JP4974876B2 - Optical signal receiver - Google Patents

Description

  The present invention receives an optical signal obtained by performing frequency modulation of several GHz on a multi-channel signal that has been frequency division multiplexed (hereinafter referred to as FDM: Frequency Division Multiplexing), converts the optical signal into an electrical signal, and converts the optical signal into an electrical signal. The present invention relates to an optical signal receiving apparatus that demodulates a channel signal.

  In a conventional optical signal transmission system, when an FDM signal is input, the FDM signal is frequency-modulated, converted into an optical signal, and output, and received from the optical signal transmitter via an optical fiber. There is one that converts an optical signal into an electric signal and demodulates a multi-channel signal that is an FDM signal from the electric signal (see, for example, Patent Document 1).

  However, since the conventional optical signal transmission system transmits a wideband collective FM modulated signal over several GHz, in order to prevent distortion from occurring in the demodulated FDM signal band, the frequency dependence of the group delay ( (Hereinafter referred to as group delay deviation) is required to be flat within the collective FM modulation signal band. In such analog communication, it is necessary to manage the group delay deviation in the entire system from the transmission end to the reception end of the optical signal transmission system. Therefore, there has been a conventional optical signal receiving apparatus provided with a group delay adjustment unit that compensates for the group delay of the optical signal transmission system so that distortion does not occur in the demodulated FDM signal band (for example, Patent Document 2).

JP-A-8-274714 JP 2006-245966 A

  Since the conventional optical signal receiving apparatus is configured as described above, by adjusting in advance the group delay deviation from the optical signal transmitting apparatus to the FDM signal demodulating section provided in the optical signal receiving apparatus by the group delay adjusting section. It is possible to minimize distortion components in the demodulated FDM signal. However, depending on where the optical signal receiver is installed, the received power of the optical signal receiver changes and the operating point of the current-voltage conversion amplifier (hereinafter referred to as transimpedance amplifier) changes. The generated group delay deviation changes, the adjustment value of the group delay adjustment unit adjusted in advance deviates from the optimum value, the distortion component in the demodulated FDM signal increases, and the signal quality after demodulation is degraded. was there.

  An object of the present invention is to obtain an optical signal receiving apparatus that can demodulate an FDM signal with a constant group delay characteristic of a signal input to a signal demodulator.

An optical signal receiving device according to the present invention includes a monitoring unit that monitors a current value of an electric signal converted by a photoelectric conversion unit, and an electric signal output from a signal attenuating unit based on the current value monitored by the monitoring unit. and a control unit the current value of the performs control so that a predetermined reference value, the group delay adjusting unit, when the current value corresponding to the reference value from the signal attenuator is output, the output from the demodulator The multi-channel signal is adjusted so that the distortion component caused by the group delay deviation included in the multi-channel signal is minimized .

According to the present invention, the current value of the electrical signal output from the signal attenuating unit is monitored based on the current value monitored by the monitoring unit, which monitors the current value of the electrical signal converted by the photoelectric conversion unit. A control unit that performs control so that the reference value is set in advance , and the group delay adjustment unit is a multi-channel that is output from the demodulation unit when a current value corresponding to the reference value is output from the signal attenuation unit. since the distortion component due to the group delay deviation included in the signal is adjusted to minimize the group delay characteristic of the signal input to the demodulation section is constant, it is possible to reliably demodulate the FDM signal effect There is.

Hereinafter, an example of an embodiment of the present invention will be described with reference to the accompanying drawings.
Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration of an optical signal transmission system according to the first embodiment. When an FDM signal is input, the optical signal transmission apparatus 2 that performs frequency modulation on the FDM signal, converts the FDM signal into an optical signal, and outputs the optical signal. And an optical signal receiving device 1 that converts an optical signal received from the optical signal transmitting device 2 through the optical fiber 3 into a current signal (electric signal) and demodulates a multichannel signal that is an FDM signal from the current signal. I have.

  FIG. 2 is a block diagram showing a configuration of optical signal receiving apparatus 1 according to Embodiment 1 of the present invention. The optical signal receiving apparatus 1 includes a photodiode (photoelectric conversion unit) 21, a signal attenuation unit 22, a transimpedance amplifier (signal amplification unit) 23, a group delay adjustment unit 24, a demodulation unit 25, a monitoring unit 26, and a control unit 27. I have. The photodiode 21 converts the optical signal transmitted from the optical signal transmission device into a current signal, and outputs the current signal to the signal attenuating unit 22 and the monitoring unit 26. The monitoring unit 26 monitors the current signal of the photodiode 21. The control unit 27 compares the current value of the current signal monitored by the monitoring unit 26 with a reference signal current value stored in advance, and controls the signal attenuating unit 22. The signal attenuating unit 22 attenuates the current signal output from the photodiode 21 based on the control of the control unit 27 and outputs the signal to the transimpedance amplifier 23 (FET: Field Effect Transistor) or a PIN diode (PIN). -DIODE: p-intrinsic-n Diode).

