JP2012175228A - Light-receiving power monitor circuit, optical receiver, method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical receiver for accurately measuring light-receiving power corresponding to multiplication factor fluctuation of an avalanche photodiode.SOLUTION: A current corresponding to optical burst signals detected in an avalanche photodiode 14 is inputted from a current mirror circuit 15 to a current/voltage conversion circuit 20 and converted to a voltage. Of the voltage, one is applied to an analog/digital conversion circuit 22 to acquire a light-receiving power value Pp. The other is applied to a low-pass filter 30 and its low frequency component is applied to an analog/digital conversion circuit 32 to acquire an average light-receiving power value Prave. The light-receiving power value Pp and average light-receiving power value Prave are inputted to a control operation circuit 24, and the control operation circuit 24 corrects the value of the light receiving power value Pp using a correction coefficient k(Prave) corresponding to the latest average light-receiving power value set by a correction coefficient setting part 38.

Description

  The present invention relates to a received light power monitor circuit, an optical receiver, a method, and a program for receiving an optical burst signal transmitted in bursts, and more particularly, to a received light power monitor circuit, an optical receiver, a method, and a program for measuring the received power of an optical burst signal. Regarding the program.

  In recent years, as shown in FIG. 10, for example, an optical subscriber unit (ONU: Optical Line Unit) 104 to which a communication terminal device 102 installed in a subscriber's home 100 is connected, There is an access optical communication system that accesses an optical line termination (OLT) 106 provided in a station building on the side of a telecommunications carrier such as an Internet service provider via an optical fiber. In this access optical communication system, for example, a single optical fiber F, which is a transmission line connected to an optical line terminator, is branched into a plurality of optical fibers G by an optical splitter 108, and each optical fiber branched and connected Some G employ a PON (Passive Optical Network) system in which an optical subscriber unit is connected.

  An optical network unit (IP) network 112 and another communication network 114 are connected to the optical line terminating device 106 adopting the PON system as a higher-level communication network. It is possible to access the IP network 112 or the like via the user device 104, the optical splitter 108, and the optical line termination device 106. The optical line termination device 106 includes an optical module 120 having an optical transceiver function for transmitting and receiving information. The optical module 120 transmits an optical burst signal transmitted from the subscriber device 104 via an optical fiber. And an optical transmitter 124 for converting the main signal to be transmitted to the subscriber unit 104 into an optical burst signal and transmitting it to an optical fiber. . These transmission systems that use optical burst signals transmit the transmitted optical signals intermittently in units of burst cells, thereby reducing the effects of scattered light in the optical fiber transmission path and reflections at connection points such as optical splitters. This is a transmission method that prevents it from being received.

  Such an optical module 120 is provided with, for example, an avalanche photo-diode (APD) as a photoelectric conversion element that detects an optical burst signal. Avalanche photodiodes use avalanche multiplication that occurs when a high reverse bias voltage is applied, so the received optical burst signal is photoelectrically converted with high sensitivity, and the optical burst signal is detected well and converted into a current signal. Can be converted.

  By the way, in the PON system as described above, since a plurality of subscriber devices 104 are connected to the optical line termination device 106 via the optical splitter 108 having a passive configuration, the number of subscriber devices 104 connected, The light receiving intensity (light receiving power) of the optical burst signal received on the optical line terminating device 106 side varies greatly according to the connection distance between the subscriber unit 104 and the optical line terminating device 106. An optical power monitor circuit 126 that monitors and measures the received light power is provided in the optical line termination device 106. When the optical power monitor circuit 126 performs measurement, the power monitor value of the monitoring result is as described above. The problem of large fluctuations occurs. This power monitor value is used, for example, to measure the loss of the optical transmission line, and may be used to confirm the transmission state of the subscriber unit 104.

  A circuit for detecting the intensity of such an optical burst signal is disclosed in Patent Document 1, for example. In the burst optical receiver described in Patent Document 1, a current signal photoelectrically converted by an avalanche photodiode (APD) is input to a preamplifier, and the preamplifier converts the input current signal into a voltage signal. The intensity of the burst signal is determined by the level detection circuit, and the preamplifier gain and the APD multiplication factor are switched stepwise according to the intensity.

  As a burst optical receiver that uses the avalanche photodiode (APD) as described above and receives burst light, for example, there is a burst optical receiver described in Patent Document 2. This burst optical receiver includes an avalanche photodiode, a trans-impedance amplifier that converts a current signal into a voltage signal, amplifies and outputs the burst signal, a lamp voltage output low-pass filter that outputs an average voltage of the burst signal, a lamp A voltage output low-pass filter output (reference voltage) and a discriminator that amplifies the voltage difference between the burst signals.

  Here, FIG. 11 shows a related technique of a light reception power monitor circuit for measuring the light reception power of such an optical burst signal. As shown in the figure, a light receiving power monitor circuit 1 having a receiving function has a photodiode 2 that receives an optical burst signal, and a current signal corresponding to the received optical burst signal is a trans-impedance amplifier (TIA: Trans Impedance). Amplifier) 3.

  A feedback resistor R1 is connected in parallel to the input / output terminal of the transimpedance amplifier 3, and a current signal from the photodiode 2 is amplified with a gain corresponding to the value of the feedback resistor R1 and converted into a voltage signal. This voltage signal is applied to the input of a limiting amplifier (LIM: Limiting Amplifier) 3, is amplified by limiting to a preset limit voltage, and is output to the output S as a main signal. In this example, the received light power monitor circuit 1 includes the function of the optical receiver 124 shown in FIG.

