JP5218210B2 - Monitor circuit and optical receiver using the same - Google Patents

Description

  The present invention relates to a monitor circuit and an optical receiver using the monitor circuit, and more particularly to a monitor circuit for monitoring an optical signal propagated through an optical fiber for optical communication and an optical receiver using the monitor circuit.

Along with the dramatic increase in communication demand, the use of optical fibers in communication systems has increased the capacity, but it has always been confirmed that information is reliably transmitted via optical fibers. It is necessary to keep it.
In the field of optical communication, an optical receiver is used to convert an optical signal propagating through an optical fiber into an electric signal. In order to confirm that information is reliably transmitted through the optical fiber, in the optical receiver, the power level of the optical signal received with the optical fiber connected, that is, the optical reception level is normal. It must have a monitor function to check whether it is within the range.

The following method is disclosed as a monitor circuit in a conventional optical receiver.
That is, in the optical receiver, first, a positive voltage is applied to the light receiving element of the optical receiver from the power supply terminal, and the optical signal received by the light receiving element is converted into a current signal and then converted into a voltage signal by a transimpedance amplifier. Then, it is amplified through an amplifier and output as a data signal.
On the other hand, as a monitor circuit for monitoring the optical reception level of the optical signal received by the light receiving element, a current mirror circuit is interposed between a power supply terminal for applying a positive voltage to the light receiving element and the light receiving element, and one current mirror circuit is provided. A terminal is connected to the light receiving element, and a monitor current corresponding to the optical signal is output from the other terminal of the current mirror circuit. Based on this monitor current, it is confirmed whether the optical reception level is within a normal range.
At this time, the monitor circuit converts the monitor current from the current mirror circuit into a voltage through the monitor resistor, outputs the voltage to the monitor output terminal via the voltage follower circuit constituted by the operational amplifier, and measures the output voltage to thereby generate the optical signal. The input level is monitored.
However, when the signal strength of the optical signal input to the optical receiver is weak and sufficient current is not generated in the light receiving element, the potential difference generated in the monitor resistor approaches 0V as much as possible. The operating point may approach 0V as much as possible, and may deviate from the linear operating range of the operational amplifier.
To avoid this, add a diode between the operational amplifier output of the voltage follower circuit and the output of the feedback loop, and shift the operational amplifier output voltage by the diode forward voltage, resulting from the operational amplifier output voltage range This is a configuration that reduces errors (for example, Patent Document 1).

  Further, in a light intensity measuring device such as an optical power meter or an illuminometer, there is a problem that an error occurs in a measured value as the temperature changes because the photoelectric conversion characteristics of the photodiode have temperature dependence. For this reason, the voltage signal from the light receiving element is converted into a digital signal, and the digital signal from the light receiving element is corrected by calculating with an arithmetic circuit using a digital signal based on the output voltage of the temperature detector installed in the vicinity of the light receiving element. An example of obtaining the true light intensity is disclosed (for example, Patent Document 2).

  Further, in an optical measuring instrument that measures the white balance of a computer display or a TV, the photoelectric current of the photoelectric conversion unit is converted into a voltage by an operational amplifier, and the output data obtained by AD-converting the voltage value and the temperature of the photoelectric conversion unit are measured. The output current measured by the temperature sensor is converted into a voltage by an operational amplifier, and the temperature data obtained by AD conversion of the voltage value and the memory in which the temperature characteristic data of the light conversion unit is stored in advance are used to correct the temperature of the light output by the CPU. Examples of performing are disclosed (for example, Patent Document 3, page 158, lower left column to lower right column, or Patent Document 4, page 183, upper right column).

  Also, in a photoelectric conversion device used in a printing device such as a copying machine or a printer, or an FA (factory automation) device, a photocurrent received by a photodiode is converted into an operational amplifier and the output terminal of the operational amplifier and the inverse of the operational amplifier. In a configuration in which logarithmic compression is performed by a logarithmic compression unit configured by a diode interposed between the phase input terminal and the photodiode receives light information even when the light received by the photodiode is weak. If the S / N ratio of the input light is insufficient, the S / N ratio cannot be secured by logarithmically compressing the photocurrent, and sufficient amplification characteristics cannot be secured. An example of amplification and subsequent input to a logarithmic compression unit is disclosed (for example, paragraph number of Patent Document 5) [0021] - [0024]).

