JP2010028549A - Signal transmission apparatus and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal transmission apparatus for wide band transmission of high quality in real time, using multi carrier. <P>SOLUTION: Each of input signals having been parallel-converted is subjected to modulation for subcarrier, and a frequency component of 0 is inserted into a frequency which is out of band, for over sampling, to be subjected to the inverse Fourier transform thereafter. Further, the signal that has been subjected to the inverse Fourier transform is converted into synchronized analogue signal. It is subjected to frequency conversion so that the central frequency in the frequency band of the analogue signal becomes the central frequency in the frequency band of a subcarrier group. Then, the signal of the frequency band of subcarrier group is extracted to generate a multicarrier signal of the subcarrier group of which an interference part is removed. After that, the multicarrier signal of the subcarrier group generated serially is synthesized, for generating multicarrier signal of ultrawide band for the input signal. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a multicarrier signal transmission apparatus and method.

Conventionally, in a wireless transmission device in a communication system using multicarriers, after modulation is performed for each subcarrier, inverse Fourier transform is performed collectively and a modulation signal is generated by combining them (for example, Non-patent document 1).
SL Jansen, I. Morita, N. Takeda, H. Tanaka: “20-Gb / s OFDM Transmission over 4160-km SSMF Enabled by RF-Pilot Tone Phase Noise Compensation“, OFC 2007, pdp15, USA, 2007

  In recent years, it has been studied to use a multicarrier in broadband transmission such as optical communication. However, in the conventional technique, since the inverse Fourier transform is collectively performed after the modulation is performed for each subcarrier, the processing speed of the modulation circuit, the inverse Fourier transform, the GI (guard interval) insertion circuit, the D / A ( The data rate is limited by the operating speed of the (digital / analog) converter / frequency conversion circuit, and it has not been possible to perform processing faster than that in real time. Therefore, it is conceivable to divide the transmission band into a plurality of subcarrier groups and generate a modulation signal using a plurality of fast inverse Fourier transformers. In such a method, after frequency conversion, other subcarriers are generated. Interference will occur, leading to degradation of transmission quality. Further, in order to avoid interference, it is necessary to sufficiently separate the frequency intervals of the subcarrier groups, and the frequency utilization efficiency is lowered.

  The present invention has been made in consideration of such circumstances, and an object of the present invention is to provide a signal transmission apparatus and method capable of real-time and high-quality broadband transmission using multicarriers.

  In order to solve the above-described problems, the present invention provides a serial-parallel converter that converts an input signal into a plurality of parallel signals, each corresponding to a subcarrier group of a multicarrier signal, and for the plurality of parallel signals, A plurality of processing units that generate a signal of a subcarrier group corresponding to, a combining unit that generates a multicarrier signal by combining the signals of each subcarrier group generated by the plurality of processing units, and the combining unit A transmission unit that transmits a combined multicarrier signal, and each of the plurality of processing units includes: an input signal modulation unit that modulates each parallel signal into subcarriers; and a frequency of the signal modulated by the input signal modulation unit A zero insertion unit that inserts a zero frequency component into a frequency outside the band, and an inverse Fourier transform to the signal with the zero frequency component inserted by the zero insertion unit An inverse Fourier transform unit to perform, a digital / analog conversion unit that converts the signal subjected to the inverse Fourier transform by the inverse Fourier transform unit into an analog signal synchronized with another processing unit, and an analog signal by the digital / analog conversion unit The frequency conversion unit converts the frequency of the converted signal so that the center frequency of the frequency band of the signal is the center frequency of the frequency band of the subcarrier group corresponding to the processing unit, and frequency conversion by the frequency conversion unit A bandpass filter that extracts a signal in a frequency band used by a subcarrier group corresponding to the processing unit from the processed signal, and the synthesis unit synthesizes the signal extracted by the bandpass filter and A signal transmission apparatus that generates a multicarrier signal.

  Further, the present invention is the above-described signal transmission device, wherein each of the plurality of processing units further includes a guard interval insertion unit that inserts a guard interval into the signal subjected to inverse Fourier transform by the inverse Fourier transform unit. Features.

  Further, the present invention is the above-described signal transmission device, wherein each of the plurality of processing units performs a smoothing process at a joint between Fourier transform blocks of a signal in which a guard interval is inserted by the guard interval insertion unit Is further provided.