  In FIG. 11, a current corresponding to the current flowing through the photodiode 2 is input from the current mirror circuit 5 to the current-voltage conversion circuit 6. The current-voltage conversion circuit 6 converts an input current into a voltage and outputs the voltage, and applies the converted voltage to an input of an analog / digital conversion circuit 7 connected to the output.

  This analog / digital conversion circuit 7 is a conversion circuit that converts an analog voltage signal appearing at its input into a digital value signal, and is triggered by a control signal input to the input I of the control circuit 8 from the outside. The optical burst signal is identified and converted into a digital value, and the converted digital signal is output. The output of the analog / digital conversion circuit 7 is connected to the control circuit 8.

  The control circuit 8 includes an internal memory 9 for temporarily storing data, and data indicating a digital voltage value converted by the analog / digital conversion circuit 7 is triggered by an input timing of a control signal given to the input I from the outside. The data is taken into a designated area of the internal memory 9. Data taken into the internal memory 9 is output from the memory access input / output terminal M.

JP 2009-218852 A JP 2010-226627 A

  However, for example, when an avalanche photodiode (APD) is applied to the photodiode 2 shown in FIG. 11, the multiplication factor (M value) of the avalanche photodiode depends on the received light power of the optical burst signal as described later. There is a problem that the accuracy of the received light power monitoring function deteriorates due to fluctuation.

  As a specific example, a general avalanche photodiode will be described. The bias voltage of the avalanche photodiode is set to a multiplication factor of about 10 (M = 10) under the condition that the received light power is small. However, when the received light power fluctuates under the same bias voltage condition and the received light power increases, the multiplication factor decreases. In this case, for example, when changing to a light input power condition of large input, a multiplication factor of 5 or less (M = 5 or less) may occur. In this way, the multiplication factor (M value) is about half or less despite the same bias voltage setting conditions, so that the light receiving sensitivity is lowered, and the light receiving power monitor value is also halved. As a result, an error of 3 [dB] or more was generated in the received light power monitor value, which caused the monitor accuracy to deteriorate.

(Object of invention)
The present invention has been made in order to solve the above-described problems of the related art, and is capable of receiving a light-receiving power monitor value with high accuracy corresponding to fluctuations in the multiplication factor (M value) of the photoelectric conversion element. It is an object of the present invention to provide a power monitor circuit, an optical receiver, a method, and a program.

  In order to achieve the above object, a light receiving power monitor circuit according to the present invention receives a light burst signal transmitted in bursts, multiplies it to convert it into a current signal, and converts it into a current signal. A light receiving power detection unit for detecting the light receiving power value of the optical burst signal based on the received current signal, and an average for detecting the average light receiving power value representing the average of the light receiving power value based on the current signal converted by the photoelectric conversion element A light reception power detection unit and a correction control unit that corrects an error in the light reception power value detected by the light reception power detection unit. The correction control unit includes a multiplication factor of the photoelectric conversion element and an average light reception power value of the optical burst signal. The correction coefficient corresponding to the average received light power is selected from the correction coefficients created and held in advance based on the relationship between the received light power and the received light power value is corrected based on the selected correction coefficient. Characterized in that it.

  Further, in order to achieve the above object, the monitoring method for a received light power monitor circuit according to the present invention receives the optical burst signal burst-transmitted from the subscriber unit, receives and multiplies the photoelectric conversion element, and performs photoelectric conversion. From this photoelectrically converted current signal, the received light power detection unit detects the received light power value of the optical burst signal (received power detection step), and from the current signal, the average received power value of the optical burst signal is detected by the average received light power detection unit. The control unit detects a correction coefficient corresponding to the average received light power from a correction coefficient that is detected (average received light power detection step) and stored in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value. In addition to the selection, the received light power value detected by the received light power detection unit is corrected based on the selected correction coefficient (correction processing step).

  In order to achieve the above object, the monitor program for the received light power monitor circuit according to the present invention receives the optical burst signal burst-transmitted from the subscriber unit, receives and multiplies the photoelectric conversion element, and performs photoelectric conversion. A function of detecting the light reception power value of the optical burst signal from the photoelectrically converted current signal, a function of detecting an average light reception power value of the optical burst signal from the current signal photoelectrically converted by the photoelectric conversion element, and photoelectric conversion Based on the relationship between the multiplication factor of the element and the average received light power value, a correction coefficient corresponding to the average received light power is selected from correction coefficients created and held in advance, and the received light power value is determined based on the selected correction coefficient. A correction function is provided, and each of these functions is realized by a computer.

  Since the present invention is configured as described above, an accurate received light power monitor value can be obtained in response to fluctuations in the multiplication factor (M value) of the photoelectric conversion element that receives and multiplies the optical burst signal and converts it into a current signal. It is possible to provide an excellent light receiving power monitor circuit, optical receiver, method, and program that can be obtained.