JP 2003-198279 A Akira Akai 62-16432 Japanese Patent Laid-Open No. 3-44525 JP-A-3-214029 JP 2006-294682 A

However, for example, in the monitor circuit disclosed in Patent Document 1, even if the output voltage of the operational amplifier is shifted by the forward voltage of the diode and the error due to the output voltage range of the operational amplifier can be reduced, the operational amplifier In some cases, it is not possible to avoid an error between the input voltage and the output voltage due to the input offset generated on the input side.
In general, in an operational amplifier, an offset voltage of about several mV is generated inside the operational amplifier. For this reason, even if the output voltage of the operational amplifier is shifted by the forward voltage of the diode, the signal strength of the optical signal input to the optical receiver is weak because of the offset voltage generated inside the operational amplifier. If sufficient current is not generated, there is a limit to the accuracy in monitoring whether the optical reception level is within the normal range. For this reason, there is a problem that it is difficult to monitor the optical signal accurately when the intensity of the optical signal is weak.

  The present invention has been made to solve the above problems, and a first object is to provide a simple configuration with high accuracy in a wide dynamic range from a weak signal power to a large power signal. A second object of the present invention is to provide an optical receiver that can monitor the optical signal level with high accuracy and can monitor the optical signal level in a wide dynamic range.

Monitor circuit according to the present invention, contact converts into an electric signal by receiving light signals, a light receiving element of which one end is connected to the signal output terminal, a first constant voltage source through a first constant resistance load And a second transistor connected to the first constant voltage source via a second constant resistance load , the first transistor and the second transistor being a current mirror. The first connection end of the current mirror circuit that is opposite to the first constant resistance load and the other end of the light receiving element are connected to each other through the first transistor. A first current mirror circuit that outputs a first monitor current corresponding to the output of the light receiving element from a second connection end of the current mirror circuit facing the two constant resistance loads, and a diode connected in a forward direction to each other. Da Is connected to a second constant voltage source having a first voltage lower than the constant voltage source via a diode, the first transistor via a third transistor and a third constant resistance load of the opposite polarity second And a fourth transistor having a polarity opposite to that of the second transistor. The third transistor and the fourth transistor constitute a current mirror circuit, and the third transistor is The first connection end of the current mirror circuit facing the diode is connected to the second connection end of the first current mirror circuit, and the third constant resistance load is opposed via the fourth transistor. from a second connection end of the current mirror circuit, a second current mirror which first monitor current from the second connection terminal of the first current mirror circuit outputs the second monitor current which is logarithmically converted A circuit, the second is connected to the second connection terminal of the current mirror circuit, a current-voltage conversion circuit for converting the output of the second current mirror circuit into a voltage signal, is connected to the current-voltage conversion circuit, a current A first A / D conversion circuit for converting the output of the voltage conversion circuit into a digital signal, a temperature detection unit disposed in the vicinity of the light receiving element and the second current mirror circuit, and an output of the temperature detection unit The second A / D conversion circuit for converting to a digital signal and the first and second A / D conversion circuits are connected. Based on the digital signal from the second A / D conversion circuit, the first A / D conversion circuit is connected. And an arithmetic unit that corrects and outputs the digital signal from the D conversion circuit.
An optical receiver according to the present invention also includes the monitor circuit, a transimpedance amplifier that converts an output current of a light receiving element of the monitor circuit into a voltage signal, and amplifies and outputs the output signal of the transimpedance amplifier. And an amplifier.

In the monitor circuit according to the present invention, the first monitor current output from the first current mirror circuit is logarithmically converted by the second current mirror circuit and level-shifted and output as the second monitor current. While facilitating connection to the current-voltage conversion circuit and the first A / D conversion circuit, the optical reception level can be accurately monitored in a wide dynamic range.
In addition, since the optical receiver according to the present invention includes a monitor circuit having a wide dynamic range, an optical receiver capable of accurately monitoring the optical signal level with a simple configuration can be configured.

1 is a circuit diagram of an optical receiver including a partial block diagram according to an embodiment of the present invention. FIG. It is a graph which shows the A / D converter output of a monitor circuit with respect to the average optical input power of the monitor circuit which concerns on Embodiment 1 of this invention. 1 is a circuit diagram of an optical receiver including a partial block diagram according to an embodiment of the present invention. FIG. 1 is a circuit diagram of an optical receiver including a partial block diagram according to an embodiment of the present invention. FIG. It is a graph which shows the A / D converter output of the monitor circuit with respect to the average optical input power of the monitor circuit which concerns on Embodiment 3 of this invention. 1 is a circuit diagram of an optical receiver including a partial block diagram according to an embodiment of the present invention. FIG. It is a graph which shows the relationship of the monitor current with respect to the average optical input power of the monitor circuit which concerns on this invention. It is a graph which shows the temperature characteristic of the monitor circuit which concerns on this invention. It is a graph which shows the temperature characteristic of the monitor circuit which concerns on this invention.