  The transimpedance amplifier 23 converts the current signal into a voltage signal and amplifies it. The group delay adjustment unit 24 adjusts the group delay of the amplified voltage signal output from the transimpedance amplifier 23. The demodulator 25 demodulates the voltage signal output from the group delay adjuster 24 and outputs an FDM signal. The group delay adjustment unit 24 is a distortion component caused by the group delay deviation included in the FDM signal output from the demodulation unit 25 at the specified minimum received light power, that is, the reference signal current value stored in the control unit 27. Is adjusted in advance so as to be minimum.

Next, the operation will be described.
When the photodiode 21 of the optical signal receiving device 1 receives an optical signal from the optical signal transmitting device via an optical fiber, the photodiode 21 converts the optical signal into a current signal. Next, the monitoring unit 26 monitors the current signal of the photodiode 21 and outputs the current value of the current signal to the control unit 27. Next, the control unit 27 compares the current value output from the monitoring unit 26 with a reference signal current value stored in advance. Next, the control unit 27 controls the signal attenuation unit 22 so that the current value of the current signal input to the transimpedance amplifier 23 becomes the same value as the reference signal current value. Specifically, the signal current input to the signal attenuator 22 is equal to the difference Isig-Imin [mA] between the signal current value Isig [mA] output from the monitoring unit 26 and the reference signal current value Imin [mA]. The signal attenuator 22 is controlled so as to attenuate the current value.

  Next, the signal attenuating unit 22 attenuates the current signal converted by the photodiode 21 based on an instruction from the control unit 27. Next, the transimpedance amplifier 23 converts the attenuated current signal output from the signal attenuation unit 22 into a voltage signal and amplifies it. Next, the group delay adjustment unit 24 adjusts the group delay of the amplified voltage signal output from the transimpedance amplifier 23. Next, the demodulation unit 25 demodulates the voltage signal output from the group delay adjustment unit 24 and outputs an FDM signal.

  As described above, the optical signal receiving device 1 according to the first embodiment includes the monitoring unit 26 that monitors the current signal output from the photodiode 21, the current value of the current signal monitored by the monitoring unit 26, Since the control unit 27 that compares the reference signal current value stored inside and controls the signal attenuating unit 22 is provided, the operation state of the transimpedance amplifier 23 is determined regardless of the received light power of the optical signal receiving device 1. The group delay deviation generated by the transimpedance amplifier 23 can be kept constant without depending on the received light power of the optical signal receiving device 1. For this reason, the distortion component resulting from the group delay deviation included in the FDM signal demodulated by the demodulator 25 does not depend on the received light power, and the FDM signal can be reliably demodulated. Further, since no optical parts such as an optical attenuator are used, there is an effect that the manufacturing cost of the optical signal receiving apparatus can be suppressed.

Embodiment 2. FIG.
FIG. 3 is a block diagram showing the configuration of the optical signal receiving apparatus 1 according to the second embodiment of the present invention. The optical signal receiving apparatus 1 according to the second embodiment includes a photodiode 21, a signal attenuating unit 22, a transimpedance amplifier 23, a group delay adjusting unit 24, a demodulating unit 25, a branching unit 31, a filter unit 32, and a detecting unit (distortion component). A detector 33) and a controller 34. Branch unit 31 branches the FDM signal demodulated by the demodulator 2 5. Filter section 3 2, extracts a frequency signal of the distortion component due to the group delay deviation from FDM signal branched by the branching unit 3 1.

  Here, since the distortion component is generated at a frequency determined by the frequency arrangement of the FDM signal, it can be easily extracted by a band-pass filter or the like that passes only the frequency signal of the distortion component. For example, if the carrier frequency of the FDM signal is f1, f2 (f1 <f2), distortion components are generated at frequencies such as f1 + f2 and f2-f1, so that only the frequency signal of f1 + f2 or f2-f1 is passed. Use a filter. Note that the distortion component at the frequency of f1 + f2 and the frequency of f2-f1 are in a proportional relationship, and if the distortion component at one frequency is minimized, the distortion component at the other frequency is also minimized.

Detection section 3 3 converts the frequency signal of the distortion component extracted by the filter unit 3 2 to a DC voltage value. The control unit 3 4, DC voltage value converted by the detection unit 3 3 controls the attenuation unit 2 2 so that the previously stored reference values therein. Wherein the reference value is converted, when adjusting the group delay compensator 2 4 minimum light receiving power, a value of the frequency signal is converted into a DC voltage distortion component, and to the reference value, the detection unit 3 3 The distortion component can be minimized by controlling the DC voltage value to be the same value. Since other configurations are the same as those of the first embodiment, description thereof is omitted.

