JPH0685752A - Error rate adjustment method for optical receiver - Google Patents

Abstract

(57) [Abstract] [Objective] Regarding the error rate adjustment method of the optical receiver, the error rate adjustment method of the optical receiver capable of automatically setting the optimum adjustment value of the 3R function against temperature fluctuation, power supply fluctuation, etc. For the purpose of providing. [Configuration] A signal for inputting an error rate signal output from the error rate measuring unit 170 to adjust the multiplication factor of the light receiving element 100 and the gain of the equalizing amplifier 200 to an optimum value, and the discrimination level in the discrimination circuit 300. A signal for adjusting the optimum value at the ambient temperature is output to each of the equalizing amplifiers, and a signal for adjusting the phase of the output clock of the timing circuit 400 to the optimum value at the ambient temperature is output to output the timing. An arithmetic processing unit 130 to be added to the circuit and a storage unit 150 for storing each optimum adjustment value of the multiplication factor of the light receiving element at each ambient temperature, the gain of the equalizing amplifier, the discrimination level, and the phase of the timing clock are provided. The data stored in the storage unit is read at an arbitrary time during communication, and the error rate value is always automatically set to a predetermined range.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in an error rate adjustment method for an optical receiver. Optical communication regenerators or optical receivers used in terminal equipment are equipped with equalization amplification (Reshaping), retiming (Retiming), identification regeneration (Reg
It has a so-called 3R function of enerating) and is adjusted so that the 3R function operates optimally with respect to temperature fluctuations and power supply fluctuations. At this time, 3R that is optimal for temperature fluctuations, power supply fluctuations, etc.
There is a demand for an error rate adjustment method for an optical receiver that can automatically set an adjustment value for a function.

[0002]

2. Description of the Related Art FIG. 8 is a circuit diagram of a conventional optical receiver. Regarding the adjustment of the error rate of the optical receiver, the error rate (error rate) is measured by a measurement circuit (not shown) connected to the subsequent stage of the optical receiver shown in FIG. 8 and observed so that the error rate becomes optimum. On the other hand, adjustment is performed on three items, that is, adjustment of the identification level (SL level), MOPT adjustment, and phase adjustment.

Adjustment of discrimination level: In order to set an optimal discrimination level (minimum width voltage) for discriminating between "0" and "1" of input data in the discrimination circuit 3 in the optical receiver, etc. The variable resistor (Rv) 6 provided in the integrated amplifier 2 is adjusted.

MOPT adjustment: An avalanche photodiode (APD) is used as the light receiving element 1, and the optimum signal / noise ratio (S / N ratio) of the optical receiver is used.
There is a multiplication factor value (MOPT) of the APD that obtains the following. The variable resistor (Rv) 7 provided in the equalizing amplifier 2 is adjusted to set MOPT.

Phase adjustment: The timing circuit 4 extracts a timing clock from the output data of the equalizing amplifier 2, and the identification circuit 3 performs identification reproduction with respect to the input data using this timing clock. The phase is adjusted first by the coaxial 8 connected between the output of the equalizing amplifier 2 and the input of the timing circuit 4, and the phase is further finely adjusted by the variable resistor (Rv) 9 provided in the timing circuit 4.

In this way, the error rate of the optical receiver is adjusted.

[0007]

However, in the circuit configuration described above, the error rate is deteriorated due to temperature fluctuations, power supply fluctuations, aging of the light emitting element of the optical transmitter (not shown), the light receiving element of the optical receiver, or the like. If you do, there is a problem that you can not return.

Therefore, an object of the present invention is to provide an error rate adjustment method for an optical receiver capable of automatically setting an optimum adjustment value for the 3R function with respect to temperature fluctuations, power supply fluctuations, and the like.