Embodiment 1 FIG.
In the field of optical communication, an optical signal of 10 Gbps is used as a signal for information transmission, and this optical signal is propagated through an optical fiber. An optical receiver for converting an optical signal into an electric signal is used at a place where the optical signal is converted into an electric signal in order to perform signal processing.
In the place where the normal optical signal is converted to the electrical signal, an optical fiber is connected to confirm that the optical signal is reliably transmitted separately from the main circuit that transmits the data signal. The monitor circuit has a monitor function for confirming whether the power level of the optical signal received by the optical receiver in the state, that is, the optical reception level is within a normal range.
FIG. 1 is a circuit diagram of an optical receiver including a partial block diagram according to an embodiment of the present invention. In addition, in each following figure, it shows that the same code | symbol is the same or equivalent.
In FIG. 1, the main circuit of the optical receiver 10 includes an avalanche photodiode (hereinafter referred to as APD) 12 as a light receiving element that receives an optical signal L from an optical fiber (not shown). A current _IPD is output, this optical signal current _IPD is converted into a voltage signal by the transimpedance circuit 14, further amplified by the amplifier 16, and output as a data signal from the data output terminal 18 to an electric circuit (not shown). The

On the other hand, the monitor circuit of the optical receiver 10 is configured as follows.
A first connection end 20 a of a previous stage current mirror circuit 20 as a first current mirror circuit is connected to the cathode of the APD 12. The second connection end 20b of the front-stage current mirror circuit 20 is connected to the first connection end 22a of the rear-stage current mirror circuit 22 as a second current mirror circuit. The second connection end 22 b of the rear-stage current mirror circuit 22 is connected to the current-voltage conversion circuit 24, and is connected to the A / D conversion circuit 26 via the current-voltage conversion circuit 24.
In the pre-stage current mirror circuit 20, a constant voltage source 20c as a first constant voltage source is connected to an emitter of a pnp-type first bipolar transistor 20e as a first transistor via a constant resistor 20d as a constant resistance load. Similarly, a constant voltage source 20c is connected to the emitter of a pnp-type second bipolar transistor 20g as a second transistor via a constant resistance 20f as a constant resistance load.
The base of the first bipolar transistor 20e and the base of the second bipolar transistor 20g are connected to each other and also connected to the collector of the first bipolar transistor 20e. Connected to the cathode.
Further, the collector of the second bipolar transistor 20 g is connected to the second connection end 20 b of the previous stage current mirror circuit 20. In the first embodiment, the constant voltage source 20c is, for example, 50V.

In the rear-stage current mirror circuit 22, a ground terminal 22c as a second constant voltage source is connected to a cathode of a diode 22d, and an anode of the diode 22d serves as an emitter of an npn-type first bipolar transistor 22e as a first transistor. The ground terminal 22c is connected to the emitter of an npn-type second bipolar transistor 22g as a second transistor via a constant resistance 22f as a constant resistance load.
The base of the first bipolar transistor 22e and the base of the second bipolar transistor 22g are connected to each other and also connected to the collector of the first bipolar transistor 22e. The current mirror circuit 20 is connected to the second connection end 20b.
The collector of the second bipolar transistor 22g is connected to the second connection end 22b of the rear-stage current mirror circuit 22.

In this embodiment, for example, the current-voltage conversion circuit 24 includes a constant voltage source 24a and a pull-up resistor 24b, and the second connection end 22b of the rear-stage current mirror circuit 22 is connected to the constant voltage source via the pull-up resistor 24b. The A / D converter circuit 26 is connected in series to the A / D converter circuit 26 having a known configuration via a pull-up resistor 24b connected in parallel.
In this embodiment, the voltage of the constant voltage source 24a is, for example, 3.3V.
The second constant voltage source of the rear-stage current mirror circuit 22 is the ground terminal 22c in the first embodiment, but is a constant voltage source having a lower voltage than the constant voltage source 20c that is the first constant voltage source. I just need it. However, when the current-voltage conversion circuit 24 is composed of the constant voltage source 24a and the pull-up resistor 24b as in the first embodiment, the second constant voltage source of the rear-stage current mirror circuit 22 is the constant voltage source. It must be lower than the voltage of 24a.

