JP5491974B2 - Optical access system and receiving apparatus - Google Patents

Description

  The present invention relates to a receiving apparatus for performing data reception economically and with high accuracy in an optical access system that performs data transmission between a transmitting apparatus and a receiving apparatus.

  Conventionally, a baseband transmission system in which binary digital signal information of 0 and 1 is reflected in the light intensity is used. In recent years, for the purpose of further improving transmission performance, binary digital signal information of 0 and 1 is reflected in the intensity, phase and frequency of light, a 4-value PSK (Phase Shift Keying), a 16-value QAM (Quadrature Amplitude). Multi-level modulation schemes such as Modulation and OFDM (Orthogonal Frequency Division Multiplexing) have been verified.

  Non-Patent Document 1 and Non-Patent Document 2 disclose a conventional optical access system.

  FIG. 1 is a diagram illustrating a conventional optical access system. The transmission device 1 transmits data to a plurality of reception devices including the reception device 2 via the optical transmission path 3 and the optical splitter 4. In the transmission apparatus 1, the band signal generator 101 modulates a data signal into a band signal by a predetermined method, and the optical transmitter 102 converts the band signal from an electric signal to an optical signal and transmits the band signal. FIG. 1B shows a band signal that is an electrical signal output from the band signal generator 101, and FIG. 1C shows a band signal that is an optical signal output from the optical transmitter 102. In the receiver 2, the optical receiver 201 receives a band signal and converts it from an optical signal to an electrical signal, and an AD (Analog / Digital) conversion circuit 202 converts the band signal from an analog signal to a digital signal for digital signal processing. The circuit 203 demodulates the band signal into a data signal by a predetermined method, and compensates for signal degradation caused by the transmission apparatus 1 and the optical transmission line 3 as necessary. FIG. 1 (d) shows a band signal that is an electrical signal output from the light receiver 201.

  FIG. 2 is a diagram illustrating a conventional optical transmitter. In FIG. 2A, the band signal is input to the laser light source 103 and the modulated light is output from the laser light source 103 by the direct modulation method. In FIG. 2B, the band signal and the continuous wave light of the laser light source 103 are input to the optical modulator 104 and the modulated light is output from the optical modulator 104 by an external modulation method.

  A time division multiplexing method is used in which a plurality of band signals are time-division multiplexed using the broadband characteristics of the optical transmission line 3. Non-Patent Document 3 discloses a prior art time division multiplexing receiver shown in FIG. 5 that receives an optical signal, converts the optical signal into a radio signal, and transmits the radio signal. Non-Patent Document 4 discloses a time division multiplexing receiver of the prior art shown in FIG. 8 that uses coherent detection without using a direct detection method.

  FIG. 3 is a diagram illustrating a conventional time division multiplexing transmitter. As shown in FIG. 3A, the transmission apparatus 1A includes band signal generators 101A-1, 101A-2,..., 101A-N, a time division multiplexing switch 105A, and an optical transmitter 102A. The The band signal generators 101A-1, 101A-2,..., 101A-N each modulate a data signal into a band signal by a predetermined method. The time division multiplexing switch 105A performs time division multiplexing of a plurality of band signals. FIG. 3B shows a plurality of band signals input to the time division multiplexing switch 105A, and FIG. 3C shows a time division multiplexed signal output from the time division multiplexing switch 105A. The optical transmitter 102A converts the time division multiplexed signal from an electrical signal to an optical signal and transmits it. FIG. 3D shows a time division multiplexed signal transmitted from the optical transmitter 102A.

  FIG. 4 is a diagram showing a first conventional time division multiplexing receiver. As shown in FIG. 4A, the receiving device 2A includes a light receiver 201A, a time division separation switch 204A, an AD conversion circuit 202A, and a digital signal processing circuit 203A. The light receiver 201A receives the time division multiplexed signal and converts the optical signal into an electrical signal. FIG. 4B shows a time division multiplexed signal received by the optical receiver 201A. The time division separation switch 204A extracts a predetermined band signal from the time division multiplexed signal. FIG. 4C shows a time division multiplexed signal inputted to the time division separation switch 204A, and FIG. 4D shows a predetermined band signal outputted from the time division separation switch 204A. The AD conversion circuit 202A converts a predetermined band signal from an analog signal to a digital signal. The digital signal processing circuit 203A demodulates a predetermined band signal into a predetermined data signal by a predetermined method. As described above, the receiving device 2A performs time division separation in the electrical domain after converting the optical signal into the electrical signal.

  FIG. 5 is a diagram showing a second conventional time division multiplexing receiver. As shown in FIG. 5A, the receiving device 2B includes a light receiver 201B, a time division separation switch 204B, a bandpass filter 205B, a radio signal front end 206B, and an antenna 207B. The light receiver 201B receives the time division multiplexed signal and converts it from an optical signal to an electrical signal. FIG. 5B shows a time division multiplexed signal received by the optical receiver 201B. The time division separation switch 204B extracts a predetermined band signal from the time division multiplexed signal. FIG. 5C shows a time division multiplexed signal input to the time division separation switch 204B, and FIG. 5D shows a predetermined band signal output from the time division separation switch 204B. The band pass filter 205B extracts a signal having a predetermined frequency. The radio signal front end 206B amplifies a signal having a predetermined frequency. The antenna 207B transmits a signal having a predetermined frequency. In this way, the receiving device 2B performs time division separation in the electrical domain after converting the optical signal into an electrical signal.

  FIG. 6 is a diagram illustrating processing of the second conventional time division multiplexing receiver. FIG. 6A shows the frequency distribution of the band signal before sampling the original band signal. FIG. 6B shows the frequency distribution of the band signal after sampling the original band signal. In FIG. 6B, unlike FIG. 6A, a signal having a copy of the information of the original band signal is distributed in the frequency space separated from the frequency of the original band signal by an integer multiple of the sampling frequency. Here, in the transmitting apparatus 1A in FIG. 3 and the receiving apparatus 2B in FIG. 5, by setting the sampling pulse width to be sufficiently narrow, a signal having a copy of the information of the original band signal is a radio frequency band. It is also distributed in the frequency band. Therefore, the bandpass filter 205B can extract a signal with a predetermined radio frequency, and the antenna 207B can transmit a signal with a predetermined radio frequency.

