, a demodulation / parallel serial converter 402, a known symbol storage device 403, a carrier wave selector 404, a simultaneous equation calculator 405, and a maximum delay time detection. Instrument 406. The discrete Fourier transformer 401 and the demodulator / parallel converter 402 in FIG. 3 are the same as the discrete Fourier transformer 301 and the demodulator / parallel converter 302 in FIG. The discrete Fourier transformer 401 performs a Fourier transform on the sample value of the received signal to obtain complex data. The output is supplied to the demodulator / parallel converter 402 and also to the carrier selector 404.
[0059]
On the other hand, the known symbol storage device 403 stores a complex conjugate of data obtained by performing discrete Fourier transform on the synchronization symbol waveform. The carrier wave selector 404 selects several carrier waves to be subjected to cross-correlation calculation from the outputs of the discrete Fourier transformer 401 and sets up simultaneous equations together with the output of the known symbol storage device 403. The simultaneous equation calculator 405 solves the simultaneous equations supplied from the carrier wave selector 404. As a result, the delay time for each delay wave can be calculated. The maximum delay time detector 406 extracts the largest value from the obtained delay times, so that the maximum delay time is estimated and the guard interval length can be determined.
[0060]
Further, in FIG. 3, the maximum delay time is divided for each range, and an information sequence corresponding to the range is set in advance on the transmission side and the reception side. In this case, information regarding the maximum delay time can be transmitted with a small number of bits, and the storage capacity required for storing the guard interval length can be reduced.
[0061]
Also, in FIG. 3, when the reception performance in the receiving unit 200 is deteriorated, for example, only when the error rate is larger than before, information on the guard interval is updated so that the maximum delay time is updated for the communication destination. There is also a way to communicate. According to this method, the amount of information transmitted in the OFDM transmission frame can be increased, and since it is possible to detect that the transmission path has changed on the receiving side, A guard interval considering the influence of multipath can be added, and it is possible to prevent the influence of multipath upon reception at the other side from exceeding the guard interval length.
[0062]
As described above, according to the present embodiment, data transmission is performed by OFDM between the second transmission device including the second transmission unit and the reception unit having the same configuration as the first transmission unit and the reception unit. In the OFDM communication system, the first receiving unit estimates the multipath maximum delay time from the received signal obtained by receiving the transmission signal from the second transmitting unit, and guards based on the estimated maximum delay time A maximum delay time estimator 206 that generates an interval length, and a feedback unit 212 that feeds back the generated guard interval length to the first transmission unit. The first transmission unit sets the fed back guard interval length to the first The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter detects the detected guard event. By performing transmission to the first communication device using the Tarval length, the guard interval length of each OFDM symbol in communication can be changed to the length with the highest transmission efficiency according to the state of the transmission path, In any transmission line, the maximum transmission efficiency in the transmission line state can be obtained, and in particular, the transmission formed by each change even with respect to a change in the transmission line state between communication devices in multipoint-to-multipoint communication Maximum transmission efficiency suitable for the road can be obtained.
[0063]
Further, the maximum delay time estimator 206 performs correlation by performing inverse discrete Fourier transform on the multiplication data obtained by multiplying the complex conjugate of the data obtained by discrete Fourier transform of the synchronization symbol waveform and the data obtained by performing discrete Fourier transform on the received signal. By calculating the function value and estimating the point where the correlation function value is larger than the predetermined correlation function threshold as the delay time, the guard interval length of each OFDM symbol in communication is set to the highest transmission efficiency according to the state of the transmission path. Can be changed to a good length.
[0064]
Further, the maximum delay time estimator 206 estimates the signal-to-noise power ratio in each carrier of the received signal, and excludes the carrier whose signal-to-noise power ratio is smaller than a predetermined ratio from the target of the correlation function calculation. As a result, it is possible to reduce the influence even under a transmission line in which high-level narrow-band noise such as power line communication frequently occurs.