The diode 22d of the rear-stage current mirror circuit 22 has temperature characteristics, and the output current of the rear-stage current mirror circuit 22 is easily affected by the ambient temperature. Therefore, it may be difficult to accurately monitor the optical reception level without performing temperature compensation.
For this purpose, a temperature sensor 28 as a temperature detection unit is disposed in the vicinity of the rear-stage current mirror circuit 22. For example, a thermistor is used as the temperature sensor. The temperature sensor 28 is connected to an A / D conversion circuit 30 having a known configuration as a second A / D conversion circuit.
The A / D conversion circuit 26 for digitizing the monitor signal and the A / D conversion circuit 30 for digitizing the temperature signal are connected to a microprocessor (hereinafter referred to as MCU) 32 as an arithmetic unit, and perform temperature compensation. The monitor value of the received optical reception level is output from the MCU 32 and further output from the monitor signal output terminal 36.
Usually, the APD 12 is enclosed in a can package. Except for the APD 12, the transimpedance circuit 14 and the amplifier 16 constituting the main circuit of the optical receiver 10, the front-stage current mirror circuit 20, the rear-stage current mirror circuit 22 constituting the monitor circuit, the current-voltage conversion circuit 24, and the A / D conversion The circuit 26, the temperature sensor 28, the A / D conversion circuit 30, and the MCU 32 are disposed on the circuit board 34.
The APD 12 enclosed in the can package is engaged with a socket provided on the circuit board 34 by a lead electrode of the can package, and is connected to the main circuit and the monitor circuit on the circuit board 34 side.

Next, the operation of the optical receiver 10 will be described.
The first connection end 20a of the front stage current mirror circuit 20 is connected to the cathode of the APD 12 of the optical receiver 10, and a positive voltage based on the constant voltage source 20c of the front stage current mirror circuit 20 is applied to the cathode of the APD 12. . This APD 12 is receiving the signal light L propagated through the optical fiber, APD 12 outputs a light signal current I _PD. The optical signal current _IPD is converted into a voltage signal by the transimpedance circuit 14, further amplified by the amplifier 16, and output as a data signal from the data output terminal 18 to an electric circuit (not shown) for signal processing.

On the other hand, the first connecting end 20a to the APD12 optical signal current I _PD flows a constant resistance 20d of front stage current mirror circuit 20, level-shifted according to the value of the constant resistance 20f, the second connection end of the front stage current mirror circuit 20 20b first monitor current Imon1 level-shifted in response to the light signal current I _PD flows.
The first monitor current Imon1 flows through the first connection end 22a of the rear-stage current mirror circuit 22. The first monitor current Imon1 input to the first connection terminal 22a of the rear-stage current mirror circuit 22 is logarithmically converted due to the characteristic that the ON resistance increases when the current flowing through the diode 22d is small, and the collector of the second bipolar transistor 22g. Is output as a second monitor current Imon2 logarithmically converted from the second connection end 22b of the subsequent stage current mirror circuit 22 connected to.
The second monitor current Imon2 is voltage-converted by the pull-up resistor 24b of the current-voltage conversion circuit 24. The voltage-converted monitor signal is converted into a digital signal by the A / D conversion circuit 26 and input to the MCU 32.
The ambient temperature in the vicinity of the rear-stage current mirror circuit 22 is measured as a voltage value of the temperature signal by the temperature sensor 28, and this output is converted into a digital signal by the A / D conversion circuit 30 and input to the MCU 32.

The monitor signal input from the A / D conversion circuit 26 to the MCU 32 is a digitized monitor signal that has been logarithmically converted. Therefore, the monitor signal is calculated to be a value that is meaningful as a physical quantity indicating the optical reception level. To calculate. Next, a correction value is uniquely calculated from the digital signal based on the temperature measured by the temperature sensor 28, and the physical quantity indicating the light reception level previously obtained is corrected by this correction value, and monitored as a monitor output signal of the light reception level. The signal is output from the signal output terminal 36.
For example, assuming that the value of the monitor signal input from the A / D conversion circuit 26 is X and the physical quantity indicating the optical reception level is Y, the physical quantity Y is expressed by Expression (1).
Y = AX ⁿ + BX ⁿ⁻¹ + CX ⁿ⁻² +... + PX ² + QX + R (1)
Here, the coefficients A, B, C,..., P, Q, R are functions of temperature.
When equation (1) is used as a function with a relatively low-order term and the coefficients A, B, C,..., P, Q, R are expressed as constants or simple functions, The calculation formula can be stored in the internal memory of the MCU 32, and signal processing can be performed by H / W (hardware).