  FIG. 7 is a diagram illustrating a third conventional time division multiplexing receiver. As illustrated in FIG. 7A, the receiving device 2C includes an optical switch 208C, a light receiver 201C, an AD conversion circuit 202C, and a digital signal processing circuit 203C. The optical switch 208C receives the time division multiplexed signal and extracts a predetermined band signal from the time division multiplexed signal. FIG. 7B shows a time division multiplexed signal input to the optical switch 208C, and FIG. 7C shows a predetermined band signal output from the optical switch 208C. The light receiver 201C converts a predetermined band signal from an optical signal to an electrical signal. FIG. 7D shows a predetermined band signal output from the light receiver 201C. The AD conversion circuit 202C converts a predetermined band signal from an analog signal to a digital signal. The digital signal processing circuit 203C demodulates a predetermined band signal into a predetermined data signal by a predetermined method. Thus, the receiving device 2C performs time division separation in the optical domain.

  FIG. 8 is a diagram showing a fourth conventional time division multiplexing receiver. The receiving device 2D includes an optical multiplexer 209D, a light receiver 201D, an AD conversion circuit 202D, a digital signal processing circuit 203D, a frequency stabilization circuit 210D, a pulse light source 211D, and a polarization adjuster 212D. The frequency stabilizing circuit 210D stabilizes the frequency of the pulsed light signal output from the pulsed light source 211D to the sampling frequency, and the difference between the oscillation wavelength of the pulsed light source 211D and the wavelength of the received time-division multiplexed signal is a predetermined value. Thus, the oscillation wavelength of the pulse light source 211D is stabilized. The polarization adjuster 212D adjusts the polarization state of the pulse optical signal output from the pulse light source 211D. The optical multiplexer 209D combines the time division multiplexed signal from the transmission apparatus 1A and the pulsed optical signal from the polarization adjuster 212D. The light receiver 201D converts the combined signal from an optical signal to an electrical signal. The AD conversion circuit 202D converts the combined signal from an analog signal to a digital signal. The digital signal processing circuit 203D demodulates the combined signal into a data signal by a predetermined method. The combined signal includes a predetermined band signal as a beat signal. Thus, the receiving device 2D performs time division separation in the optical domain.

  When the receiving device 2 receives a wideband signal of about several GHz, the light receiver 201, the AD conversion circuit 202, the digital signal processing circuit 203, the bandpass filter 205, and the radio signal front end 206 operate at a high speed of about several GHz. As required. In particular, since the AD converter circuit 202 makes it difficult to operate at a high speed of several GHz, the configuration of the receiving device 2 is complicated, and the price of the receiving device 2 is increased. Therefore, a plurality of AD conversion circuits 202 process wideband signals of about several GHz in a distributed and parallel manner.

  FIG. 9 is a diagram illustrating a first wideband signal receiving apparatus according to the prior art. As shown in FIG. 9A, the receiver 2E includes a light receiver 201E, a time division separation switch 204E, AD conversion circuits 202E-1, 202E-2,..., 202E-N, and a digital signal processing circuit. 203E. The processing of the light receiver 201E is the same as the processing of the light receiver 201A in FIG. FIG. 9B shows a broadband signal received by the optical receiver 201E. The time division separation switch 204E outputs the wideband signals sampled at the first, second,..., Nth timings to the AD conversion circuits 202E-1, 202E-2,. To do. FIG. 9C shows a broadband signal before sampling input to the time division separation switch 204E, and FIG. 9D shows a broadband signal after sampling output from the time division separation switch 204E. The AD conversion circuits 202E-1, 202E-2,..., 202E-N convert the wideband signals sampled at the first, second,. . The digital signal processing circuit 203E combines the wideband signals sampled at the first, second,..., Nth timings and demodulates the wideband signal into a data signal by a predetermined method. As described above, the receiving device 2E performs time-division separation in the electrical domain and performs distributed / parallel processing after converting the optical signal into the electrical signal.

  FIG. 10 is a diagram illustrating a second wideband signal receiving apparatus of the related art. Receiving device 2F includes optical switch 208F, light receivers 201F-1, 201F-2,..., 201F-N, AD conversion circuits 202F-1, 202F-2,. 203F. The optical switch 208F receives the broadband signal, and receives the broadband signals sampled at the first, second,..., Nth timings, respectively, on the optical receivers 201F-1, 201F-2,. Output to. Receiving devices 201F-1, 201F-2,..., 201F-N convert the broadband signals sampled at the first, second,. . The AD conversion circuits 202F-1, 202F-2,..., 202F-N convert the wideband signals sampled at the first, second,. To do. The digital signal processing circuit 203F combines the wideband signals sampled at the first, second,..., Nth timings, and demodulates the wideband signal into a data signal by a predetermined method. Thus, the receiving device 2F performs time division separation in the optical domain and performs distributed / parallel processing in the electrical domain.