  In addition, the present invention is the signal transmission device described above, wherein the transmission unit transmits a multicarrier signal using an optical signal.

  In addition, the present invention is the above-described signal transmission device, wherein the transmission unit includes an optical intensity modulator that converts the electrical multicarrier signal synthesized by the synthesis unit into an optical signal.

  Also, the present invention is the signal transmission apparatus described above, wherein the transmission unit generates an optical signal using the I-component and Q-component signals of the multicarrier signal synthesized by the synthesis unit as drive signals. It is characterized by providing a vessel.

  The present invention also relates to a serial-parallel conversion process in which a serial-parallel conversion unit converts an input signal into a plurality of parallel signals and a subcarrier group of the multi-carrier signal in a signal transmission apparatus that transmits a multi-carrier signal. A plurality of processing units generate a signal of a subcarrier group corresponding to the plurality of parallel signals, and a combining unit is generated by the plurality of processing units in the signal processing step. A combination process of combining the signals of each subcarrier group to generate a wideband multicarrier signal, and a transmission process of transmitting the multicarrier signal combined in the combination process, wherein each of the plurality of processes The input signal modulation unit modulates each parallel signal into subcarriers, and the zero insertion process. A zero insertion process for inserting a zero frequency component into a frequency outside the frequency band of the signal modulated in the input signal modulation process, and an inverse Fourier transform unit for inserting a zero frequency component in the zero insertion process. An inverse Fourier transform process for performing an inverse Fourier transform on the received signal, and a digital / analog conversion process in which the digital / analog conversion unit converts the signal subjected to the inverse Fourier transform in the inverse Fourier transform process into an analog signal synchronized with another processing unit. The frequency conversion unit converts the signal converted into the analog signal in the digital-analog conversion process so that the center frequency of the frequency band of the signal becomes the center frequency of the frequency band of the subcarrier group corresponding to the processing unit. A frequency changing process for converting the frequency into a frequency band and a bandpass filter are converted in the frequency converting process. An extraction process for extracting a signal in a frequency band used by a subcarrier group corresponding to the processing unit from the received signal. In the synthesis process, the synthesis unit extracts the signal extracted in the extraction process. A signal transmission method characterized in that the multicarrier signal is generated by combining.

  According to the present invention, it is possible to realize a steep band-pass filter that is difficult to realize with only a conventional analog filter, and to remove interference from outside the band divided for each subcarrier group. By performing frequency conversion on each of the subcarrier groups and combining them, real-time and high-quality broadband transmission using multicarriers can be realized. Also, since zero insertion, guard interval insertion, and smoothing processing are performed in parallel for each subcarrier group, it is possible to operate with a slow clock.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<First Embodiment>
FIG. 1 is a block diagram showing a configuration of a signal transmission apparatus according to the first embodiment of the present invention. In the figure, a signal transmission device transmits a signal to a signal generation circuit 1 that modulates binary data into an output signal of a wideband frequency, a signal light source 3 that generates an optical carrier of frequency fc, and an optical carrier generated by the signal light source 3. It comprises an optical intensity modulator 4 that generates and outputs a broadband optical multicarrier signal on the output A, which is a broadband electrical multicarrier signal output from the generation circuit 1.

FIG. 2 is a block diagram showing a detailed configuration of the signal generation circuit 1 shown in FIG.
In the figure, an S / P (serial parallel) conversion circuit 11 converts an input signal of binary data input to the signal generation circuit 1 into a parallel signal and outputs it to a modulation circuit 12-i (i = 1 to k). To do. Each of the modulation circuits 12-i (i = 1 to k) corresponds to a subcarrier group in which the subcarriers of the multicarrier signal are grouped into a predetermined number, and from the S / P conversion circuit 11 by a predetermined modulation method. Modulates the input signal into subcarriers. Hereinafter, subcarrier groups corresponding to the respective modulation circuits 12-i will be referred to as subcarrier groups i, respectively.