FIG. 2 is a graph showing the A / D converter output of the monitor circuit with respect to the average optical input power of the monitor circuit according to Embodiment 1 of the present invention.
In FIG. 2, the horizontal axis is the average optical input power Pin of the APD 12 and is indicated by the dBm value. The vertical axis represents the output of the A / D converter 26 and is represented by a digital value of 12-bit resolution display, and is represented by a decimal value ranging from a minimum value 0 to a maximum value 4095. Also in FIG. 5 to be described later, the vertical axis is indicated by the same digital value.
In FIG. 2, a curve a is an output of the A / D converter 26 in the monitor circuit according to the first embodiment shown in FIG. A curve b is a curve shown for comparison, and is an A / D converter output when the diode 22d is replaced with a simple constant resistance load in the rear-stage current mirror circuit 22 of FIG.

It is clear that the curve a, which is the output of the A / D converter of the monitor circuit according to the first embodiment, rises from the lower average optical input power Pin than the curve b and has a wide dynamic range. At the same time, the value of the A / D converter output is also high.
The starting point of the rise of the curve a depends on the identification voltage level of the A / D converter 26, but logarithmic conversion is performed on the subsequent stage current mirror circuit 22 to increase the input to the current-voltage conversion circuit 24. Since the input to the D converter 26 is increased, the discrimination voltage level of the A / D converter 26 can be exceeded even when the average optical input power Pin is low.

For example, as shown by the curve b, the diode 22d of the rear-stage current mirror circuit 22 is replaced with a simple constant resistance load, and the second connection from the second connection end 22b of the rear-stage current mirror circuit 22 even when logarithmic conversion is not performed. The monitor current Imon2 can be increased.
That is, the resistance value of the constant resistance 20f is made smaller than the resistance value of the constant resistance 20d of the front-stage current mirror circuit 20, and the resistance value of the constant resistance 22f is smaller than the resistance value of the constant resistance replaced by the diode 22d of the rear-stage current mirror circuit 22. If the value is decreased, the second monitor current Imon2 can be increased. However, if this is done, the power consumption of the current mirror circuits at the front and rear stages will increase.
Thus, without having a logarithmic conversion function in front and rear stage current mirror circuit, when a large second monitor current Imon2, when the optical signal current I _PD of APD12 was increased, the constant voltage source 20c The current flowing into the current mirror circuit 20 from the current increases and exceeds the maximum current of the booster circuit of the constant voltage source 20c. Therefore, when a constant resistor is simply used as all the resistive loads of the current mirror circuit, the dynamic range cannot be widened.

  Alternatively, it is possible to increase the number of bits of the A / D converter 26 and read an area where the average optical input power is small, but such an A / D converter is expensive and increases the number of bits. However, when the input to the A / D converter is small, the reading reliability may not be stable.

On the other hand, as shown in the first embodiment, the diode 22d of the rear stage current mirror circuit 22 in response to the light signal current I _PD of APD 12, the resistance value is changed, that is a characteristic that the voltage across the diode 22d varies For this reason, the amplification factor is high in the region where the optical signal current _IPD is small. On the other hand, even if the optical signal current _IPD increases, the power consumption of the current mirror circuit does not increase so much. Therefore, in the monitor circuit of the optical receiver 10, it is possible to realize a monitor circuit having a wide dynamic range with low noise and low power consumption without increasing the resolution of the A / D converter with a simple circuit configuration. it can.
Furthermore, by using a current mirror circuit for the circuit that performs logarithmic conversion, it is possible to increase the passband of the main signal in the main circuit, and to perform a higher-speed receiving operation as an optical receiver.

  As described above, the monitor circuit according to the present invention includes a light receiving element that receives an optical signal and converts it into an electrical signal, and the first and second connected to the first constant voltage source through the constant resistance load. And a first connection end and a second connection end, the first connection end is connected to the light receiving element, and a first monitor current corresponding to the output of the light receiving element is supplied from the second connection end. A first current mirror circuit for output, a first transistor connected to a second constant voltage source having a voltage lower than that of the first constant voltage source via a diode, and a second constant voltage via a constant resistance load. A second transistor connected to the voltage source, a first connection end on the first transistor side, and a second connection end on the second transistor side, and a first current mirror at the first connection end The first monitor current from the circuit is input, and the first monitor current is input from the second connection end. A second current mirror circuit that outputs a second monitor current obtained by logarithmically converting the current, and a current-voltage conversion that is connected to the second current mirror circuit and converts the output of the second current mirror circuit into a voltage signal A first A / D conversion circuit connected to the circuit and the current-voltage conversion circuit and converting the output of the current-voltage conversion circuit into a digital signal; and a light receiving element and a second current mirror circuit. The second A / D converter is connected to the temperature detector, the second A / D converter circuit that converts the output of the temperature detector into a digital signal, and the first and second A / D converter circuits. And an arithmetic unit that corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the circuit.