  FIG. 11 is a diagram illustrating a third wideband signal receiving apparatus according to the prior art. Receiving device 2G includes optical splitter 213G, optical multiplexers 209G-1, 209G-2,..., 209G-N, light receivers 201G-1, 201G-2,. 202G-1, 202G-N, digital signal processing circuit 203G, frequency stabilization circuit 210G, pulse light source 211G, polarization controller 212G, optical branching device 214G, and optical delay device 215G-2, ... composed of 215G-N. The processing of the frequency stabilization circuit 210G, the pulse light source 211G, and the polarization adjuster 212G is the same as the processing of the frequency stabilization circuit 210D, the pulse light source 211D, and the polarization adjuster 212D of FIG. The optical splitter 214G receives an optical pulse signal from the polarization adjuster 212G and branches it. The optical delay units 215G-2,..., 215G-N receive the branched optical pulse signal from the optical branching unit 214G, and delay the branched optical pulse signal by the respective delay times. The optical branching device 213G receives a broadband signal from the transmission device 1A and branches it. The optical multiplexer 209G-1 combines the branched broadband signal from the optical branching device 213G and the optical pulse signal after branching from the optical branching device 214G, and combines the optical multiplexers 209G-2,. N multiplexes the branched broadband signal from the optical branching unit 213G and the optical pulse signal after branching / delaying from the optical delay units 215G-2,... 215G-N, respectively. The light receivers 201G-1, 201G-2,..., 201G-N convert the combined signals from the optical combiners 209G-1, 209G-2,. Convert. The AD conversion circuits 202G-1, 202G-2,..., 202G-N convert the combined signals from the optical receivers 201G-1, 201G-2,. Convert. The digital signal processing circuit 203G combines the combined signals from the AD conversion circuits 202G-1, 202G-2, ..., 202G-N, and demodulates the further combined signal into a data signal by a predetermined method. To do. Thus, the receiving device 2G performs time division separation in the optical domain and performs distributed / parallel processing in the electrical domain.

Dayou Qian, Neda Cvjetic, Junqi Hu and Ting Wang, “108 Gb / s OFDMA-PON with polarization multiplexing and direction detection”, IEEE J. Lighttw. Technol. , Vol. 28, no. 4, pp. 484-493, Feb. 2010. Sang-Yuep Kim, Naoya Sakurai, Hideaki Kimura and Kiyomi Kumozaki, "10-Gbit / s next-generation coherent QPSK-PON with reduced bandwidth requirements employing linear digital equalization with adaptive algorithm", OFC 2009, OMN6, Mar. 2009. Hiroshi Harada, Katsutoshi Tsukamoto, Shozo Komaki, Norihiko Morinaga, “Millimeter-Wave Radio Signal Optical Fiber Transmission System Using Optical TDM”, IEICE Transactions CI, Vol. J77-CI, No. 1, pp. 649-658. , November 1994. Cho Zhang, Koji Igarashi, Kazuhiro Kato, Kazuo Kikuchi, “Demodulation of optical QPSK signal by digital coherent receiver with time demultiplexing function”, 2008 IEICE General Conference, B-10-98, March 2008 . Eszter Udvary and Timber Berceli, “Semiconductor Optical Amplifier for Detection Function in Radio Over Fiber System”, Journal of Lightweight. 26, no. 15, pp. 2563-2570, August 1, 2008.

  The receiving apparatuses 2A and 2B illustrated in FIG. 4 and FIG. 5 perform time division separation in the electrical domain after converting the optical signal into an electrical signal. The receiving apparatus 2E illustrated in FIG. 9 performs time-division separation in the electrical domain and performs distributed / parallel processing after converting the optical signal into an electrical signal. Therefore, the receiving devices 2A, 2B, and 2E are not suitable for receiving a band signal of about several GHz.

  The receiving apparatuses 2C and 2D illustrated in FIGS. 7 and 8 perform time division separation in the optical domain. The receiving apparatuses 2F and 2G illustrated in FIGS. 10 and 11 perform time division separation in the optical domain and perform distributed / parallel processing in the electrical domain. Therefore, the receiving devices 2C, 2D, 2F, and 2G are suitable for receiving a band signal of about several GHz. However, in the receiving apparatuses 2C and 2F, if the optical switch 208 generates an optical loss and an optical amplifier is arranged to compensate for the optical loss, the apparatus configuration becomes complicated. In the receiving apparatuses 2D and 2G, the frequency stabilization circuit 210 and the polarization adjuster 212 are necessary, and the apparatus configuration is complicated. In particular, in the optical access system shown in FIG. 1, the transmitting device 1 is a housing station, and the receiving device 2 is a subscriber premises device. If the receiving apparatuses 2C, 2D, 2F, and 2G are applied to the subscriber premises apparatus, the optical access system becomes expensive. Thus, there has been no specific study on an effective method for time-division separation of the optical region.

  Accordingly, in order to solve the above-described problems, the present invention provides an optical access system that performs data transmission between a transmission device and a reception device, and performs data reception by time-division separation of an optical region with high accuracy. An object is to provide a receiving apparatus.

  In order to achieve the above object, the optical semiconductor amplifier samples and amplifies an optical signal such as a time-division multiplexed optical signal or a broadband signal at a predetermined timing. A signal generator outputs a signal having a current larger than a threshold current of the semiconductor optical amplifier to the semiconductor optical amplifier at a predetermined timing, and a signal having a current equal to or lower than the threshold current at a time other than the predetermined timing. Output to.

  Specifically, the present invention is an optical access system comprising: a transmitter that transmits time-division multiplexed optical signals; and a receiver that receives the time-division multiplexed optical signals, The receiving device receives the time division multiplexed optical signal, samples and amplifies the semiconductor optical amplifier at a predetermined timing, and receives a signal having a current larger than a threshold current of the semiconductor optical amplifier at the predetermined timing. A signal generator that outputs to the semiconductor optical amplifier and outputs a signal having a current equal to or lower than the threshold current to the semiconductor optical amplifier at a time other than the predetermined timing; and an optical signal sampled and amplified by the semiconductor optical amplifier An optical access system comprising: a light receiver that converts the light into an electrical signal.

  According to this configuration, it is possible to provide an optical access system including a receiving device that time-division-separates time-division multiplexed optical signals in the optical domain with high accuracy.

  The present invention is also an optical access system comprising a transmitting device that transmits an optical signal and a receiving device that receives the optical signal, wherein the receiving device branches the optical signal into a plurality of branched optical signals. An optical branching device, a plurality of semiconductor optical amplifiers that input each branched optical signal, sample and amplify at each predetermined timing, and a signal having a current larger than the threshold current of each semiconductor optical amplifier at each predetermined timing. A plurality of signal generators that output to a semiconductor optical amplifier and output a signal having a current equal to or less than each threshold current to each semiconductor optical amplifier at a time other than each predetermined timing, and are sampled and amplified by each semiconductor optical amplifier A plurality of optical receivers that convert each branched optical signal into each electrical signal; and an electrical circuit that performs signal processing on each electrical signal and multiplexes the electrical signals that have undergone signal processing. Which is an optical access system that.