  The 0 insertion circuit 13-i (i = 1 to k) inserts a frequency component of 0 in a frequency band outside the frequency band of the signal modulated by the modulation circuit 12-i. The inverse Fourier transform circuit 14-i (i = 1 to k) performs inverse Fourier transform on the signal in which the zero frequency component is inserted by the zero insertion circuit 13-i. The GI (guard interval) insertion circuit 15-i (i = 1 to k) inserts a guard interval into the signal subjected to inverse Fourier transform by the inverse Fourier transform circuit 14-i. The smoothing circuit 16-i (i = 1 to k) performs smoothing by digital signal processing on the joints between the Fourier transform blocks. The D / A conversion circuit 17-i (i = 1 to k) converts the digital signal into a synchronized analog signal using the clock by the common clock 21.

  The frequency conversion circuit 18-i (i = 1 to k) converts the frequency of the analog signal using the oscillation signal from the local oscillator 22. At this time, the center frequency in the frequency band of the analog signal output from the D / A conversion circuit 17-i (hereinafter, the center frequency in the frequency band is referred to as “the center frequency of the frequency band”) is a subcarrier. Frequency conversion is performed so as to be the center frequency of the frequency band used by the group. The BPF (band pass filter) 19-i (i = 1 to k) extracts a frequency band signal used by the subcarrier group from the frequency-converted signal. The synthesizing circuit 20 synthesizes the subcarrier group i output from each of the BPFs 19-i (i = 1 to k), generates a baseband signal of a wideband multicarrier signal, and outputs it as an output A.

  FIG. 3 is a diagram showing a configuration of the light intensity modulator 4 shown in FIG. As shown in the drawing, a Mach-Zehnder type modulator is used for the light intensity modulator 4, and the output A from the signal generation circuit 1 is input thereto. As a result, the light intensity modulator 4 generates a DSB (double sideband) optical multicarrier signal around the optical carrier having the frequency fc emitted from the signal light source 3. When the light intensity modulator 4 is driven, if the bias point is set to half of the half-wave voltage (V), the optical carrier remains, and if the bias point is set to the NULL point, the light carrier can be suppressed.

Next, signal processing by the signal transmission apparatus described above will be described.
First, the S / P conversion circuit 11 converts the binary signal input to the signal generation circuit 1 from a serial signal to a parallel signal having a predetermined data length, and sends it to the modulation circuit 12-i (i = 1 to k). Output. The modulation circuit 12-i (i = 1 to k) is S in accordance with a predetermined modulation method, for example, 16QAM (Quadrature Amplitude Modulation), 64QAM, QPSK (Quadrature Phase Shift Keying) or the like. The data input from the / P conversion circuit 11 is modulated, mapped to subcarriers assigned to data among the subcarriers of the subcarrier group i, and output to the 0 insertion circuit 13-i. Specifically, for each subcarrier assigned to data, a signal composed of an in-phase component (I component) and a quadrature component (Q component) is output. It is also possible to output fixed I component and Q component signals to subcarriers not assigned as data. The subcarriers to which data and fixed signals are allocated can be set, for example, inside the subcarrier group i, and no signal is allocated to one or a plurality of subcarriers corresponding to the frequency band outside the subcarrier group i. Can be. In addition, when performing signal processing by dividing the subcarrier group i into a plurality of blocks on the receiving side, one or a plurality of subcarriers corresponding to the frequency band outside the subcarrier group i and the divided blocks It is possible not to assign a signal to one or a plurality of subcarriers corresponding to the outer frequency band. Further, it is possible not to assign a signal to one or a plurality of subcarriers corresponding to the center frequency band of the subcarrier group i or one or a plurality of subcarriers corresponding to the center frequency band of the divided block. it can.

  The 0 insertion circuit 13-i (i = 1 to k) inserts a frequency component of 0 into a subcarrier to which no data or signal is output by the modulation circuit 12-i, and outputs it to the inverse Fourier transform circuit 14-i. . FIG. 4 is a diagram showing the output of the 0 insertion circuit 13-i when no signal is assigned to the frequency band corresponding to the outside of the subcarrier group i. In the figure, 0 is inserted in the frequency band outside the transmission symbol of the subcarrier group i input from the modulation circuit 12-i. In addition, by specifying 0 for all subcarriers in advance and outputting a signal to the corresponding subcarrier by the modulation circuit 12-i, the same effect can be obtained without going through the 0 insertion circuit 13-i. You can also.

  The inverse Fourier transform circuit 14-i (i = 1 to k) performs the inverse Fourier transform on the data input from the 0 insertion circuit 13-i, thereby converting the transmission signal mapped in the frequency domain into a time domain signal. Convert and perform modulation to a multi-carrier signal. Thereby, in each subcarrier group i, the inverse Fourier transform is operated on the signal sequence in which 0 is inserted.