It is a block diagram which shows the structural example of the optical receiver in the 1st Embodiment of this invention. It is a graph which shows the characteristic of the multiplication factor (M value) which changes according to an average received light power value. It is a timing chart which shows the average light reception power value which changes according to the light reception power value of an optical burst signal, and the output current of an avalanche photodiode. It is a graph which shows the correction coefficient k which changes according to the magnitude of an average received light power value. It is a figure which shows an example of the memory area of the temporary memory part provided in the control arithmetic circuit in 1st Embodiment. 3 is a flowchart showing an operation of an optical power monitor circuit in the optical receiver in the first embodiment. It is a block diagram which shows the structural example of the optical receiver in the 2nd Embodiment of this invention. It is a block diagram which shows the structural example of the optical receiver in the 3rd Embodiment of this invention. It is a block diagram which shows the structural example of the optical receiver in the 4th Embodiment of this invention. It is a figure which shows the example of whole structure of the optical communication system in related technology. It is a block diagram which shows an example of the light reception power monitor circuit in related technology.

  A first embodiment of an optical receiver according to the present invention will be described below with reference to FIGS.

[First Embodiment]
As shown in FIG. 1, an optical receiver 10 according to the first embodiment is provided in a PON (Passive Optical Network) optical line terminator (OLT) and includes a plurality of subscriber devices ( This is an apparatus for receiving an optical burst signal (burst cell) intermittently transmitted from an ONU (Optical Line Unit) 11 through an optical fiber F to an optical line termination apparatus. As shown in the figure, the optical receiver 10 includes an optical receiving circuit 12 that receives an optical burst signal, and a received light power monitor circuit 13 that measures the received light power of the optical burst signal. In the figure, a plurality of subscriber devices 11 are represented by a single subscriber device 11.

  An avalanche photo diode (APD) 14 provided in the optical receiving circuit 12 detects an optical burst signal transmitted from a plurality of subscriber devices 11, and responds to the intensity of the detected optical burst signal. This is a photodetector that generates a current signal. The avalanche photodiode 14 is a photomultiplier photoelectric conversion element that multiplies a photocurrent by a multiplication factor (M value) corresponding to a reverse bias voltage. One output of the current mirror circuit 15 is connected to the cathode side of the avalanche photodiode 14, and a preset reverse bias voltage is applied to the cathode of the avalanche photodiode 14.

  The avalanche photodiode 14 has a characteristic that the multiplication factor decreases as the intensity of the received optical burst signal, that is, the value of the received light power increases. This is because it is affected by the internal resistance. An example of such characteristics is shown in FIG. This figure shows how the multiplication factor (M value) of the avalanche photodiode 14 changes in accordance with the change in the average received light power value obtained by averaging the received light power values of the optical burst signals transmitted in bursts. A characteristic curve 200 is shown. In this figure, the horizontal axis represents the average received light power value of the optical burst signal, and the vertical axis represents the multiplication factor (M value). As shown in the figure, the avalanche photodiode 14 has, for example, a multiplication factor (M value) of 10 when the average received light power value is small, and the multiplication factor (M value) decreases as the average received light power value increases. For example, it has a characteristic of decreasing to a multiplication factor of value 5.

  Further, in FIG. 1, a trans impedance amplifier (TIA) 16 is connected to the anode of the avalanche photodiode 14. A feedback resistor R is connected in parallel to the input / output terminal of the transformer impedance amplifier 16, and the transformer impedance amplifier 16 gains the current signal input from the avalanche photodiode 14 according to the resistance value of the feedback resistor R. This is a preamplifier circuit that amplifies the signal and converts it into a voltage signal.

  A limiting amplifier (LIM) 18 is connected to the output of the transformer impedance amplifier 16, and the limiting amplifier 18 converts the output signal of the transformer impedance amplifier 16 to a preset limit voltage. This is an amplitude limiting amplifier circuit that amplifies by limiting and outputs to the output S as a main signal. This main signal is processed by other processing circuits in an optical line termination device (OLT). The received light power monitor circuit 10 includes these avalanche photodiodes 14, a trans-impedance amplifier 16, and a limiting amplifier 18, and receives the optical burst signal and demodulates it into an electrical signal. Functional.

  The other received light power monitor circuit 13 is configured to measure the received light power indicating the signal intensity using a current signal corresponding to the optical burst signal detected by the avalanche photodiode 14 of the optical receiver 12. Has been. Specifically, one output of the current mirror circuit 15 is connected to the cathode of the avalanche photodiode 14, and the current mirror circuit 15 outputs a current corresponding to the current signal flowing through the avalanche photodiode 14 to the other output. The output is connected to the current-voltage conversion circuit 20. The current mirror circuit 15 in this embodiment also has a function of applying a reverse bias voltage to the cathode of the avalanche photodiode 14.

  The current-voltage conversion circuit 20 is a circuit that converts the current signal input from the current mirror circuit 15 into a voltage signal. The current-voltage conversion circuit 20 applies the converted voltage signal to the input of the analog / digital conversion circuit 22 connected to the output thereof.

  The analog / digital conversion circuit 22 (light reception power detection unit) holds the voltage signal appearing at the input at the input timing of the trigger signal given from the arithmetic control circuit 24 connected via the connection line T, and the hold This is a conversion circuit that converts a value into a digital value, detects this as a received light power value, and outputs it to the arithmetic control circuit 24. As described above, the voltage value of the light reception power is affected by the multiplication factor that varies according to the change in the average light reception power of the optical burst signal.

  This state is shown in FIG. 3, which shows the average received light power when the average received light power value of the optical burst signal is low and when it is high, and the output current of the avalanche photodiode (APD) 14. A timing chart is shown. As shown in the figure, when the average light receiving power is low, when the optical burst signal 302 to be measured is received by the avalanche photodiode 14 (see FIG. 1) following the optical burst signal 300 not to be measured, the avalanche photodiode 14 is received. Multiplies the optical burst signal by a multiplication factor corresponding to the set bias voltage, and outputs it as output currents 304 and 306, respectively. The average received light power value at this time is indicated by a broken line 308. In this case, a current generated at a desired multiplication factor is generated.