Next, the operation will be described.
When the photodiode 21 of the optical signal receiving device 1 receives an optical signal from the optical signal transmitting device via an optical fiber, the photodiode 21 converts the optical signal into a current signal. Next, the signal attenuating unit 22 attenuates the current signal converted by the photodiode 21 based on an instruction from the control unit 34. Next, the transimpedance amplifier 23 converts the attenuated current signal output from the signal attenuation unit 22 into a voltage signal and amplifies it. Next, the group delay adjustment unit 24 adjusts the group delay of the amplified voltage signal output from the transimpedance amplifier 23.

  Next, the demodulation unit 25 demodulates the voltage signal output from the group delay adjustment unit 24. Next, the branching unit 31 branches a part of the signal power of the FDM signal output from the demodulating unit 25. Next, the filter unit 32 extracts, that is, passes the frequency signal of the distortion component from a part of the FDM signal power branched by the branch unit 31. Next, the detection unit 33 converts the frequency signal of the distortion component extracted by the filter unit 32 into a DC voltage value. Next, the control unit 34 controls the signal attenuation unit 22 so that the DC voltage value output from the detection unit 33 becomes the same value as the reference value stored therein.

  As described above, the optical signal receiving apparatus 1 according to the second embodiment includes the filter unit 32 that extracts the frequency signal of the distortion component from the FDM signal branched by the branching unit 31, and the distortion component extracted by the filter unit 32. And a control unit that controls the signal attenuating unit 22 so that the DC voltage value output from the detecting unit 33 is the same as the reference value stored therein. 34, the operating state of the transimpedance amplifier 23 can be kept constant, and the group delay deviation generated in the transimpedance amplifier 23 becomes constant regardless of the received light power of the optical signal receiving apparatus 1. For this reason, the distortion component resulting from the group delay deviation included in the FDM signal demodulated by the demodulator 25 does not depend on the received light power, and the FDM signal can be reliably demodulated. Other effects are the same as those of the first embodiment.

It is the figure which showed the structure of the optical signal transmission system. 1 is a block diagram showing a configuration of an optical signal receiving device according to Embodiment 1. FIG. FIG. 5 is a block diagram illustrating a configuration of an optical signal receiving device according to a second embodiment.

Explanation of symbols

  1 optical signal receiver, 2 optical signal transmitter, 3 optical fiber, 21 photodiode (photoelectric converter), 22 signal attenuator, 23 transimpedance amplifier (signal amplifier), 24 group delay adjuster, 25 demodulator, 26 monitoring unit, 27, 34 control unit, 31 branching unit, 32 filter unit, 33 detection unit (distortion component detection unit).

Claims (2)

A photoelectric conversion unit that converts an optical signal obtained by frequency-modulating multi-channel signals into an electrical signal;
A signal attenuation unit for attenuating the electrical signal converted by the photoelectric conversion unit;
A signal amplifying unit for amplifying the electric signal attenuated by the signal attenuating unit;
And group delay adjustment unit for adjusting the group delay of the electrical signal amplified by the signal amplifying section,
A demodulator that demodulates a multi-channel signal from the electrical signal adjusted by the group delay adjuster;
A monitoring unit that monitors the current value of the electrical signal converted by the photoelectric conversion unit;
A control unit that performs control so that the current value of the electrical signal output from the signal attenuation unit becomes a preset reference value based on the current value monitored by the monitoring unit ;
The group delay adjusting unit is
When the current value corresponding to the reference value is output from the signal attenuating unit, the distortion component due to the group delay deviation included in the multi-channel signal output from the demodulating unit is adjusted to be minimum An optical signal receiving device. A photoelectric conversion unit that converts an optical signal obtained by frequency-modulating multi-channel signals into an electrical signal;
A signal attenuation unit for attenuating the electrical signal converted by the photoelectric conversion unit;
A signal amplifying unit for amplifying the electric signal attenuated by the signal attenuating unit;
And group delay adjustment unit for adjusting the group delay of the electrical signal amplified by the signal amplifying section,
A demodulator that demodulates a multi-channel signal from the electrical signal adjusted by the group delay adjuster;
A distortion component detection unit for detecting distortion components caused by group delay deviation included in the multi-channel signal demodulated by the demodulation unit;
An optical signal receiving apparatus comprising: a control unit that controls a current value of an electrical signal output from the signal attenuating unit so that a distortion component detected by the distortion component detecting unit becomes a preset reference value .

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