The GI (guard interval) insertion circuit 15-i (i = 1 to k) inserts a guard interval into the signal input from the inverse Fourier transform circuit 14-i.
FIG. 5 is a diagram illustrating a guard interval insertion method in the GI insertion circuit 15-i. The GI insertion circuit 15-i adds the same signal as a part of the latter half of the Fourier transform block, which is one symbol of the original multicarrier signal, to the first half of the Fourier transform block as a guard interval.

The smoothing circuit 16-i (i = 1 to k) performs smoothing by digital signal processing on the joint between the Fourier transform blocks of the signal input from the GI insertion circuit 15-i, and the D / A conversion circuit 17 Output to -i.
FIG. 6 is a diagram illustrating a smoothing process in the smoothing circuit 16-i. If the Fourier transform blocks are simply arranged continuously, the signal becomes discontinuous between the Fourier transform blocks. Therefore, the smoothing circuit 16-i performs processing so that the joints between the Fourier transform blocks change smoothly, and removes the presence of steep frequency components.

  The D / A conversion circuit 17-i (i = 1 to k) uses the clock by the common clock 21 to convert the digital signal input from the smoothing circuit 16-i to the other D / A conversion circuit 17-i. The analog signal synchronized with the signal is converted and output to the frequency conversion circuit 18-i. The frequency conversion circuit 18-i (i = 1 to k) uses the oscillation signal from the local oscillator 22 to change the frequency band of the analog signal of the subcarrier group i input from the D / A conversion circuit 17-i. The frequency is converted to the frequency band fi and output to the BPF 19-i. The center frequency of the frequency band fi matches the center frequency of the frequency band used by the subcarrier group i. That is, the frequency conversion circuit 18-i has the center frequency of the frequency band of the input analog signal as Frequency conversion is performed so that the center frequency of the frequency band of the subcarrier group i is obtained.

  FIG. 7 is a diagram illustrating frequency conversion in the frequency conversion circuit 18-1. In the figure, the frequency conversion circuit 18-1 frequency-converts the signal output from the D / A conversion circuit 17-i into the frequency band f1. The frequency bands f1 to fk are continuous so that a part of the frequency band fi (a part or all of the frequency band δfi described later) overlaps with the adjacent frequency bands f (i−1) and f (i + 1). It is a frequency band.

The BPF 19-i (i = 1 to k) extracts a signal of the frequency band Δfi corresponding to the frequency band of the subcarrier group i from the frequency-converted signal of the frequency band fi. Signals for adjacent frequency bands δfi are also extracted.
FIG. 8 is a diagram showing processing in the BPF 19-1. In the figure, the BPF 19-1 extracts the signal of the frequency band Δf1 from the signal of the frequency band f1, and the BPF 19-1 extracts the frequency band adjacent to the frequency band Δf1 when extracting the frequency band Δf1. The signal of δf1 is extracted at the same time. However, since the outer portion of the frequency band Δf1 corresponds to the frequency portion in which 0 insertion is performed by the 0 insertion circuit 13-1, the subcarrier can be used without using a steep BPF that is difficult to realize (δf1 is close to 0). It is possible to remove interference from outside the frequency band of group i and drop the operation clock of the inverse Fourier transform.

The combining circuit 20 combines the subcarrier groups i output from the BPFs 19-i (i = 1 to k), generates an output A, and outputs the output A.
FIG. 9 is a diagram illustrating an output A output from the synthesis circuit 20. As shown in the figure, the synthesis circuit 20 synthesizes the subcarrier groups 1 to k in the frequency bands f1 to fk output from the BPFs 19-i (i = 1 to k), respectively, and generates an electrical ultra-wideband multi An output A that is a carrier signal is generated.

The light intensity modulator 4 inputs the output A of the signal generation circuit 1 to the Mach-Zehnder modulator, thereby generating a DSB optical multicarrier signal centered on the optical carrier of the frequency fc emitted from the signal light source 3. .
FIG. 10 is a diagram illustrating a spectrum of an optical multicarrier signal output from the light intensity modulator 4. As shown in the figure, the optical multicarrier signal output from the optical intensity modulator 4 has sidebands corresponding to the frequency fi (i = 1 to k) in the bands on both sides centered on the optical carrier frequency fc. is made of. When the intensity modulator 4 is driven, if the bias point is set to half of the half-wave voltage (V), the optical carrier remains, and if the bias point is set to the NULL point, the optical carrier can be suppressed.