  According to this configuration, an optical access system including a receiving device that optically and optically divides an optical signal such as a wideband signal in an optical domain and distributes and processes the optical signal such as a broadband signal in an electrical domain. Can be provided.

  According to the present invention, the signal generator controls at least one of an amplitude and a bias of a current signal output to the semiconductor optical amplifier, and controls a sampling pulse width and an amplification gain of the semiconductor optical amplifier. An optical access system characterized by the above.

  According to this configuration, it is possible to provide an optical access system including a receiving apparatus that can flexibly cope with fluctuations in reception intensity of an optical signal such as a time-division multiplexed optical signal or a broadband signal.

  In the present invention, the receiving device monitors an electrical signal output from the light receiver, and determines whether the electrical signal is a baseband signal or a modulated signal obtained by modulating the baseband signal. Based on the determination of the control circuit, when the electrical signal is a baseband signal, the connection between the signal generator and the semiconductor optical amplifier is cut off, and the baseband signal is modulated with the electrical signal. In the case of a modulated signal, the optical access system further comprises a switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other.

  According to this configuration, the optical device includes a receiving device that flexibly changes the processing content between the processing content when the baseband signal is received and the processing content when the modulation signal obtained by modulating the baseband signal is received. An access system can be provided.

  The present invention also provides a semiconductor optical amplifier that inputs a time division multiplexed optical signal, samples and amplifies the signal at a predetermined timing, and a signal having a current larger than a threshold current of the semiconductor optical amplifier at the predetermined timing. A signal generator that outputs a signal having a current equal to or lower than the threshold current to the semiconductor optical amplifier, and outputs the signal to the semiconductor optical amplifier at a time other than the predetermined timing; and light sampled and amplified by the semiconductor optical amplifier And a light receiver for converting a signal into an electric signal.

  According to this configuration, it is possible to provide a receiver that time-division-separates time-division multiplexed optical signals in the optical domain with high accuracy.

  Further, the present invention provides an optical branching device that branches an optical signal into a plurality of branched optical signals, a plurality of semiconductor optical amplifiers that input each branched optical signal, and sample and amplify at each predetermined timing, and A signal having a current larger than a threshold current is output to each semiconductor optical amplifier at each predetermined timing, and a signal having a current equal to or lower than each threshold current is output to each semiconductor optical amplifier at a time other than each predetermined timing. Signal generators, a plurality of optical receivers that convert each of the branched optical signals sampled and amplified by each semiconductor optical amplifier into electric signals, and electric signals that have been subjected to signal processing and signal processing. And an electric circuit for combining the two.

  According to this configuration, it is possible to provide a receiving apparatus that performs time-division separation of an optical signal such as a broadband signal in the optical domain economically and with high accuracy, and performs dispersion / parallel processing of the optical signal such as a broadband signal in the electrical domain. .

  According to the present invention, the signal generator controls at least one of an amplitude and a bias of a current signal output to the semiconductor optical amplifier, and controls a sampling pulse width and an amplification gain of the semiconductor optical amplifier. This is a receiving device.

  According to this configuration, it is possible to provide a receiving apparatus that can flexibly cope with fluctuations in the reception intensity of an optical signal such as a time-division multiplexed optical signal or a broadband signal.

  The present invention also provides a control circuit for monitoring an electrical signal output from the light receiver and determining whether the electrical signal is a baseband signal or a modulated signal obtained by modulating a baseband signal, and the control circuit When the electrical signal is a baseband signal, the mutual connection between the signal generator and the semiconductor optical amplifier is cut off, and when the electrical signal is a modulated signal obtained by modulating the baseband signal. And a switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other.

  According to this configuration, there is provided a receiving apparatus that flexibly changes processing contents between processing contents when receiving a baseband signal and processing contents when receiving a modulated signal obtained by modulating the baseband signal. be able to.

  INDUSTRIAL APPLICABILITY The present invention can provide a receiving apparatus for receiving data by time division separation of an optical region in an optical access system that performs data transmission between a transmitting apparatus and a receiving apparatus.

It is a figure which shows the optical access system of a prior art. It is a figure which shows the optical transmitter of a prior art. It is a figure which shows the time division multiplexing transmission apparatus of a prior art. It is a figure which shows the 1st time division multiplexing receiving apparatus of a prior art. It is a figure which shows the 2nd time division multiplexing receiving apparatus of a prior art. It is a figure which shows the process of the 2nd time division multiplexing receiving apparatus of a prior art. It is a figure which shows the 3rd time division multiplexing receiving apparatus of a prior art. It is a figure which shows the 4th time division multiplexing receiving apparatus of a prior art. It is a figure which shows the 1st wideband signal receiver of a prior art. It is a figure which shows the 2nd wideband signal receiver of a prior art. It is a figure which shows the 3rd wideband signal receiver of a prior art. 1 is a diagram illustrating a time division multiplexing receiver according to Embodiment 1. FIG. It is a figure which shows the process of the semiconductor optical amplifier and signal generator of Embodiment 1. FIG. It is a figure which shows the process of the semiconductor optical amplifier and signal generator of Embodiment 1. FIG. It is a figure which shows the process of the semiconductor optical amplifier and signal generator of Embodiment 1. FIG. It is a figure which shows the process of the semiconductor optical amplifier and signal generator of Embodiment 1. FIG. FIG. 3 is a diagram illustrating a timing adjustment method according to the first embodiment. It is a figure which shows the sampling experiment result of Embodiment 1. FIG. 6 is a diagram illustrating a time division multiplexing receiver according to Embodiment 2. FIG. It is a figure which shows the wideband signal receiver of Embodiment 3. FIG. 10 is a diagram illustrating a time division multiplexing receiving apparatus according to a fourth embodiment. FIG. 10 is a diagram illustrating a time division multiplexing receiver according to a fifth embodiment.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are examples of the present invention, and the present invention is not limited to the following embodiments. In the present specification and drawings, the same reference numerals denote the same components.