  On the other hand, when the optical burst signal 312 to be measured is received by the avalanche photodiode 14 (see FIG. 1) following the non-measurement optical burst signal 310 having a large optical burst signal reception power, the average received light power is high. As a result, the avalanche photodiode 14 multiplies the optical burst signal at a multiplication factor smaller than the multiplication factor corresponding to the set bias voltage, and outputs the resultant as output currents 314 and 316, respectively. . In this case, since the average received light power value 318 is increased and increased as compared with the above, the multiplication factor is reduced as shown in FIG. 2, and it is generated at a multiplication factor lower than the desired multiplication factor. An output current 316 is output from the avalanche photodiode 14.

  Further, in FIG. 1, the control arithmetic circuit 24 performs analog / digital conversion in order to cope with the output characteristics of the avalanche photodiode 14 in which the multiplication factor (M value) decreases as the average light receiving power of the optical burst signal increases. It has a function of correcting the error of the received light power value converted into a digital value by the circuit 22 based on the average received light power monitor value obtained by monitoring the average received light power of the optical burst signal.

  This average received light power monitor value is obtained by connecting the low-pass filter 30 branched and connected to the output of the current-voltage conversion circuit 20, and the analog / digital conversion circuit 32 (average received light power detection unit) connected to the output of the low-pass filter 30. It is generated after.

  The low-pass filter 30 is a low-pass filter that blocks a high-frequency component of a voltage signal (optical burst signal) applied from the output of the current-voltage conversion circuit 20 and allows a low-frequency component to pass. An average received light power value Pave averaged in amplitude is output.

  The analog / digital conversion circuit 32 is a conversion circuit that continuously detects the average received light power value Pave output from the low-pass filter 30 and sequentially converts it into a digital signal, and controls the average received light power value Pave of the converted digital value. The result is output to the arithmetic circuit 24 (correction control unit).

  The control arithmetic circuit 24 generates a trigger signal for controlling the timing of holding the input signal of the analog / digital conversion circuit 22 in accordance with a control signal given from another circuit in the optical line termination device; It has a function of capturing and temporarily storing the received light power value Pp acquired at the timing of the trigger signal and output from the analog / digital conversion circuit 22. Further, the control arithmetic circuit 24 takes in the average received light power value Pave sequentially output from the analog / digital conversion circuit 32 and stores it in a renewed manner, and the received light power value Pp that fluctuates according to the change in the average received light power. This is a main control unit that has an arithmetic processing function for calculating to a value corresponding to a preset multiplication factor and controls the operation of each unit of the optical receiver 10.

  Specifically, the control circuit 24 inputs a control signal supplied from the external circuit 25 of the received light power monitor circuit 13 to the input C, generates a trigger signal in response to the control signal, and generates the generated trigger signal in analog / digital. By outputting to the conversion circuit 22, it has a specific control function for specifying an optical burst signal to be measured. The control circuit 24 includes a temporary storage unit 34 for temporarily storing the acquired received light power value, the average received light power value, and a correction coefficient for correcting an error in the received light power value in a storage area designated in advance. .

  A configuration example of the storage area of the temporary storage unit 34 is shown in FIG. As shown in the figure, the storage area 500 of the temporary storage unit 34 is output from the storage area 502 for storing the received light power value Pp output from one analog / digital conversion circuit 22 and from the other analog / digital conversion circuit 32. A storage area 504 for storing the average received light power value Pave, a storage area 506 for storing the correction coefficient k (Prav) corresponding to each value of the average received light power value Pave, and a storage for temporarily storing the corrected received light power monitor value Region 508.

  In FIG. 1, the control arithmetic circuit 24 takes in the received light power value Pp specified by the output timing of the trigger signal to the analog / digital conversion circuit 22 from the analog / digital conversion circuit 22, and stores the data in the temporary storage unit 34. Temporarily stored in the storage area 502 (see FIG. 5). When the period of the optical burst signal of the received signal is shorter than the operation cycle of the control circuit 24, or when a long time is required until the data stored in the temporary storage unit 34 is taken out to the outside. As described above, a trigger signal is generated in response to a control signal from the external circuit 25 and an optical burst signal to be measured is specified.

  The control circuit 24 sequentially inputs the average received light power value Pave output from the analog / digital conversion circuit 32, and temporarily stores the input average received light power value Pave in the area 506 of the temporary storage unit 34 (see FIG. 5). To do.

  The control circuit 24 includes an arithmetic processing unit 36 for correcting the error of the received light power value Pp stored in each storage area of the temporary storage unit 34 based on the average received light power value Prav.

  Specifically, the arithmetic processing unit 36 corrects the received light power value Pp by multiplying the correction coefficient k (Prav) given from the correction coefficient setting unit 38 by the received light power value Pp. The correction coefficient k at this time is a correction coefficient corresponding to the latest average received light power Pave which is sequentially output from the analog / digital conversion circuit 32 and stored in the temporary storage unit 34, and this is expressed as a correction coefficient k (Prav). ing. Since the control circuit 24 has such a functional configuration, an error in the received light power value Pp can be corrected in accordance with the fluctuation even if the average received light power fluctuation occurs.