Thus, in DSB, the same multicarrier signal is generated in both bands around the frequency fc, but in order to increase the band utilization efficiency, an optical BPF (bandpass filter) 5 is used as shown in FIG. And the multicarrier signal output from the light intensity modulator 4 may be converted into SSB (single sideband) by the optical BPF 5.
FIG. 12 is a diagram illustrating a spectrum of a multicarrier signal output from the optical BPF 5. As shown in the figure, in the multicarrier signal output from the optical BPF 5, only one of the sidebands appearing in both bands centered on the optical carrier frequency fc in the optical multicarrier signal output from the optical intensity modulator 4 is used. Take out.
Although not shown in the figure, the output A can be converted to an SSB without using the optical BPF by using the output A as the Ich drive signal of the optical quadrature modulator and the Hilbert transform of the output A as the Qch drive signal.

  According to the above embodiment, compared with the prior art, it is possible to multiplex a wideband ODFM signal in the electrical frequency domain, and therefore, for a set of light sources and an optical modulator, modulation of an optical ODFM signal with a wide bandwidth and good frequency utilization efficiency. Is possible.

  Note that the 0 insertion circuit 13-i (i = 1 to k) inserts a frequency component of 0 in the corresponding frequency band by the modulation circuit 12-i, but the value is substantially 0, and is an inverse discrete Fourier transform. It is also possible to insert a frequency component having a value that does not affect the signal component at the time of conversion.

<Second Embodiment>
Next, a signal transmission apparatus according to the second embodiment of the present invention will be described. In the second embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  FIG. 13 is a block diagram showing a configuration of a signal transmission apparatus according to the second embodiment of the present invention. In the first embodiment, the signal A, which is a broadband electric multicarrier signal generated by the signal generation circuit 1, is used as a drive signal for the light intensity modulator 4. In this embodiment, the signal A is generated by the signal generation circuit 1a. The difference is that the output Ich signal and Qch signal of the output A are output to the optical quadrature modulator 6.

  FIG. 14 is a block diagram showing a configuration of the signal generation circuit 1a of the present embodiment. In the same figure, in the digital signal processing unit up to the smoothing circuit 16-i (i = 1 to k), the calculation is performed with the complex signal as in the configuration of the signal generation circuit 1 of the first embodiment shown in FIG. ing. Therefore, the D / A conversion circuits 17a-i (i = 1 to k) of the present embodiment output analog complex signals (Ich, Qch). As a result, the Ich signal and Qch signal of output A shown in FIG. 10 are output from the synthesis circuit 20a.

  FIG. 15 is a block diagram showing another configuration of the signal generation circuit 1a of the present embodiment. In the figure, the digital signal processing units up to GI insertion circuits 15-i (i = 1 to k) are the same as the configuration of the signal generation circuit 1 of the first embodiment shown in FIG. The smoothing circuits 16a-i (i = 1 to k) perform the same processing as in the first embodiment, but the output to the D / A conversion circuit is divided into Ich and Qch and is output. Qch is output to the D / A conversion circuit 17b-i, and Qch is output to the D / A conversion circuit 17c-i. Then, the D / A conversion circuit 17b-i, the frequency conversion circuit 18b-i, the BPF 19b-i, and the synthesis circuit 20b are the D / A conversion circuit 17c-i, the frequency conversion circuit 18c-i, the BPF 19c-i, the synthesis for the Ich. The circuit 20c performs the same processing on Qch as the D / A conversion circuit 17-i, frequency conversion circuit 18-i, BPF 19-i, and synthesis circuit 20 described in the first embodiment. In this way, by processing the subsequent circuits from the smoothing circuit 16a-i separately for Ich and Qch, the number of clocks of the D / A conversion circuit can be reduced.

  FIG. 16 is a diagram illustrating a configuration of the optical quadrature modulator 6. As shown in the figure, the optical quadrature modulator 6 arranges Mach-Zehnder type modulators in parallel, and inputs an Ich drive signal and a Qch drive signal output from the signal generation circuit 1a, respectively. Then, by applying a phase shift π / 2 to one branch to which the Qch signal is input, it is possible to modulate the light sin (Qch) and cos (Ich) waves.