(Embodiment 1)
FIG. 12 is a diagram illustrating the time division multiplexing receiver according to the first embodiment. The receiving device 2H includes a semiconductor optical amplifier 216H, a light receiver 201H, an AD conversion circuit 202H, a digital signal processing circuit 203H, a signal generator 217H, a timing adjustment circuit 218H, an amplitude adjustment circuit 219H, and a bias adjustment circuit 220H.

  The semiconductor optical amplifier 216H receives the time division multiplexed signal, samples and amplifies the time division multiplexed signal at a predetermined timing, and extracts a predetermined band signal. The light receiver 201H converts a predetermined band signal from an optical signal to an electrical signal. The AD conversion circuit 202H converts a predetermined band signal from an analog signal to a digital signal. The digital signal processing circuit 203H demodulates a predetermined band signal into a predetermined data signal by a predetermined method.

  The signal generator 217H outputs a signal having a current larger than the threshold current of the semiconductor optical amplifier 216H to the semiconductor optical amplifier 216H at a predetermined timing, and outputs a signal having a current equal to or lower than the threshold current at a time other than the predetermined timing. Output to the semiconductor optical amplifier 216H. The timing adjustment circuit 218H adjusts the timing of the current signal from the signal generator 217H. The amplitude adjustment circuit 219H adjusts the amplitude of the current signal from the signal generator 217H. The bias adjustment circuit 220H adjusts the bias of the current signal from the signal generator 217H.

  FIGS. 13 to 16 are diagrams illustrating processing of the semiconductor optical amplifier and the signal generator according to the first embodiment. The signal intensity of the current signal from the signal generator 217H is larger than the threshold current of the semiconductor optical amplifier 216H at a predetermined timing, and is lower than the threshold current of the semiconductor optical amplifier 216H at a time other than the predetermined timing. Therefore, the gain of the semiconductor optical amplifier 216H becomes a finite value at a predetermined timing, but becomes almost zero at a time other than the predetermined timing. Of the signals received by the semiconductor optical amplifier 216H, signals at a predetermined timing are amplified and pass, but signals at times other than the predetermined timing hardly pass.

  In FIG. 13, the received signal at the semiconductor optical amplifier 216H is a received signal having a constant temporal strength, and the current signal from the signal generator 217H is a rectangular wave signal. FIG. 13A shows the change over time of the signal strength for the received signal at the semiconductor optical amplifier 216H. FIG. 13B shows the current-gain characteristic of the semiconductor optical amplifier 216H and the time change of the signal current for the current signal from the signal generator 217H. FIG. 13C shows the change over time of the signal strength for the output signal from the semiconductor optical amplifier 216H.

  The amplitude adjustment circuit 219H can adjust the amplification gain of the semiconductor optical amplifier 216H by adjusting the amplitude of the current signal from the signal generator 217H. The bias adjustment circuit 220H can adjust the amplification gain of the semiconductor optical amplifier 216H by adjusting the bias of the current signal from the signal generator 217H. It is sufficient that at least one of the amplitude adjustment circuit 219H and the bias adjustment circuit 220H is operating.

  In FIG. 14, the received signal at the semiconductor optical amplifier 216H is a received signal having a constant intensity in time, and the current signal from the signal generator 217H is a sine wave signal. FIG. 14A shows the change over time of the signal strength for the received signal at the semiconductor optical amplifier 216H. FIG. 14B shows the current-gain characteristic of the semiconductor optical amplifier 216H and the time change of the signal current for the current signal from the signal generator 217H. FIG. 14C shows a time change of the signal intensity for the output signal from the semiconductor optical amplifier 216H.

  The amplitude adjustment circuit 219H can adjust the sampling pulse width and amplification gain of the semiconductor optical amplifier 216H by adjusting the amplitude of the current signal from the signal generator 217H. The bias adjustment circuit 220H can adjust the sampling pulse width and amplification gain of the semiconductor optical amplifier 216H by adjusting the bias of the current signal from the signal generator 217H. It is sufficient that at least one of the amplitude adjustment circuit 219H and the bias adjustment circuit 220H is operating. In FIG. 14, since the sine wave signal is not a wideband signal, it is sufficient for the receiving apparatus 2H to include simple hardware.

  In FIG. 15, the received signal at the semiconductor optical amplifier 216H is a time-division multiplexed signal having a high intensity, and the current signal from the signal generator 217H is a sine wave signal. FIG. 15A shows the change over time of the signal strength of the received signal at the semiconductor optical amplifier 216H. FIG. 15B shows the current-gain characteristic of the semiconductor optical amplifier 216H and the time change of the signal current for the current signal from the signal generator 217H. FIG. 15C shows the change over time of the signal strength for the output signal from the semiconductor optical amplifier 216H.

  The signal generator 217H outputs a current signal larger than the threshold current of the semiconductor optical amplifier 216H at a predetermined timing in order to extract a predetermined band signal. Since the received signal at the semiconductor optical amplifier 216H is a time-division multiplexed signal having a high intensity, the amplitude and bias of the current signal from the signal generator 217H may be small.

  In FIG. 16, the received signal at the semiconductor optical amplifier 216H is a time-division multiplexed signal with a low intensity, and the current signal from the signal generator 217H is a sine wave signal. FIG. 16A shows the change over time of the signal strength of the received signal at the semiconductor optical amplifier 216H. FIG. 16B shows the current-gain characteristic of the semiconductor optical amplifier 216H and the time change of the signal current for the current signal from the signal generator 217H. FIG. 16C shows the change over time of the signal strength for the output signal from the semiconductor optical amplifier 216H.

  The signal generator 217H outputs a current signal larger than the threshold current of the semiconductor optical amplifier 216H at a predetermined timing in order to extract a predetermined band signal. Since the received signal at the semiconductor optical amplifier 216H is a time-division multiplexed signal with a low intensity, it is desirable that the amplitude and bias of the current signal from the signal generator 217H be large.