[0009]

The above problems can be solved by the circuit configuration shown in FIG. That is, in FIG. 1, (claim 1) an input optical signal is converted into an electric signal with a predetermined multiplication factor and outputted, and the multiplication factor is variable by the output optical signal; Equalization amplifier 200 that amplifies and outputs to the extent that presence can be determined
A timing circuit 400 that outputs a clock for setting the time point for determining the presence or absence of a pulse from the output pulse of the equalizing amplifier, and the waveform of the output pulse of the equalizing amplifier,
An optical receiver having an identification circuit 300 for performing identification and reproduction at the timing of an output clock of a timing section, wherein an error rate measuring section 170 connected to a subsequent stage of the optical receiver is provided with an error rate of an output signal of the optical receiver. In the error rate adjustment method of the optical receiver that measures the error rate and sets the error rate value within a predetermined range, 130 is
For adjusting the multiplication factor of the light receiving element 100 and the gain of the equalizing amplifier 200 to the optimum values so that the error rate signal output from the error rate measuring unit 170 is input and the value of the error rate is set within a predetermined range. It outputs a signal to the equalizing amplifier, and outputs a signal for adjusting the discrimination level in the discriminating circuit 300 to an optimum value at the ambient temperature to add to the equalizing amplifier, and the timing clock output from the timing circuit 400. It is an arithmetic processing unit that outputs a signal for adjusting the phase to an optimum value at the ambient temperature and adds the signal to the timing circuit.

Then, the multiplication factor of the light receiving element 100, the gain of the equalizing amplifier 200, the discrimination level, and the phase of the timing clock are repeatedly adjusted a predetermined number of times to set the value of the error rate within a predetermined range. .

(Claim 2) An input optical signal is converted into an electric signal with a predetermined multiplication factor and output, and the multiplication factor is variable depending on the output optical signal. The equalizing amplifier 200 that amplifies and outputs to the extent that can be determined, the timing circuit 400 that outputs a clock for setting the time to determine the presence or absence of a pulse from the output pulse of the equalizing amplifier, and the output pulse of the equalizing amplifier. An optical receiver having an identification circuit 300 for performing identification and reproduction with respect to a waveform at the timing of a clock output from a timing circuit, the error rate measuring section 17 being connected to a subsequent stage of the optical receiver.
At 0, in the error rate adjustment method of the optical receiver that measures the error rate of the output signal of the optical receiver and sets the value of the error rate within a predetermined range, 130 is the error rate of the output of the error rate measurement unit 170. To input a signal and set the error rate value within a predetermined range,
A signal for adjusting the multiplication factor of the light receiving element 100 and the gain of the equalizing amplifier 200 to an optimum value is output to be added to the equalizing amplifier, and the identification level in the identification circuit 300 is adjusted to the optimal value at the ambient temperature. It is an arithmetic processing unit that outputs a signal and adds it to the equalizing amplifier, and outputs a signal for adjusting the phase of the timing clock output from the timing circuit 400 to an optimum value at the ambient temperature and adds it to the timing circuit.

Reference numeral 150 denotes the light receiving element 100 at each ambient temperature.
Is a storage unit that stores the optimum adjustment value of the multiplication factor and the gain of the equalization amplifier 200, the optimum adjustment value of the discrimination level at each ambient temperature, and the optimum adjustment value of the phase of the timing clock.

The storage unit 150 can be used at any time during communication.
The error rate value is always automatically set within a predetermined range by reading and adjusting the data stored in.

[0014]

[Operation] Referring to FIG. 1, the light receiving element 10 at each ambient temperature
The storage unit 150 stores the optimum adjustment value of the multiplication factor of 0 and the optimum adjustment value of the gain of the equalization amplifier 200, the optimum adjustment value of the discrimination level at each ambient temperature, and the optimum adjustment value of the phase of the timing clock.

Then, the arithmetic processing section 130 reads out and adjusts the data stored in the storage section 150 at an arbitrary time during communication to automatically set the value of the error rate within a predetermined range.

As a result, it is possible to automatically set the optimum adjustment value for the 3R function with respect to temperature fluctuations, power supply fluctuations, and the like.

[0017]

2 is a circuit diagram of an optical receiver according to an embodiment of the present invention. FIG. 3 is a diagram for explaining a method of setting the adjustment voltage in the embodiment.

FIG. 4 is a diagram showing the relationship between phase adjustment voltage and temperature in the embodiment. FIG. 5 is a block diagram of the system of the embodiment. FIG. 6 is a flowchart (No. 1) for explaining the operation of the embodiment.