[0065]
Furthermore, the maximum delay time estimator 206 estimates the delay time by using the correlation of only a few carrier waves in the received signal, thereby greatly increasing the hardware scale compared to the cross-correlation value calculation by FFT. Can be reduced.
[0066]
Furthermore, the feedback unit 212 divides the maximum delay time into predetermined ranges, and the information sequence corresponding to the predetermined range is set in advance between the first communication device and the second communication device, whereby the maximum delay time is set. Information about time can be transmitted with a small number of bits, and the storage capacity necessary for storing the guard interval length can be reduced.
[0067]
Furthermore, the feedback unit 212 increases the amount of information transmitted in the OFDM transmission frame by transmitting the update guard interval length to the first transmission unit only when the reception performance in the first reception unit deteriorates. Since it is possible to detect that the transmission path has changed on the receiving side, a guard interval that takes into account the effects of the multipath received by you is added the next time you communicate with that party. It is also possible to prevent the influence of multipath upon reception at the other party from exceeding the guard interval length.
[0068]
  As explained aboveAccording to the first inventionAccording to the OFDM communication system, the first transmitter and the receiverHaveA first communication device;SecondTransmitter and receiverHaveAn OFDM communication system for performing data transmission by OFDM with a second communication device, wherein the first receiver receives a transmission signal from the second transmitter and multipaths the received signal. Estimate the maximum delay time ofWasA maximum delay time estimator that generates a guard interval length based on the maximum delay time; and a feedback unit that feeds back the generated guard interval length to the first transmission unit. The interval length is transmitted to the second communication device, the second reception unit detects the fed back guard interval length transmitted from the first transmission unit, and the second transmission unit detects the detected guard interval length. Send to the first communication device usingThe maximum delay time estimator obtains a correlation function value, estimates a point where the correlation function value is larger than a predetermined correlation function threshold value as a delay time, and the maximum delay time estimator determines the signal pair in each carrier of the received signal. Estimate the noise power ratio, and exclude carriers whose signal-to-noise power ratio is lower than the predetermined ratio from the correlation function calculationAs a result, the guard interval length of each OFDM symbol in communication can be changed to the length with the best transmission efficiency according to the state of the transmission line, so that the maximum transmission efficiency in the transmission line state can be obtained in any transmission line. In particular, even in the case of a change in the transmission path state between communication devices in a multipoint-to-multipoint communication, there is an advantageous effect that the maximum transmission efficiency suitable for the transmission path formed by each can be obtained. It is done.In addition, there is an advantageous effect that it is possible to reduce the influence even under a transmission path in which high-level narrow-band noise such as power line communication is frequently generated.
[0069]
  According to the second inventionAccording to the OFDM communication system,According to the first inventionIn an OFDM communication system, the maximum delay time estimator performs inverse discrete Fourier transform on the multiplied data obtained by multiplying the complex conjugate of the data obtained by performing discrete Fourier transform on the synchronization symbol waveform and the data obtained by performing discrete Fourier transform on the received signal. The correlation function value is obtained by the above, and the point at which the correlation function value is larger than the predetermined correlation function threshold is estimated as the delay time, so that the guard interval length of each OFDM symbol in communication is set to the highest transmission efficiency according to the state of the transmission path. An advantageous effect is obtained that the length can be reliably changed to a good length.
[0071]
  According to the third inventionAccording to the OFDM communication system,According to the first inventionIn an OFDM communication system, the maximum delay time estimator significantly reduces the hardware scale compared to the cross-correlation value calculation by FFT by estimating the delay time using the correlation of only a few carriers of the received signal. The advantageous effect of being able to do this is obtained.
[0072]
  According to the fourth inventionAccording to the OFDM communication system,First1 to3eitherRelated to the inventionIn the OFDM communication system, the feedback unit divides the maximum delay time into predetermined ranges, and sets the information sequence corresponding to the predetermined range in advance between the first communication device and the second communication device, so that the maximum delay time is obtained. As a result, it is possible to transmit the information on a small number of bits, and it is possible to obtain an advantageous effect that the storage capacity necessary for storing the guard interval length can be reduced.