  As described with reference to FIGS. 15 and 16, in order to control the amplitude and bias of the current signal from the signal generator 217H, the output current of the light receiver 201H may be monitored. The receiving device 2H can flexibly cope with fluctuations in the reception intensity of the time division multiplexed signal.

  FIG. 17 is a diagram illustrating a timing adjustment method according to the first embodiment. In the transmitting apparatus 1A, the time division multiplexing switch 105A performs time division multiplexing of a plurality of band signals and synchronization acquisition signals. The synchronization acquisition signal is, for example, an alternating signal. In the receiving device 2H, the timing adjustment circuit 218H adjusts the timing of the current signal from the signal generator 217H so that the synchronization acquisition signal can be extracted. The semiconductor optical amplifier 216H can extract a predetermined band signal by sampling and amplifying the time division multiplexed signal at a timing separated from the synchronization acquisition signal by a predetermined time.

  FIG. 18 is a diagram illustrating a sampling experiment result of the first embodiment. FIG. 18A shows the measurement result of the optical signal waveform when an optical signal greatly modulated by a 200 MHz sine wave is input to a semiconductor optical amplifier operated by a 1 GHz sine wave. FIG. 18B shows the measurement result of the optical signal waveform when an optical signal modulated small by a 200 MHz sine wave is input to a semiconductor optical amplifier operated by a 1 GHz sine wave. In FIGS. 18A and 18B, sampling is performed with high accuracy when the sampling width is 110 to 120 ps. By adjusting the operating conditions of the semiconductor optical amplifier, sampling was performed with high accuracy even when the sampling width was 70 to 80 ps.

  As described above, the semiconductor optical amplifier samples and amplifies the time division multiplexed signal at a predetermined timing, and the signal generator applies a signal having a current larger than the threshold current of the semiconductor optical amplifier to a predetermined value. A signal having a current equal to or lower than the threshold current is output to the semiconductor optical amplifier at a timing, and a signal having a current lower than the threshold current is output to the semiconductor optical amplifier at a time other than a predetermined timing. Since the semiconductor optical amplifier can be integrated with a light receiver and is excellent in mass productivity, the receiving apparatus can receive data by time division separation of the optical region economically and with high accuracy.

  Here, the semiconductor optical amplifier can also reduce the polarization dependence. At this time, it is possible to solve the problem of polarization dependency that occurs when coherent detection is used. Furthermore, the semiconductor optical amplifier can have an amplification wavelength band of 100 nm or more by using a quantum dot structure. At this time, it can be operated in a very wide wavelength band.

(Embodiment 2)
FIG. 19 is a diagram illustrating a time division multiplexing receiver according to the second embodiment. The receiving device 2J includes a semiconductor optical amplifier 216J, a light receiver 201J, a bandpass filter 205J, a radio signal front end 206J, an antenna 207J, a signal generator 217J, a timing adjustment circuit 218J, an amplitude adjustment circuit 219J, and a bias adjustment circuit 220J. The

  The processes of the semiconductor optical amplifier 216J, the light receiver 201J, the signal generator 217J, the timing adjustment circuit 218J, the amplitude adjustment circuit 219J, and the bias adjustment circuit 220J are the same as those of the semiconductor optical amplifier 216H, the light receiver 201H, the signal generator 217H in FIG. The processing is the same as that of the timing adjustment circuit 218H, the amplitude adjustment circuit 219H, and the bias adjustment circuit 220H. The processing of the band pass filter 205J and the radio signal front end 206J is the same as the processing of the band pass filter 205B and the radio signal front end 206B of FIG. The same effect as that of the first embodiment can be obtained, and a radio signal can be output.

(Embodiment 3)
FIG. 20 is a diagram illustrating the wideband signal receiving apparatus according to the third embodiment. Receiving device 2K includes optical branching device 213K, semiconductor optical amplifiers 216K-1, 216K-2,... 216K-N, light receivers 201K-1, 201K-2,. 202K-1, 202K-2, ..., 202K-N, digital signal processing circuit 203K, signal generator 217K, timing adjustment circuit 218K, amplitude adjustment circuit 219K, bias adjustment circuit 220K, branching device 221K and delay circuit 222K- 2, ..., 222K-N.

  The processing of the signal generator 217K, timing adjustment circuit 218K, amplitude adjustment circuit 219K, and bias adjustment circuit 220K is the same as the processing of the signal generator 217H, timing adjustment circuit 218H, amplitude adjustment circuit 219H, and bias adjustment circuit 220H in FIG. It is.

  The branching device 221K receives the current signal from the signal generator 217K and branches it. The delay circuits 222K-2,..., 222K-N receive the branched current signal from the branching device 221K, and delay the branched current signal by the respective delay times. The optical branching unit 213K receives a broadband signal from the transmission device 1A and branches it.

  The semiconductor optical amplifier 216K-1 inputs the branched broadband signal from the optical branching device 213K, inputs the branched current signal from the branching device 221K, and samples the branched broadband signal using the branched current signal. And amplify. The semiconductor optical amplifiers 216K-2,..., 216K-N receive the branched broadband signals from the optical branching unit 213K, and are branched and delayed from the delay circuits 222K-2,. A current signal is input, and the branched and delayed wideband signal is sampled and amplified using the branched and delayed current signals.

  The optical receivers 201K-1, 201K-2,..., 201K-N are optical signals which are obtained by sampling and amplifying the broadband signals from the semiconductor optical amplifiers 216K-1, 216K-2,. Convert signal to electrical signal. The AD conversion circuits 202K-1, 202K-2,..., 202K-N respectively convert the wideband signals after sampling and amplification from the light receivers 201K-1, 201K-2,. Convert signal to digital signal. The digital signal processing circuit 203K combines the sampling / amplified wideband signals from the AD conversion circuits 202K-1, 202K-2,..., 202K-N, and combines the sampling signal amplified by a predetermined method. The amplified broadband signal is demodulated into a data signal.