With this configuration, the first monitor current output from the first current mirror circuit is logarithmically converted by the second current mirror circuit and level-shifted and output as the second monitor current. Since the connection to the first A / D conversion circuit is facilitated and processing is performed in the calculation unit in consideration of the temperature of the temperature detection unit, the optical reception level can be accurately monitored in a wide dynamic range.
As a result, it has a simple circuit configuration, low noise, low power consumption, a wide dynamic range area, and a monitor circuit that can output a monitor signal at an optical reception level with high accuracy. An optical receiver capable of receiving operation can be configured.

Embodiment 2. FIG.
FIG. 3 is a circuit diagram of an optical receiver including a partial block diagram according to one embodiment of the present invention.
The optical receiver 40 shown in FIG. 3 is different from the optical receiver 10 according to the first embodiment in that the optical receiver 10 has two stages of current mirror circuits, and the subsequent stage current mirror circuit 22 performs logarithmic conversion. In contrast, the optical receiver 40 has only one stage of the current mirror circuit, and the current mirror circuit 42 has a logarithmic conversion function.
Since the first connection end 42a of the current mirror circuit 42 is connected to the cathode of the APD 12, and the second connection end 42b of the current mirror circuit 42 is connected to the current-voltage conversion circuit, one end of the output conversion circuit 44 is grounded. This is configured by a pull-down resistor 44a. Other configurations are the same as those according to the first embodiment shown in FIG.

In FIG. 3, in the current mirror circuit 42, a constant voltage source 42c as a first constant voltage source is connected to an anode of a diode 42d, and a cathode of the diode 42d is a pnp-type first bipolar transistor 42e as a first transistor. On the other hand, a constant voltage source 42c is connected to the emitter of a pnp-type second bipolar transistor 42g as a second transistor through a constant resistance 42f as a constant resistance load.
The base of the first bipolar transistor 42e and the base of the second bipolar transistor 42g are connected to each other and are also connected to the collector of the first bipolar transistor 42e to serve as the first connection terminal 42a of the current mirror circuit 42, and become the cathode of the APD 12. It is connected to the.
The collector of the second bipolar transistor 42g is connected to the second connection end 42b of the current mirror circuit 42.

Note that this embodiment is effective when a sufficient monitor gain can be obtained with one stage of the current mirror, or when a space-saving small circuit is realized by reducing the number of component mounting points.
In a current mirror circuit configured only by a resistance ratio that does not use a diode, the maximum output current of the power supply 20c is limited. That is, in the case of a boosted voltage, the maximum is 2 mA, and the resistance ratio of the constant resistances 20d and 20f is 1: 1. I have to make it. In this case, a two-stage current mirror circuit is inevitably required to ensure the gain of the monitor current. If the current mirror circuit system using the point diode is used, a gain can be secured efficiently with a single stage current mirror circuit, and high-precision monitoring becomes possible.
The constant voltage source 42c is lower than 50V in the first embodiment.
For example, in this embodiment, the current-voltage conversion circuit 44 includes a pull-down resistor 44a connected to the ground terminal. The second connection terminal 42b of the current mirror circuit 42 is connected to the ground terminal in series via a pull-down resistor 44a, and is connected to the A / D conversion circuit 26 via a parallel-connected pull-down resistor.

Next, the operation of the optical receiver 40 will be described.
The first connection terminal 42 a of the current mirror circuit 42 is connected to the cathode of the APD 12 of the optical receiver 40, and a positive voltage based on the constant voltage source 42 c of the current mirror circuit 42 is applied to the cathode of the APD 12.
This APD 12 is receiving the signal light L propagated through the optical fiber, APD 12 outputs a light signal current I _PD. The optical signal current _IPD is converted into a voltage signal by the transimpedance circuit 14, further amplified by the amplifier 16, and output as a data signal from the data output terminal 18 to an electric circuit (not shown) for signal processing.