  FIG. 17 is a diagram illustrating a spectrum of an optical multicarrier signal output from the optical quadrature modulator 6. By driving the optical quadrature modulator 6 with the output A Ich signal and Qch signal output from the signal generation circuit 1, the frequency fc of the light source is centered as shown in the spectrum transition shown in FIG. A broadband optical multicarrier signal can be generated. At this time, if the bias point of the optical quadrature modulator 6 is set to a NULL point, the optical carrier can be suppressed. In the case of this configuration, the band utilization efficiency is increased as compared with the configuration using the intensity modulator.

  In the above description, the optical multicarrier signal is generated and transmitted. However, the multicarrier signal may be transmitted wirelessly. In this case, a radio signal is generated in the D / A conversion circuit 17-i, or the output A from the signal generation circuit 1 is placed on the carrier wave of the radio signal.

The above-described inverse Fourier transform circuit 14-i and GI insertion circuit 15-i in FIGS. 2, 14, and 15 can have different numbers of inverse Fourier transform points and guard interval lengths in each subcarrier group. .
The common clock 21 and local oscillator 22 shown in FIGS. 2, 14, and 15 are the same for all subcarrier groups. However, the common clock 21 and local oscillator 22 are not common but are different for each subcarrier group. May be used.
2 and FIG. 14 and 18b-i and 18c-i of FIG. 15 perform all frequency conversion for each subcarrier group and then set all subcarriers set in advance. The transmission quality of all subcarriers can be made the same by adjusting the level to the common power target value and making the signal power of all subcarriers constant.

  According to the present embodiment, it is possible to realize a steep bandpass filter that is difficult to realize with only a conventional analog filter, and to remove interference from outside the band divided for each subcarrier group. By substituting each subcarrier group from which frequency information is removed by frequency conversion, real-time and high-quality broadband transmission using multicarriers can be realized. Also, since zero insertion, guard interval insertion, and smoothing processing are performed in parallel for each subcarrier group, it is possible to operate with a slow clock.

1 is a signal transmission device according to a first embodiment of the present invention. It is a block diagram which shows the structure of the signal generation circuit by the embodiment. It is a block diagram which shows the structure of the light intensity modulator by the embodiment. It is a figure which shows the output of the 0 insertion circuit by the embodiment. It is a figure which shows the output of the GI insertion circuit by the embodiment. It is a figure which shows the output of the smoothing circuit by the embodiment. It is a figure which shows the output of the frequency converter circuit by the same embodiment. It is a figure which shows the process of BPF by the embodiment. It is a figure which shows the output of the synthetic | combination circuit by the embodiment. It is a figure which shows the output from the light intensity modulator by the embodiment. It is a block diagram which shows the other structure of the signal transmitter by the same embodiment. It is a figure which shows the output from the optical BPF by the embodiment. It is a signal transmission apparatus in the 2nd Embodiment of this invention. It is a block diagram which shows the structure of the signal generation circuit by the embodiment. It is a block diagram which shows the other structure of the signal generation circuit by the embodiment. It is a block diagram which shows the structure of the optical orthogonal modulator by the embodiment. It is a figure which shows the output from the optical orthogonal modulator by the same embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1a ... Signal generation circuit 11 ... S / P conversion circuit (serial parallel conversion part)
12-1 to 12-k ... modulation circuit (input signal modulation section)
13-1 to 13-k ... 0 insertion circuit (zero insertion section)
14-1 to 14-k: Inverse Fourier transform circuit (inverse Fourier transform unit)
15-1 to 15-k ... GI insertion circuit (guard interval insertion unit)
16-1 to 16-k, 16a-1 to 16a-k ... smoothing circuit (smoothing unit)
17-1 to 17-k, 17a-1 to 17a-k, 17b-1 to 17b-k, 17c-1 to 17c-k ... D / A conversion circuit (digital / analog conversion unit)
18-1 to 18-k, 18b-1 to 18b-k, 18c-1 to 18c-k ... frequency conversion circuit (frequency conversion unit)
19-1 to 19-k, 19b-1 to 19b-k, 19c-1 to 19c-k ... BPF (band pass filter)
20, 20a, 20b, 20c ... synthesis circuit (synthesis unit)
21 ... Common clock 22 ... Local oscillator 3 ... Signal light source 4 ... Light intensity modulator 5 ... Optical BPF
6. Optical quadrature modulator