  As described above, the semiconductor optical amplifier samples and amplifies an optical signal such as a broadband signal at a predetermined timing, and the signal generator outputs a signal having a current larger than the threshold current of the semiconductor optical amplifier. The signal having a current equal to or lower than the threshold current is output to the semiconductor optical amplifier at a timing other than the predetermined timing. Since the semiconductor optical amplifier can be integrated with a light receiver and is excellent in mass productivity, the receiving apparatus can receive data by time division separation of the optical region economically and with high accuracy. The receiving apparatus can distribute and parallel process optical signals such as broadband signals in the electrical domain.

(Embodiment 4)
FIG. 21 is a diagram illustrating a time division multiplexing receiver according to the fourth embodiment. The receiving device 2L includes a semiconductor optical amplifier 216L, an AD conversion circuit 202L, a digital signal processing circuit 203L, a signal generator 217L, a timing adjustment circuit 218L, an amplitude adjustment circuit 219L, a bias adjustment circuit 220L, and a signal separation circuit 223L.

  The AD conversion circuit 202L, digital signal processing circuit 203L, signal generator 217L, timing adjustment circuit 218L, amplitude adjustment circuit 219L, and bias adjustment circuit 220L are respectively processed by the AD conversion circuit 202H, digital signal processing circuit 203H, and signal in FIG. The processing is the same as that of the generator 217H, the timing adjustment circuit 218H, the amplitude adjustment circuit 219H, and the bias adjustment circuit 220H.

  The semiconductor optical amplifier 216L receives the time division multiplexed signal, samples and amplifies the time division multiplexed signal at a predetermined timing, extracts a predetermined band signal, and converts the predetermined band signal from an optical signal to an electrical signal. Convert (see Non-Patent Document 5). The signal separation circuit 223L separates a predetermined band signal from the semiconductor optical amplifier 216L and a current signal from the signal generator 217L. A directional coupler can be used as the signal separation circuit 223L. The same effects as those of the first embodiment can be obtained, and a light receiver can be omitted.

(Embodiment 5)
FIG. 22 is a diagram illustrating a time division multiplexing receiver according to the fifth embodiment. The receiving device 2M includes a semiconductor optical amplifier 216M, a light receiver 201M, a switching circuit 226M, an AD conversion circuit 202M, a digital signal processing circuit 203M, a baseband signal receiving circuit 227M, a signal generator 217M, a timing adjustment circuit 218M, and an amplitude adjustment circuit 219M. , A bias adjustment circuit 220M, a control circuit 224M, and a switch circuit 225M.

  The transmitting apparatus 1A switches and transmits a baseband signal and a modulated signal obtained by modulating the baseband signal at a predetermined timing. The receiving apparatus 2M selects a received signal processing method according to whether the received signal is a baseband signal or a modulated signal obtained by modulating the baseband signal. Examples of the baseband signal include a high-speed baseband signal such as a 10 Gb / s or 40 Gb / s NRZ signal. Examples of the modulation signal obtained by modulating the baseband signal include multilevel modulation signals such as 4-level PSK, 16-level QAM, and OFDM.

  The control circuit 224M determines whether the electrical signal from the light receiver 201M is a baseband signal or a modulation signal obtained by modulating the baseband signal as described below.

  First, a case where the bit rate of the baseband signal is different from an integer multiple of the sampling frequency will be described. The control circuit 224M has a clock extraction function for a frequency equal to the bit rate of the baseband signal. When the clock can be extracted from the electrical signal from the light receiver 201M, the control circuit 224M determines that the electrical signal from the light receiver 201M is the base hand signal. When the clock cannot be extracted from the electrical signal from the light receiver 201M, the control circuit 224M determines that the electrical signal from the light receiver 201M is a modulated signal obtained by modulating the base hand signal.

  Next, a case where the bit rate of the baseband signal is equal to an integer multiple of the sampling frequency will be described. In the transmitting apparatus 1A, a signal type determination pattern is added in advance to at least one of the header portion of the baseband signal and the modulated signal obtained by modulating the baseband signal. In the receiving device 2M, the control circuit 224M determines whether the electrical signal from the light receiver 201M is a baseband signal or a modulated signal obtained by modulating the baseband signal based on the signal type determination pattern.

  When the bit rate of the baseband signal is different from an integer multiple of the sampling frequency, the control circuit 224M may have a clock extraction function for a frequency equal to the bit rate of the baseband signal. A pattern for type determination may be added in advance. When the bit rate of the baseband signal is equal to an integer multiple of the sampling frequency, even if the control circuit 224M has a clock extraction function for a frequency equal to the bit rate of the baseband signal, the time division multiplexed signal Since the harmonic components of the clock may be extracted, the transmission apparatus 1A adds a signal type determination pattern in advance.

  First, a processing method when the receiving device 2M receives a baseband signal will be described. The control circuit 224M determines that the electrical signal from the light receiver 201M is a baseband signal, turns off the switch circuit 225M, and sets the switching circuit 226M on the baseband signal reception circuit 227M side. The semiconductor optical amplifier 216M simply amplifies the baseband signal. The baseband signal receiving circuit 227M demodulates the baseband signal by a predetermined method.

  Next, a processing method when receiving apparatus 2M receives a modulated signal obtained by modulating a baseband signal will be described. The control circuit 224M determines that the electrical signal from the light receiver 201M is a modulation signal obtained by modulating the baseband signal, turns on the switch circuit 225M, and sets the switching circuit 226M on the AD conversion circuit 202M side. The semiconductor optical amplifier 216M samples and amplifies the modulated signal obtained by modulating the baseband signal using the current signal from the signal generator 217M. The AD conversion circuit 202M converts the modulation signal obtained by modulating the baseband signal from an analog signal to a digital signal, and the digital signal processing circuit 203M demodulates the modulation signal obtained by modulating the baseband signal by a predetermined method.

  As described above, the receiving apparatus flexibly changes the processing content between the processing content when the baseband signal is received and the processing content when the modulation signal obtained by modulating the baseband signal is received. be able to.