On the other hand, the optical signal current _IPD flows through the first connection end 42 a of the current mirror circuit 42. The first bipolar transistor 42e whose collector is connected to the first connection end 42a has its emitter connected to the cathode of the diode 42d and is connected to the constant voltage source 42c via this diode 22d, while the second bipolar transistor since 42g is connected to a constant voltage source 42c through a constant resistor 42f, it varies the resistance of the current value by the diode 42d of the optical signal current I _PD, oN resistance increases and that is the current through the diode 42d is small the characteristic that, in response to the light signal current I _PD flowing through the first connecting end 42a of the current mirror circuit 42, the second connecting end 42b connected to the collector of the second bipolar transistor 42 g, corresponding to an optical signal current IPD The first monitor current Imon1 logarithmically converted is output.
The first monitor current Imon1 is voltage-converted by the pull-down resistor 44b of the current-voltage conversion circuit 44. The voltage-converted monitor signal is converted into a digital signal by the A / D conversion circuit 26 and input to the MCU 32.
Subsequent calculation of the monitor signal and temperature compensation measured by the temperature sensor are performed by the same method as described in the first embodiment.

Further, the tendency of the A / D converter output of the monitor circuit with respect to the average optical input power of the monitor circuit in the optical receiver 40 shows the same tendency as the curve a in FIG. Has an effect. That is, in the monitor circuit of the optical receiver 40, it is possible to realize a monitor circuit having a wide dynamic range with low noise and low power consumption without increasing the resolution of the A / D converter with a simple circuit configuration. it can.
In addition, it is possible to increase the passband of the main signal in the main circuit, and it is possible to perform a higher-speed receiving operation as an optical receiver.

  As described above, the monitor circuit according to the present invention includes the first transistor connected to the first constant voltage source via the diode and the second transistor connected to the first constant voltage source via the constant resistance load. Having a first connection end on the first transistor side and a second connection end on the second transistor side, the first connection end being connected to the light receiving element, and receiving light from the second connection end A first current mirror circuit corresponding to the output of the element and outputting a logarithmically converted first monitor current and the first current mirror circuit are connected, and the output of the first current mirror circuit is used as a voltage signal. A current-voltage conversion circuit for conversion, a first A / D conversion circuit connected to the current-voltage conversion circuit for converting the output of the current-voltage conversion circuit into a digital signal, and the proximity of the light receiving element and the first current mirror circuit Arranged A temperature detection unit, a second A / D conversion circuit that converts an output of the temperature detection unit into a digital signal, and a first and second A / D conversion circuit, and a second A / D conversion circuit And an arithmetic unit that corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the first A / D converter.

With this configuration, when the drive voltage of the light receiving element may be a relatively low voltage, the current mirror circuit is logarithmically converted by the current mirror circuit and input as the first monitor current, and is connected to the first A / D converter circuit. Since the processing is performed in the calculation unit in consideration of the temperature of the temperature detection unit, the optical reception level can be accurately monitored in a wide dynamic range.
As a result, when the drive voltage of the light receiving element may be a relatively low voltage, a simple circuit configuration, low noise, low power consumption, a wide dynamic range area, and a signal with an optical reception level with high accuracy. Therefore, an optical receiver having a monitor circuit capable of outputting a high-speed signal and capable of performing a high-speed reception operation can be configured.

Embodiment 3 FIG.
FIG. 4 is a circuit diagram of an optical receiver including a partial block diagram according to one embodiment of the present invention.
The optical receiver 50 shown in FIG. 4 further includes the output of the current mirror circuit 42 of the optical receiver 40 of the second embodiment and a subsequent stage current mirror having a logarithmic conversion function similar to that shown in the first embodiment. It is configured to input to the circuit 22.
That is, the first connection end 42 a of the previous stage current mirror circuit 42 as the first current mirror circuit is connected to the cathode of the APD 12. The second connection end 42b of the front-stage current mirror circuit 42 is connected to the first connection end 22a of the rear-stage current mirror circuit 22 as a second current mirror circuit. The second connection end 22 b of the rear-stage current mirror circuit 22 is connected to the current-voltage conversion circuit 24, and is connected to the A / D conversion circuit 26 via the current-voltage conversion circuit 24.

However, in the case of the optical receiver 50, when the driving voltage of the light receiving element 12 is higher than that of the current-voltage conversion circuit 24 and the A / D conversion circuit 26 in the subsequent stage, the constant voltage source 42c is used in the second embodiment. Higher voltage, for example 50V.
Unlike the case of the optical receiver 50 according to the second embodiment, the current-voltage conversion circuit 24 includes, for example, a constant voltage source 24a and a pull-up resistor 24b similar to those in the first embodiment. The voltage of the constant voltage source 24a is, for example, 3.3V.