[0073]
  According to the fifth inventionAccording to the OFDM communication system,First1 to4EitherRelated to the inventionIn the OFDM communication system, the feedback unit increases the amount of information transmitted in the OFDM transmission frame by transmitting the update guard interval length to the first transmission unit only when the reception performance in the first reception unit deteriorates. Since it is possible to detect that the transmission path has changed on the receiving side, a guard interval that takes into account the effects of the multipath received by you is added the next time you communicate with that party. Therefore, an advantageous effect is obtained that it is possible to prevent the influence of the multipath upon reception on the other side from exceeding the guard interval length.
[0074]
  According to the sixth inventionAccording to the OFDM communication method, the first transmitter and the receiverHaveA first communication device, a second transmitter and a receiver;HaveAn OFDM communication method for performing data transmission by OFDM with a second communication apparatus, wherein the first receiver receives a multipath from a received signal obtained by receiving a transmission signal from the second transmitter Estimate the maximum delay time ofWasA guard interval length based on the maximum delay time is generated, the generated guard interval length is fed back to the first transmitter, and the first transmitter transmits the fed back guard interval length to the second communication device, The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter uses the detected guard interval length to transmit to the first communication device. lineThe correlation function value is obtained, the point where the correlation function value is larger than the predetermined correlation function threshold is estimated as the delay time, the signal-to-noise power ratio in each carrier of the received signal is estimated, and the signal-to-noise power ratio is predetermined. Exclude carrier smaller than the ratio ofAs a result, the guard interval length of each OFDM symbol in communication can be changed to the length with the best transmission efficiency according to the state of the transmission line, so that the maximum transmission efficiency in the transmission line state can be obtained in any transmission line. In particular, even in the case of a change in the transmission path state between communication devices in a multipoint-to-multipoint communication, there is an advantageous effect that the maximum transmission efficiency suitable for the transmission path formed by each can be obtained. It is done.In addition, there is an advantageous effect that it is possible to reduce the influence even under a transmission path in which high-level narrow-band noise such as power line communication is frequently generated.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an OFDM communication apparatus constituting an OFDM communication system according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a multipath delay time estimator to which cross-correlation calculation is applied.
FIG. 3 is a block diagram illustrating a multipath delay time estimator to which cross-correlation calculation is applied.
FIG. 4 is a timing chart showing transmission signal waveforms in OFDM communication.
FIG. 5 is a timing diagram showing transmission symbols in OFDM communication.
6A is a spectrum diagram showing a frequency spectrum in OFDM communication. FIG. 6B is a spectrum diagram showing a frequency spectrum in OFDM communication.
FIG. 7 is a frame diagram illustrating a configuration example of an OFDM transmission frame.
FIG. 8 is a block diagram showing a communication apparatus to which the OFDM communication method is applied.