  The correction coefficient k is recorded in advance and stored in the memory circuit 40 connected to the control arithmetic circuit 24, and the stored correction coefficient k is read out to the correction coefficient setting unit 38. The correction coefficient setting unit 38 selects a correction coefficient k corresponding to the current average received light power Pave from among the correction coefficients k held in the memory circuit 40 and temporarily stores it in the designated storage area 506 of the temporary storage unit 34. The calculation processing unit 36 calculates the product of the set correction coefficient k (Prav) and the received light power value Pp by calculation.

That is, the arithmetic processing unit 36
(Equation 1)
Light reception power monitor value after correction = Pp × k (Prav)
Is calculated.

  The calculation result of the calculation processing unit 36, that is, the corrected received light power monitor value is temporarily stored in the designated storage area 508 of the temporary storage unit 34. In the present embodiment, the correction coefficient setting unit 38 reads the correction coefficient k corresponding to the current average received light power Pave from the memory circuit 40 and stores it in the storage area 506 of the temporary storage unit 34. The correction coefficient k of each average received light power recorded in the memory circuit 40 may be read from the memory circuit 40 and stored in another storage area of the temporary storage unit 34. In this case, the correction coefficient setting unit 38 may select the correction coefficient k corresponding to the current average received light power Pave from the correction coefficients stored in the other storage area of the temporary storage unit 34 and temporarily store it in the storage area 506.

  An example of the correction coefficient k is shown in FIG. In the figure, the horizontal axis represents the average received light power Pave, and the vertical axis represents the correction coefficient k. As shown in the figure, the correction coefficient k is a value of coefficient 1 at the portion where the average light reception power Pave is the smallest, and increases as the average light reception power Pave increases. For example, the correction coefficient k increases to the value 2. It is a characteristic. The correction coefficient k is determined based on the reciprocal of the multiplication factor that changes in accordance with the average received light power Pave shown in FIG. The arithmetic processing unit 36 multiplies the light reception power value Pp by such a correction coefficient k, whereby a light reception power monitor value corresponding to the case where the multiplication is performed at a constant multiplication factor can be obtained.

  The corrected received light power monitor value stored in the storage area 508 of the temporary storage unit 34 receives the memory access input / output terminal M from another circuit in the optical line termination device. The received light power monitor value is read from the memory access terminal M. The power monitor value output from the optical receiver 10 in this way is used, for example, to measure the loss of the optical transmission line, and is used to confirm the transmission state of the subscriber unit.

(Operation of optical receiver circuit and monitor operation of received light power monitor circuit)
Next, the operation of the optical receiver 10 in the first embodiment will be described. First, an optical burst signal burst-transmitted from a plurality of subscriber apparatuses 11 through an optical fiber F is detected by an avalanche photodiode 14, and a current signal corresponding to the detected optical burst signal is transmitted from the avalanche photodiode 14 to a transformer. Input to the impedance amplifier 16. In addition, a current signal corresponding to the current signal is generated by the current mirror circuit 15, and the generated current signal is input to the current-voltage conversion circuit 20 (FIG. 6: step S60 / current detection step).

  The current signal input to one of the transimpedance amplifiers 16 is amplified with a gain corresponding to the feedback resistor R and applied to the input of the limiting amplifier 18 as a voltage signal. This voltage signal is amplified by the limiting amplifier 18 with its amplitude limited, and the amplified voltage signal is output from the output S as the main signal.

  The current signal input to the other current-voltage conversion circuit 20 is converted into a voltage signal, and the converted voltage signal is applied to the input of the analog / digital conversion circuit 22 (FIG. 6: step S61 / current-voltage conversion processing step). ).

  The voltage signal applied to the input of the analog / digital conversion circuit 22 is held and a hold value is specified when a trigger signal is output from the arithmetic control circuit 24 (FIG. 6: Step S62 / received power specifying control step). ). The specified hold value is further converted into a digital value (FIG. 6: Step S63 / received power value digital conversion processing step). This digital value is taken into the arithmetic control circuit 24 as the received light power value Pp and stored in the storage area 502 of the temporary storage unit 34 (FIG. 6: Step S64 / received power value storage processing step).

  The voltage signal converted by the current-voltage conversion circuit 20 is applied to the input of the low-pass filter 30, and the low frequency component is applied to the input of the analog / digital conversion circuit 32 as an average received light power value (FIG. 6: FIG. 6). Step S65 / average received light power detection process).

  The average received light power value applied to the input of the analog / digital conversion circuit 32 is sequentially converted into a digital signal, and the converted received light power average value Prav is input to the control arithmetic circuit 24 (FIG. 6: Step S66 / Average). Received power value digital conversion process).

  The average received light power value Pave input to the control circuit 24 is temporarily stored in the area 504 of the temporary storage unit 34 (FIG. 6: Step S67 / received power average value storage processing step).

  When the received light power average value Pave is temporarily stored in the area 504, a correction coefficient k (Prav) corresponding to the current average received light power Pave is further selected by the correction coefficient setting unit 38 and temporarily stored in the storage area 506 ( FIG. 6: Step S68 / correction coefficient setting processing step).

  Next, the light receiving power value Pp stored in the area 502 and the correction coefficient k stored in the storage area 506 are multiplied by the arithmetic processing unit 36, and the product of these is calculated (FIG. 6: Step S69 / Arithmetic processing step).