FIG. 7 is a flow chart (No. 2) for explaining the operation of the embodiment. The same reference numerals denote the same objects throughout the drawings. First, an embodiment of the first invention will be described.

(1) First, a method of manually adjusting the error rate will be described. An optical signal is input to the optical receiver shown in FIG. Control signals are sent to a microprocessor unit (hereinafter M
(Hereinafter referred to as PU) 13 to output digital data corresponding to MOPT from MPU 13 to convert it to an analog MOPT signal via D / A converter 14 and then add it to equalizing amplifier 2. Then, while observing the eye pattern at the output point a of the equalizing amplifier 2, the MOPT data is changed little by little and the scan is performed so that this eye pattern is adjusted to be the widest.

A coaxial line connecting the equalizing amplifier 2 and the timing circuit 4 while observing an eye pattern at the output point a of the equalizing amplifier 2 and observing a timing clock at the output point b of the timing circuit 4. Optimally adjust the length of 8.

(2) Next, an automatic error rate adjusting method will be described. A control signal is input to the MPU 13 to switch to the automatic adjustment mode. The current analog temperature data from the temperature detector 11 is converted into digital temperature data via the A / D converter 12 and then input to the MPU 13. MPU13 to MOP
Outputs the adjustment values of T and SL, and the value for phase adjustment and outputs D
Converted to an analog value via the A / A converter 14 for MOP
The adjustment values of T and SL are added to the equalizing amplifier 2, and the value for phase adjustment is added to the timing circuit 4.

Then, the error rate is measured by a measuring circuit (not shown) connected to the subsequent stage of the optical receiver, and the error rate signal as the measurement result is fed back to the MPU 13 and added. By changing the SL adjustment value little by little, the MPU 13 repeats this scan several times so that the error rate signal becomes the best, and ends when the error rate signal falls within the preset standard, and finally Write the set SL adjustment value (in this case, the value corresponding to b) to the E ² PROM / RAM 14.

The values for MOPT and the phase adjustment are similarly set. FIG. 3 shows an eye pattern display of the error rate curve. For example, when the error rate signal fed back to the MPU 13 is E ^-5 (10 ^-5 ), the SL adjustment point h shown in the figure is moved to the f point and again. Measure the error rate. When the next error rate signal is E ^-7 (10 ^-7 ), the SL adjustment point f is further moved to point d, and the error rate is repeatedly measured. The next error rate signal is E ^-9
If it is (10 ⁻⁹ ), it does not fall within the standard, so the SL adjustment point d is moved to point b and the error rate is measured. The process ends when the error rate signal falls within the standard.

FIG. 4 shows the temperatures T ₁ , T ₂ , ..., T
The relationship of the optimum phase adjustment voltage at n is shown. As shown in the figure, when the temperature is sequentially changed to T ₁ , T ₂ , ..., Tn, the above operation is repeated to obtain the optimum phase at each temperature. Obtain the adjustment value (voltage) and write these optimum adjustment values (voltage) to the E ² PROM / RAM14. The adjustment values of MOPT and SL are similarly performed.

A control signal is input to the MPU 13 to turn off the automatic adjustment mode. Next, an automatic adjustment method during communication according to the second embodiment of the invention will be described with reference to the flowcharts shown in FIGS. 6 and 7.

(Step 1 (S.1)) The MPU 13 determines the presence / absence of an optical signal input by the monitor signal (RIN MON) from the equalizing amplifier 2. (S.2) When there is no optical signal input in (S.1) above, the automatic adjustment mode is terminated at that point.

(S.3) When an optical signal is input in the above (S.1), the error rate signal measured by the measuring circuit described later is input to the MPU 13, and this error rate signal is 10 ^-5 to 10 ^-9. It is determined whether or not it is within the range.

As shown in FIG. 5, the serial output data of the optical receiver 10 is converted into a serial / parallel converter (hereinafter referred to as S / P).
(Referred to as DMUX) 16 and converted into parallel data and added to a demultiplexer (hereinafter referred to as DMUX) 17. The DMUX 17 descrambles the input data to restore the original data, and the selection unit (hereinafter referred to as SEL) 18 transfers the data to a predetermined communication destination. The error rate signal described above is measured by a measuring circuit (not shown) provided in this DMUX 17, and is fed back to be added to the optical receiver 10.