Claims (7)

A serial-parallel converter that converts an input signal into a plurality of parallel signals;
A plurality of processing units each corresponding to a subcarrier group of a multicarrier signal and generating a signal of a subcarrier group corresponding to the plurality of parallel signals;
A combining unit that generates a multicarrier signal by combining the signals of the subcarrier groups generated by the plurality of processing units;
A transmission unit for transmitting the multicarrier signal synthesized by the synthesis unit,
Each of the plurality of processing units is
An input signal modulator for modulating each parallel signal to a subcarrier;
A zero insertion unit for inserting a frequency component of 0 into a frequency outside the frequency band of the signal modulated by the input signal modulation unit;
An inverse Fourier transform unit that performs an inverse Fourier transform on the signal in which the zero frequency component is inserted by the zero insertion unit;
A digital-analog converter that converts the signal that has been subjected to the inverse Fourier transform by the inverse Fourier transform unit into an analog signal that is synchronized with another processing unit;
Frequency converter that converts the signal converted into an analog signal by the digital analog converter so that the center frequency of the frequency band of the signal is the center frequency of the frequency band of the subcarrier group corresponding to the processing unit When,
A band-pass filter that extracts a signal of a frequency band used by a subcarrier group corresponding to the processing unit from the signal frequency-converted by the frequency conversion unit;
The combining unit combines the signals extracted by the bandpass filter to generate the multicarrier signal;
A signal transmission apparatus characterized by that. Each of the plurality of processing units is
A guard interval insertion unit that inserts a guard interval into the signal that has been inverse Fourier transformed by the inverse Fourier transform unit;
The signal transmission device according to claim 1. Each of the plurality of processing units is
A smoothing unit that performs a smoothing process at a joint between Fourier transform blocks of the signal in which the guard interval is inserted by the guard interval insertion unit;
The signal transmission apparatus according to claim 2.   The signal transmission device according to claim 1, wherein the transmission unit transmits a multicarrier signal using an optical signal.   The signal transmission device according to claim 4, wherein the transmission unit includes an optical intensity modulator that converts the electrical multicarrier signal synthesized by the synthesis unit into an optical signal.   5. The signal according to claim 4, wherein the transmission unit includes an optical quadrature modulator that generates an optical signal using the I-component and Q-component signals of the multicarrier signal combined by the combining unit as drive signals. Transmitter device. In a signal transmission device that transmits a multicarrier signal,
A serial-parallel conversion process in which the serial-parallel converter converts the input signal into a plurality of parallel signals;
A plurality of processing units corresponding to each of the subcarrier groups of the multicarrier signal generates a signal of the subcarrier group corresponding to itself for the plurality of parallel signals, and
A combining unit that combines the signals of the subcarrier groups generated by the plurality of processing units in the signal processing step to generate a wideband multicarrier signal;
A transmission unit having a transmission process of transmitting the multicarrier signal combined in the combining process;
The processing steps by each of the plurality of processing units are:
An input signal modulation unit that modulates each parallel signal into subcarriers;
A zero insertion process in which a zero insertion unit inserts a frequency component of 0 into a frequency outside the frequency band of the signal modulated in the input signal modulation process;
An inverse Fourier transform process in which an inverse Fourier transform unit performs an inverse Fourier transform on a signal in which a zero frequency component is inserted in the zero insertion process;
A digital-analog conversion process in which the digital-analog conversion unit converts the signal subjected to the inverse Fourier transform in the inverse Fourier transform process into an analog signal synchronized with another processing unit;
The frequency conversion unit converts the signal converted into the analog signal in the digital-analog conversion process so that the center frequency of the frequency band of the signal is the center frequency of the frequency band of the subcarrier group corresponding to the processing unit. The frequency change process to convert,
A bandpass filter having an extraction process of extracting a signal in a frequency band used by a subcarrier group corresponding to the processing unit from the signal frequency-converted in the frequency conversion process;
In the synthesis process, the synthesis unit synthesizes the signals extracted in the extraction process to generate the multicarrier signal.
A signal transmission method characterized by the above.

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