  The calculation result is temporarily stored in the area 508 of the temporary storage unit 34 as a corrected received light power monitor value (FIG. 6: step S70 / storage process), and the held received light power monitor value is stored in the memory access input / output terminal. When M is accessed from the external circuit 25, it is read from the storage area 508 in response to this access and output from the memory access terminal M (FIG. 6: step S71 / output control step). In this way, a corrected received light power monitor value corrected according to the average received light power value is obtained.

  When these operations are continued, the above processing is repeated (FIG. 6: Step S60 to Step S72 / continuation determination step), and even when the average received light power value fluctuates, correction corresponding to the fluctuated average received light power value is performed. Based on the coefficient k, the error of the received light power value Pp is corrected, and the corrected received light power monitor value can be obtained with high accuracy. When not continuing, the entire processing operation is stopped.

(Effects of the first embodiment)
As described above, according to the power monitor circuit 13 in the optical receiver 10 of the first embodiment, the received light power Pp and the average received light power value Pave are acquired, respectively, and each is sent to the control arithmetic circuit 24. The correction coefficient k temporarily stored and corresponding to the average received light power value Prav is selected and set by the correction coefficient setting unit 38, and calculation processing of the received light power Pp and the correction coefficient k (Prav) is executed by the calculation processing unit 36. As a result, a corrected received light power monitor value corresponding to a preset multiplication factor is obtained. Therefore, the light receiving power of the optical burst signal can be measured with high accuracy.

[Second Embodiment]
Next, a second embodiment is shown in FIG. Referring to FIG. 2, another configuration example of the optical receiver 10 shown in FIG. 1 is shown.

  As shown in the figure, the optical receiver 70 in this embodiment includes a received light power monitor circuit 71 in which the low-pass filter 30 and the analog / digital conversion circuit 32 are removed from the configuration of the received light power monitor circuit 13 shown in FIG. . The control arithmetic circuit 74 of the light reception power monitor circuit 71 acquires the light reception power value Pp based on the output of one analog / digital conversion circuit 72, and the processing function of the low-pass filter 30 (see FIG. 1) is performed according to software processing. An average received light power value Pave is obtained by calculation.

  Other points are the same as those of the first embodiment shown in FIG. 1 and are therefore denoted by the same reference numerals, and different parts will be mainly described below.

  The analog / digital conversion circuit 72 connected to the output of the current / voltage conversion circuit 20 is a trigger that outputs a voltage signal appearing at the input from the arithmetic control circuit 74, as in the analog / digital conversion circuit 22 shown in FIG. It has a function of holding in response to a signal, converting the hold value into a digital value, and outputting this to the arithmetic control circuit 74 as a received light power value. Further, the analog / digital conversion circuit 72 holds the input voltage value in response to the trigger signal output from the arithmetic control circuit 74 and outputs the received light power value to the control circuit 74 in a period other than the period shown in FIG. Similar to the analog / digital conversion circuit 32 shown, the voltage signal appearing at the input is continuously converted into a digital signal sequentially, and the converted received light power value is sequentially output to the control arithmetic circuit 74. Based on the received light power value sequentially output from the analog / digital conversion circuit 72, the average received light power value is calculated by the control arithmetic processing circuit 74.

  In addition to the functional configuration of the control arithmetic circuit 24 shown in FIG. 1, the control arithmetic circuit 74 has an arithmetic processing function for calculating an average received light power value from the received light power value given from the analog / digital conversion circuit 72.

  Specifically, the control arithmetic circuit 74 includes an averaging processing unit 76 that calculates an average value of received light power values sequentially input. The averaging processing unit 76 has a calculation processing function for calculating a moving average of sequentially received light power values, and the averaged average received light power value is stored in the storage area 504 (see FIG. 5) of the temporary storage unit 34. Store in an updated manner.

  Using the average received light power value Pave obtained by the functional configuration of the control arithmetic circuit 74, the corresponding correction coefficient k and the received light power value Pp are multiplied by the arithmetic processing unit 36, and the result of the multiplication is corrected. The subsequent received light power monitor value is stored in the storage area 508 of the temporary storage unit 34. Other operations are the same as the operations of the optical receiver 10 in the first embodiment shown in FIG.

(Effect of 2nd Embodiment)
Since the arithmetic control circuit 74 has the functional configuration as described above, the received light power monitor circuit 71 in the optical receiver 70 according to the present embodiment has a diagram in addition to the effects of the first embodiment shown in FIG. Each configuration of the low-pass filter 30 and the analog / digital conversion circuit 32 shown in FIG. 1 can be reduced. Therefore, the light reception power monitor circuit can be configured with a small number of components, and the light reception power of the optical burst signal can be measured with high accuracy.

[Third Embodiment]
Next, a second embodiment of the optical receiver according to the present invention will be described with reference to FIG.

  As shown in the figure, the optical receiver 80 in the third embodiment removes the current mirror circuit 15 from the configuration of the received light power monitor circuit 10 shown in FIG. 1 and further includes a transformer provided in the optical receiver 12. The output of the impedance amplifier 16 is branched and connected to the input of the amplifier 82. A bias voltage supply circuit 84 for applying a reverse bias voltage to the cathode is connected to the cathode of the avalanche photodiode 14 instead of the current mirror circuit 15 (see FIG. 1). In the figure, the same reference numerals are assigned to the same components as those in the first embodiment shown in FIG.