[Explanation of symbols]
100 Transmitter
101 Modulation / serial / parallel converter
102,305 Inverse discrete Fourier transform
103 Parallel to serial converter
104 Symbol switch for synchronization / data transmission
105, 204 Symbol waveform storage device for synchronization
106 Guard interval adder
107, 207 Guard interval length storage device
108 D / A converter
109, 201 Band pass filter
110, 202 Frequency converter
200 Receiver
203 A / D converter
205 Symbol position detector for synchronization
206 Multipath delay time estimator (maximum delay time estimator)
208 Guard interval remover
209 Series-parallel converter
210, 301, 401 Discrete Fourier Transform
211, 302, 402 Demodulator / parallel converter
303, 403 Known symbol storage device
304 multiplier
306, 406 Maximum delay time detector
404 Carrier selector
405 simultaneous equation calculator

Claims (9)

The first communication device having a receiving portion and the first transmission unit, the OFDM with the second communication device having a receiving portion and a second transmission section a OFDM communication system for performing data transmission ,
The first receiving unit estimates a multipath maximum delay time from a reception signal obtained by receiving a transmission signal from the second transmission unit, and sets a guard interval length based on the estimated maximum delay time. A maximum delay time estimator to be generated; and a feedback unit that feeds back the generated guard interval length to the first transmitter. The first transmitter has the guard interval length fed back as the first 2 to the communication device
The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter uses the detected guard interval length to detect the first There line to send to the communication device,
The maximum delay time estimator obtains a correlation function value, estimates a point where the correlation function value is larger than a predetermined correlation function threshold as a delay time,
The maximum delay time estimator estimates a signal-to-noise power ratio in each carrier of a received signal, and excludes a carrier whose signal-to-noise power ratio is smaller than a predetermined ratio from the target of the correlation function calculation An OFDM communication system. The maximum delay time estimator, the correlation function by performing an inverse discrete Fourier transform on the multiplied data obtained by multiplying the data discrete Fourier transform by the complex conjugate and the received signal of the data discrete Fourier transform synchronizing symbol waveform OFDM communication system according to claim 1, characterized in that the value Mel determined. The OFDM communication system according to claim 1, wherein the maximum delay time estimator estimates a delay time by using a correlation of only several carriers among received signals. The feedback unit divides a maximum delay time for each predetermined range, and presets an information sequence corresponding to the predetermined range between the first communication device and the second communication device. The OFDM communication system according to any one of 1 to 3 . The feedback unit, wherein communicating the updated guard interval length in the first transmission section only when the reception performance is degraded to any one of claims 1 to 4, characterized in the said first receiver OFDM communication system. An OFDM communication method for performing data transmission by OFDM between a first communication device having a first transmitter and a receiver and a second communication device having a second transmitter and a receiver. ,
The first receiving unit estimates a multipath maximum delay time from a reception signal obtained by receiving a transmission signal from the second transmission unit, and sets a guard interval length based on the estimated maximum delay time. Generating and feeding back the generated guard interval length to the first transmission unit, the first transmission unit transmitting the fed back guard interval length to the second communication device,
The second receiver detects the fed back guard interval length transmitted from the first transmitter, and the second transmitter uses the detected guard interval length to detect the first There line to send to the communication device,
Obtaining a correlation function value, estimating a point where the correlation function value is greater than a predetermined correlation function threshold as a delay time;
An OFDM communication method , wherein a signal-to-noise power ratio in each carrier wave of a received signal is estimated, and a carrier wave having a signal-to-noise power ratio smaller than a predetermined ratio is excluded from the correlation function calculation target . The correlation function value is obtained by performing inverse discrete Fourier transform on the multiplication data obtained by multiplying the complex conjugate of the data obtained by performing discrete Fourier transform on the synchronization symbol waveform and the data obtained by performing discrete Fourier transform on the received signal. The OFDM communication method according to claim 6. An OFDM communication device that performs data transmission with another OFDM communication device by OFDM,
A first transmitter;
A first receiving unit;
The first receiving unit includes:
A maximum delay time estimator that estimates a multipath maximum delay time from a received signal obtained by receiving a transmission signal from the other OFDM communication apparatus and generates a guard interval length based on the estimated maximum delay time; ,
A feedback unit that feeds back the generated guard interval length to the first transmission unit;
The first transmission unit transmits the fed back guard interval length to the other OFDM communication device,
The maximum delay time estimator obtains a correlation function value, estimates a point where the correlation function value is larger than a predetermined correlation function threshold as a delay time,
The maximum delay time estimator estimates a signal-to-noise power ratio in each carrier of a received signal, and excludes a carrier whose signal-to-noise power ratio is smaller than a predetermined ratio from the target of the correlation function calculation. An OFDM communication apparatus. The maximum delay time estimator performs the inverse discrete Fourier transform on the multiplication data obtained by multiplying the complex conjugate of the data obtained by performing discrete Fourier transform on the synchronization symbol waveform and the data obtained by performing discrete Fourier transform on the received signal, thereby performing the correlation function. 9. The OFDM communication apparatus according to claim 8, wherein a value is obtained .

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