  The optical access system and the receiving apparatus according to the present invention can be applied to a system that transmits and receives a baseband signal and a modulated signal obtained by modulating the baseband signal as an optical signal.

1: transmitter 2: receiver 3: optical transmission path 4: optical splitter 101: band signal generator 102: optical transmitter 103: laser light source 104: optical modulator 105: time division multiplexing switch 201: light receiver 202: AD conversion circuit 203: Digital signal processing circuit 204: Time division separation switch 205: Band pass filter 206: Radio signal front end 207: Antenna 208: Optical switch 209: Optical multiplexer 210: Frequency stabilization circuit 211: Pulse light source 212 : Polarization adjuster 213: Optical splitter 214: Optical splitter 215: Optical delay 216: Semiconductor optical amplifier 217: Signal generator 218: Timing adjustment circuit 219: Amplitude adjustment circuit 220: Bias adjustment circuit 221: Branch device 222 : Delay circuit 223: Signal separation circuit 224: Control circuit 225: Switch circuit 226: Switching Road 227: baseband signal reception circuit

Claims (6)

A transmitter for transmitting time-division multiplexed optical signals;
A receiver for receiving the time-division multiplexed optical signal;
An optical access system comprising:
The receiving device is:
A semiconductor optical amplifier that inputs the time-division multiplexed optical signal and samples and amplifies the optical signal at a predetermined timing;
A signal having a current larger than a threshold current of the semiconductor optical amplifier is output to the semiconductor optical amplifier at the predetermined timing, and a signal having a current equal to or lower than the threshold current is output at the semiconductor optical amplifier at a time other than the predetermined timing. A signal generator for output to the amplifier;
A light receiver that converts an optical signal sampled and amplified by the semiconductor optical amplifier into an electrical signal;
A control circuit that monitors the electrical signal output by the light receiver and determines whether the electrical signal is a baseband signal or a modulated signal obtained by modulating the baseband signal;
Based on the determination of the control circuit, when the electrical signal is a baseband signal, the signal generator and the semiconductor optical amplifier are disconnected from each other, and the electrical signal is a modulated signal obtained by modulating the baseband signal. A switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other;
An optical access system comprising: A transmission device for transmitting an optical signal;
A receiving device for receiving the optical signal;
An optical access system comprising:
The receiving device is:
An optical branching device for branching the optical signal into a plurality of branched optical signals;
A plurality of semiconductor optical amplifiers for inputting and sampling and amplifying each branched optical signal at each predetermined timing;
A signal having a current larger than the threshold current of each semiconductor optical amplifier is output to each semiconductor optical amplifier at each predetermined timing, and a signal having a current lower than each threshold current is output to each semiconductor optical amplifier at a time other than each predetermined timing. A plurality of signal generators for output to the amplifier;
A plurality of optical receivers that convert each branched optical signal sampled and amplified by each semiconductor optical amplifier into respective electrical signals;
An electrical circuit that performs signal processing on each electrical signal and combines the electrical signals that have undergone signal processing;
A control circuit that monitors the electrical signal output by the light receiver and determines whether the electrical signal is a baseband signal or a modulated signal obtained by modulating the baseband signal;
Based on the determination of the control circuit, when the electrical signal is a baseband signal, the signal generator and the semiconductor optical amplifier are disconnected from each other, and the electrical signal is a modulated signal obtained by modulating the baseband signal. A switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other;
An optical access system comprising:   The signal generator adjusts at least one of an amplitude and a bias of a current signal output to the semiconductor optical amplifier, and controls a sampling pulse width and an amplification gain of the semiconductor optical amplifier. Item 3. The optical access system according to Item 1 or 2. A semiconductor optical amplifier that inputs time-division multiplexed optical signals and samples and amplifies them at a predetermined timing;
A signal having a current larger than a threshold current of the semiconductor optical amplifier is output to the semiconductor optical amplifier at the predetermined timing, and a signal having a current equal to or lower than the threshold current is output at the semiconductor optical amplifier at a time other than the predetermined timing. A signal generator for output to the amplifier;
A light receiver that converts an optical signal sampled and amplified by the semiconductor optical amplifier into an electrical signal;
A control circuit that monitors the electrical signal output by the light receiver and determines whether the electrical signal is a baseband signal or a modulated signal obtained by modulating the baseband signal;
Based on the determination of the control circuit, when the electrical signal is a baseband signal, the signal generator and the semiconductor optical amplifier are disconnected from each other, and the electrical signal is a modulated signal obtained by modulating the baseband signal. A switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other;
A receiving apparatus comprising: An optical branching device for branching an optical signal into a plurality of branched optical signals;
A plurality of semiconductor optical amplifiers for inputting and sampling and amplifying each branched optical signal at each predetermined timing;
A signal having a current larger than the threshold current of each semiconductor optical amplifier is output to each semiconductor optical amplifier at each predetermined timing, and a signal having a current lower than each threshold current is output to each semiconductor optical amplifier at a time other than each predetermined timing. A plurality of signal generators for output to the amplifier;
A plurality of optical receivers that convert each branched optical signal sampled and amplified by each semiconductor optical amplifier into respective electrical signals;
An electrical circuit that performs signal processing on each electrical signal and combines the electrical signals that have undergone signal processing;
A control circuit that monitors the electrical signal output by the light receiver and determines whether the electrical signal is a baseband signal or a modulated signal obtained by modulating the baseband signal;
Based on the determination of the control circuit, when the electrical signal is a baseband signal, the signal generator and the semiconductor optical amplifier are disconnected from each other, and the electrical signal is a modulated signal obtained by modulating the baseband signal. A switch circuit for connecting the signal generator and the semiconductor optical amplifier to each other;
A receiving apparatus comprising: The signal generator adjusts at least one of an amplitude and a bias of a current signal output to the semiconductor optical amplifier, and controls a sampling pulse width and an amplification gain of the semiconductor optical amplifier. Item 6. The receiving device according to Item 4 or 5 .

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