  In the light reception power monitor circuit 81 of the third embodiment, the voltage signal (optical burst signal) that has been subjected to current / voltage conversion by the trans-impedance amplifier 16 in the optical reception circuit 12 is an amplifier in the light reception power monitor circuit 81. 82. The amplifier 82 is a circuit that amplifies the voltage signal applied to the input at an amplification factor suitable for the maximum input level of the analog / digital conversion circuit 22, and the amplified voltage signal is supplied to the analog / digital conversion circuit 22. Applied to the input and the input of the low-pass filter 30, respectively. Other configurations and operations thereof are the same as those of the first embodiment described above.

(Effect of the third embodiment)
According to the light reception power monitor circuit 81 of the third embodiment, the configuration is simplified as compared with the light reception power monitor circuit 10 of the first embodiment. Other functions and effects are the same as those of the first embodiment described above. Therefore, the light reception power monitor circuit can be simplified and the light reception power of the optical burst signal can be measured with high accuracy.

[Fourth Embodiment]
Next, a fourth embodiment is shown in FIG. Referring to FIG. 8, another configuration example of the optical receiver 80 shown in FIG. 8 is shown.

  As shown in the figure, the optical receiver 90 in the present configuration example has a light receiving power monitor circuit 91 in which the low pass filter 30 and the analog / digital conversion circuit 32 are removed from the structure of the light receiving power monitor circuit 81 shown in FIG. ing. In FIG. 9, the same components as those of the optical receiver 80 in the third embodiment shown in FIG. 8 are denoted by the same reference numerals, and the same components as those of the optical receiver 70 shown in FIG. The code | symbol is attached | subjected.

  The control arithmetic circuit 74 in the present embodiment is configured to acquire the light reception power value Pp and the average light reception power value Prav based on the output of one analog / digital conversion circuit 72. The control arithmetic circuit 74 has the same functional configuration as that of the control arithmetic circuit 74 shown in FIG. 7, and calculates the average received light power value Prav by calculating the processing function of the low-pass filter 30 (see FIG. 8) according to software processing. The operation for acquiring the same is also the same as that of the control arithmetic circuit 74 shown in FIG.

(Effect of the fourth embodiment)
With the functional configuration as described above, the optical receiver circuit 90 in the present configuration example has a low pass as well as the effect in the optical receiver 70 shown in FIG. 7 in addition to the effect in the third embodiment shown in FIG. There is an effect of reducing each configuration of the filter 30 and the analog / digital conversion circuit 32. Therefore, the light reception power monitor circuit can be configured with a small number of components, and the light reception power of the optical burst signal can be measured with high accuracy.

  Here, in the operations in the first and fourth embodiments described above, each execution content executed in each of the above steps may be configured as a program that causes a computer to function. In this case, the program may be recorded in a non-transitory recording medium such as a DVD (trademark), a CD (trademark), or a flash memory so as to be readable. In this case, the program is read from the recording medium by a computer and executed.

  About each embodiment mentioned above, when the new technical content is put together, it will become as the following additional remarks.

Here, a part or all of each of the above embodiments is summarized as a novel technique as follows, but the present invention is not necessarily limited thereto.
(Appendix 1)
A photoelectric conversion element that receives and multiplies an optical burst signal transmitted in burst and converts it into a current signal;
A light receiving power detector that detects a light receiving power value of the optical burst signal based on a current signal converted by the photoelectric conversion element;
An average received light power detection unit that detects an average received light power value that represents an average of the received light power values based on the current signal converted by the photoelectric conversion element;
A correction control unit for correcting an error of the received light power value detected by the received light power detection unit,
The correction control unit
A correction coefficient corresponding to the average received light power is selected from correction coefficients created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value of the optical burst signal. A received light power monitor circuit, wherein the received light power value is corrected based on the corrected correction coefficient.
(Appendix 2)
In the received light power monitor circuit according to attachment 1,
The correction control unit has a function of generating a trigger signal for specifying a detection timing of the optical burst signal to be measured, and the average received light power detection unit is generated from a current signal of the photoelectric conversion element. A current-voltage conversion circuit for converting a current into a voltage signal;
A received light power monitor circuit comprising: a received light power conversion circuit that holds the voltage signal according to the trigger signal and converts the held voltage signal into a digital value.
(Appendix 3)
In the received light power monitor circuit according to attachment 2,
The average received light power detection unit includes an averaging circuit that averages the amplitude of the received light power value to generate an average received light power value, and an average received light power conversion circuit that converts the average received light power value into a digital value. Received power monitor circuit characterized by
(Appendix 4)
In the received light power monitor circuit according to attachment 2,
The function of the average received light power detection unit is included as a function in the correction control unit,
The light receiving power conversion circuit has a function of sequentially converting the voltage signal into a digital value,
The correction control unit includes, as a function of the average received light power detection unit, an averaging processing unit that generates an average value by averaging amplitudes of digital values sequentially converted by the received light power conversion circuit. Received power monitor circuit.
(Appendix 5)
In the received light power monitor circuit according to attachment 1,
A trans-impedance amplifier that amplifies the current signal of the photoelectric conversion element with a gain corresponding to a feedback resistor and converts it into a voltage signal, and an amplifier circuit that amplifies the voltage signal converted by the trans-impedance amplifier While providing
The received light power detection circuit detects the voltage signal amplified by the amplifier circuit as the received light power value.
(Appendix 6)
An optical receiver comprising the light receiving power monitor circuit according to any one of appendices 1 to 5 in a receiving circuit that demodulates a main signal from a current signal converted by the photoelectric conversion element.
(Appendix 7)
The optical burst signal burst-transmitted from the subscriber unit is received by the photoelectric conversion element, multiplied and photoelectrically converted, and the received light power value of the optical burst signal is received by the received light power detection unit from the photoelectrically converted current signal. Detect (received power detection process),
From the current signal, an average received light power detection unit detects an average received light power value of the optical burst signal (average received light power detection step),
The control unit selects a correction coefficient corresponding to the average received light power from the correction coefficient created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value. A monitoring method for a received light power monitoring circuit, wherein the received light power value detected by the received light power detection unit is corrected based on a correction coefficient (correction processing step).
(Appendix 8)
A function of detecting a light receiving power value of the optical burst signal from the photoelectrically converted current signal, photoelectrically converted by receiving and multiplying the optical burst signal transmitted in burst from the subscriber unit,
A function of detecting an average received light power value of the optical burst signal from a current signal photoelectrically converted by the photoelectric conversion element;
And selecting a correction coefficient corresponding to the average received light power from correction coefficients created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value, and to the selected correction coefficient Based on the above, a function for correcting the received light power value is provided,
A monitor program for a received light power monitor circuit, wherein each of these functions is realized by a computer.