(S.4) When the error rate signal is out of the range of 10 ^-5 to 10 ^{-9 in} the above (S.3), the automatic adjustment mode is terminated at that point. (S.5) The error rate signal is 10 ^-5 to 10 ^{-9 in the} above (S.3).
When it is within the range, the discrimination level (SL level) is adjusted. That is, the temperature detector 11 shown in FIG. 2 detects the temperature, and the MPU 13 reads the data (optimum SL adjustment value) corresponding to the detected temperature stored in the E ² PROM / RAM 15 and applies it to the equalizing amplifier 2. , Observe the error rate signal.

(S.6) Since the SL adjustment value may fluctuate due to fluctuations in the power supply, variations in circuit elements, etc., the error rate signal is observed by the MPU 13 in (S.5) above, and within the standard. It is determined whether or not it is within the standard, and when it is not within the standard, the adjustment value of SL is changed at 100 mV intervals, and the discrimination level is adjusted again. This is repeated N times (6 times or less).

(S.7) When the observed value of the error rate signal falls within the standard in (S.6) above, the adjustment of the discrimination level ends. (S.8) The optimum adjustment value of the discrimination level at the ambient temperature detected by the temperature detector 11 is read from the E ² PROM / RAM 15 and set as an initial value by the MPU 13 in addition to the equalization amplifier 2.

(S.9) E ² PROM / RAM 15 with MPU 13
The data corresponding to the detected temperature (optimum adjustment value of the phase) stored in is read out, added to the timing circuit 4, and the error rate signal is observed.

(S.10) In (S.9) above, the MPU 13 observes the error rate signal to determine whether or not the signal falls within the standard. If the signal does not fall within the standard, the phase adjustment value is adjusted, for example. Change the phase at 100 mV intervals and adjust the phase again. This is repeated N times (6 times or less).

(S.11) When the observed value of the error rate signal falls within the standard in (S.10) above, the phase adjustment is completed. (S.12) The optimum adjustment value of the phase at the ambient temperature detected by the temperature detector 11 is read from the E ² PROM / RAM 15 and set as an initial value by the MPU 13 in addition to the timing circuit 4.

[0036] (S.13) MPU13 in the E ² PROM / RAM15
Data corresponding to the detected temperature stored in
(The optimum adjustment value of 1) is read and added to the equalizing amplifier 2, and the error rate signal is observed.

(S.14) In the above (S.13), the MPU 13 observes the error rate signal to determine whether or not the signal falls within the standard. Adjust the MOPT again by changing it at 100 mV intervals. This is repeated N times (6 times or less).

(S.15) When the observed value of the error rate signal falls within the standard in (S.14), the MOPT adjustment is terminated. (S.16) If the observed value of the error rate signal does not fall within the standard even after the MOPT adjustment is repeated N times in (S.14) above, an alarm is externally issued. .

As a result, it is possible to automatically set the optimum adjustment value for the 3R function with respect to temperature fluctuations, power supply fluctuations, and the like. As a result, the standards of the equalizing amplifier, the timing circuit, the SAW filter, etc. can be relaxed, so that the yield as a module can be improved and the resistance to temperature fluctuation can also be improved.

Further, since the error rate is monitored and the optimum automatic adjustment is performed, the transmission characteristic of the optical transmission line can be improved.

[0041]

As described above, according to the present invention, in the optical receiver used in high-speed optical communication, the optimum adjustment value for the 3R function is automatically set with respect to temperature fluctuations, power supply fluctuations, and the like. be able to. As a result, the standards of the equalizing amplifier, the timing circuit, the SAW filter, etc. can be relaxed, so that the yield as a module can be improved and the resistance to temperature fluctuation can be improved.

Furthermore, since the error rate is monitored and the optimum automatic adjustment is performed, the transmission characteristics of the optical transmission line can be improved.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention,

FIG. 2 is a circuit configuration diagram of an optical receiver according to an embodiment of the present invention,

FIG. 3 is a diagram for explaining a method of setting an adjustment voltage in the embodiment,

FIG. 4 is a diagram showing a relationship between phase adjustment voltage and temperature in the embodiment,

FIG. 5 is a block diagram of the system of the embodiment,

FIG. 6 is a flowchart (part 1) for explaining the operation of the embodiment,

FIG. 7 is a flowchart (part 2) for explaining the operation of the embodiment,

FIG. 8 is a circuit configuration diagram of a conventional optical receiver.