DESCRIPTION OF SYMBOLS 10 Optical receiver 11 Subscriber apparatus 12 Optical receiver circuit 13 Light reception power monitor circuit 14 Avalanche photodiode (photoelectric conversion element)
15 Current Mirror Circuit 16 Transimpedance Amplifier 18 Limiting Amplifier 20 Current / Voltage Conversion Circuit (Receiving Power Detection Unit, Current / Voltage Conversion Circuit)
22 Analog / digital conversion circuit (light reception power detector, light reception power conversion circuit)
24 arithmetic control circuit (correction control unit)
30 Low-pass filter (average received light power detector, averaging circuit)
32 Analog / digital conversion circuit (average received light power detection unit, average received light power conversion circuit)
34 Temporary storage unit 36 Arithmetic processing unit (correction control unit)
38 Correction coefficient setting unit (correction control unit)
40 Memory circuit

Claims (8)

A photoelectric conversion element that receives and multiplies an optical burst signal transmitted in burst and converts it into a current signal;
A light receiving power detector that detects a light receiving power value of the optical burst signal based on a current signal converted by the photoelectric conversion element;
An average received light power detection unit that detects an average received light power value that represents an average of the received light power values based on the current signal converted by the photoelectric conversion element;
A correction control unit for correcting an error of the received light power value detected by the received light power detection unit,
The correction control unit
A correction coefficient corresponding to the average received light power is selected from correction coefficients created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value of the optical burst signal. A received light power monitor circuit, wherein the received light power value is corrected based on the corrected correction coefficient. In the received light power monitor circuit according to claim 1,
The correction control unit has a function of generating a trigger signal for specifying a detection timing of the optical burst signal to be measured, and the average received light power detection unit is generated from a current signal of the photoelectric conversion element. A current-voltage conversion circuit for converting a current into a voltage signal;
A received light power monitor circuit comprising: a received light power conversion circuit that holds the voltage signal according to the trigger signal and converts the held voltage signal into a digital value. In the received light power monitor circuit according to claim 2,
The average received light power detection unit includes an averaging circuit that averages the amplitude of the received light power value to generate an average received light power value, and an average received light power conversion circuit that converts the average received light power value into a digital value. Received power monitor circuit characterized by In the received light power monitor circuit according to claim 2,
The function of the average received light power detection unit is included as a function in the correction control unit,
The light receiving power conversion circuit has a function of sequentially converting the voltage signal into a digital value,
The correction control unit includes, as a function of the average received light power detection unit, an averaging processing unit that generates an average value by averaging amplitudes of digital values sequentially converted by the received light power conversion circuit. Received power monitor circuit. In the received light power monitor circuit according to claim 1,
A trans-impedance amplifier that amplifies the current signal of the photoelectric conversion element with a gain corresponding to a feedback resistor and converts it into a voltage signal, and an amplifier circuit that amplifies the voltage signal converted by the trans-impedance amplifier While providing
The received light power detection circuit detects the voltage signal amplified by the amplifier circuit as the received light power value.   6. An optical receiver comprising the light receiving power monitor circuit according to claim 1 in a receiving circuit that demodulates a main signal from a current signal converted by the photoelectric conversion element. The optical burst signal burst-transmitted from the subscriber unit is received by the photoelectric conversion element, multiplied and photoelectrically converted, and the received light power value of the optical burst signal is received by the received light power detection unit from the photoelectrically converted current signal. Detect
From the current signal, the average received power value of the optical burst signal is detected by an average received power detector,
The control unit selects a correction coefficient corresponding to the average received light power from the correction coefficient created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value. A monitoring method for a received light power monitor circuit, wherein the received light power value detected by the received light power detection unit is corrected based on a correction coefficient. A function of detecting a light receiving power value of the optical burst signal from the photoelectrically converted current signal, photoelectrically converted by receiving and multiplying the optical burst signal transmitted in burst from the subscriber unit,
A function of detecting an average received light power value of the optical burst signal from a current signal photoelectrically converted by the photoelectric conversion element;
And selecting a correction coefficient corresponding to the average received light power from correction coefficients created and held in advance based on the relationship between the multiplication factor of the photoelectric conversion element and the average received light power value, and to the selected correction coefficient Based on the above, a function for correcting the received light power value is provided,
A monitor program for a received light power monitor circuit, wherein each of these functions is realized by a computer.

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