[Explanation of symbols]

100 is a light receiving element, 130 is an arithmetic processing unit, 150 is a storage unit, 17
0 is an error rate measuring unit, 200 is an equalizing amplifier, 300 is an identification circuit, and 400 is a timing circuit.

Claims (2)

[Claims] 1. A light-receiving element (100) capable of converting an input optical signal into an electric signal with a predetermined multiplication factor and outputting the electric signal, and changing the multiplication factor according to the output optical signal, and an output pulse of the light-receiving element having a pulse. An equalizing amplifier (200) that amplifies and outputs to the extent that can be determined, a timing circuit (400) that outputs a clock for setting the time point for determining the presence or absence of a pulse from the output pulse of the equalizing amplifier, An optical receiver having an identification circuit (300) for performing identification and reproduction with respect to the waveform of an output pulse of an equalizing amplifier at the timing of an output clock of the timing circuit, the optical receiver being connected to a subsequent stage of the optical receiver. In the error rate measurement unit (170),
In the error rate adjustment method of the optical receiver for measuring the error rate of the output signal of the optical receiver and setting the value of the error rate within a predetermined range, the error rate signal output from the error rate measurement unit (170) To output a signal for adjusting the multiplication factor of the light receiving element (100) and the gain of the equalizing amplifier (200) to an optimum value so that the value of the error rate is set within a predetermined range. In addition to the equalizing amplifier, and outputs a signal for adjusting the discrimination level in the discrimination circuit (300) to an optimum value at ambient temperature, and adding the signal to the equalization amplifier, and the timing circuit (40
(0) is provided with an arithmetic processing unit (130) for outputting a signal for adjusting the phase of the timing clock output from (1) to an optimum value at ambient temperature, and adding the signal to the timing circuit. Adjustment of the gain of the equalizing amplifier (200), the discrimination level, and the phase of the timing clock is repeated a predetermined number of times to set the value of the error rate within a predetermined range. Error rate adjustment method. 2. A light-receiving element (100) capable of converting an input optical signal into an electric signal with a predetermined multiplication factor and outputting the electric signal, the multiplication factor being variable according to the output optical signal; An equalizing amplifier (200) that amplifies and outputs to the extent that can be determined, a timing circuit (400) that outputs a clock for setting the time point for determining the presence or absence of a pulse from the output pulse of the equalizing amplifier, An optical receiver having an identification circuit (300) for performing identification and reproduction with respect to the waveform of an output pulse of an equalizing amplifier at the timing of a clock output from the timing circuit, the optical receiver being connected to a subsequent stage of the optical receiver. In the error rate measurement unit (170),
In the error rate adjustment method of the optical receiver for measuring the error rate of the output signal of the optical receiver and setting the value of the error rate within a predetermined range, the error rate signal output from the error rate measurement unit (170) To output a signal for adjusting the multiplication factor of the light receiving element (100) and the gain of the equalizing amplifier (200) to an optimum value so that the value of the error rate is set within a predetermined range. In addition to the equalization amplifier, and outputs a signal for adjusting the discrimination level in the discrimination circuit (300) to an optimum value at ambient temperature, and adds the signal to the equalization amplifier, and the timing circuit (40
(0) outputs the signal for adjusting the phase of the timing clock output from (0) to the optimum value at ambient temperature and adds it to the timing circuit (130), and the increase of the light receiving element (100) at each ambient temperature. A storage unit (150) for storing the optimum adjustment value of the magnification and the gain of the equalizing amplifier (200), the optimum adjustment value of the discrimination level at each ambient temperature, and the optimum adjustment value of the phase of the timing clock is provided. The optical reception is characterized in that the value of the error rate is always automatically set to a predetermined range by reading and adjusting the data stored in the storage unit (150) at an arbitrary time during communication. Error rate adjustment method.