In FIG. 4, in the previous stage current mirror circuit 42, a constant voltage source 42c as a first constant voltage source is connected to an anode of a diode 42d, and a cathode of the diode 42d is a pnp-type first bipolar transistor as a first transistor. The constant voltage source 42c is connected to the emitter of a pnp-type second bipolar transistor 42g as a second transistor via a constant resistance 42f as a constant resistance load.
The base of the first bipolar transistor 42e and the base of the second bipolar transistor 42g are connected to each other and also connected to the collector of the first bipolar transistor 42e, and become the first connection end 42a of the previous stage current mirror circuit 42. Connected to the cathode. The collector of the second bipolar transistor 42g is connected to the second connection end 42b of the previous stage current mirror circuit 42.

In the rear-stage current mirror circuit 22, a ground terminal 22c as a second constant voltage source is connected to a cathode of a diode 22d, and an anode of the diode 22d serves as an emitter of an npn-type first bipolar transistor 22e as a first transistor. A ground terminal 22c as a second constant voltage source is connected to an emitter of an npn-type second bipolar transistor 22g as a second transistor via a constant resistance 22f as a constant resistance load.
The base of the first bipolar transistor 22e and the base of the second bipolar transistor 22g are connected to each other and are also connected to the collector of the first bipolar transistor 22e to form the first connection end 22a of the rear-stage current mirror circuit 22, thereby The mirror circuit 42 is connected to the second connection end 42b.
The collector of the second bipolar transistor 22g is connected to the second connection end 22b of the rear-stage current mirror circuit 22.

The current-voltage conversion circuit 24 includes, for example, a constant voltage source 24a and a pull-up resistor 24b, and the second connection end 22b of the rear stage current mirror circuit 22 is connected in series to the constant voltage source 24a via the pull-up resistor 24b. At the same time, it is connected to an A / D conversion circuit 26 having a known configuration via a pull-up resistor 24b connected in parallel.
Other configurations are the same as those of the optical receiver 10 of the first embodiment and the optical receiver 40 of the second embodiment.

Next, the operation of the optical receiver 50 will be described.
The first connection end 42a of the previous-stage current mirror circuit 42 is connected to the cathode of the APD 12 of the optical receiver 40, and a positive voltage based on the constant voltage source 42c of the previous-stage current mirror circuit 42 is applied to the cathode of the APD 12. .
This APD 12 is receiving the signal light L propagated through the optical fiber, APD 12 outputs a light signal current I _PD. The optical signal current _IPD is converted into a voltage signal by the transimpedance circuit 14, further amplified by the amplifier 16, and output as a data signal from the data output terminal 18 to an electric circuit (not shown) for signal processing.

On the other hand, the optical signal current _IPD flows through the first connection end 42 a of the previous stage current mirror circuit 42. The first bipolar transistor 42e whose collector is connected to the first connection end 42a has its emitter connected to the cathode of the diode 42d and is connected to the constant voltage source 42c via this diode 22d, while the second bipolar transistor 42g is connected to a constant voltage source 42c through a constant resistor 42f.
Therefore to resistance change of the diode 42d by the current value of the light signal current I _PD, i.e. by the characteristics of the current flowing through the diode 42d is small, the ON resistance increases, through the first connecting end 42a of the front stage current mirror circuit 42 in response to the light signal current I _PD, a second connection end 42b connected to the collector of the second bipolar transistor 42 g, first monitor current Imon1 the first optical signal current I _PD is logarithmically converted is output.

The first monitor current Imon1 flows through the first connection end 22a of the rear-stage current mirror circuit 22. The emitter of the first bipolar transistor 22e connected to the collector connected to the first connection end 22a is connected to the anode of the diode 22d and grounded via the diode 22d, while the second bipolar transistor 22g Since it is grounded via the constant resistor 22f, the first monitor current Imon1 input to the first connection end 22a of the rear-stage current mirror circuit 22 has a characteristic that the ON resistance increases when the current flowing through the diode 22d is small. The logarithmic conversion is again performed by.
For this reason, the second monitor current Imon2 obtained by further logarithmically converting the first monitor current Imon1 is output from the second connection end 22b of the post-stage current mirror circuit 22 connected to the collector of the second bipolar transistor 22g.
The second monitor current Imon2 is voltage-converted by the pull-up resistor 24b of the current-voltage conversion circuit 24, and the voltage-converted monitor signal is converted into a digital signal by the A / D conversion circuit 26 and input to the MCU 32.
Subsequent calculation of the monitor signal and temperature compensation measured by the temperature sensor are performed by the same method as described in the first embodiment.

FIG. 5 is a graph showing the A / D converter output of the monitor circuit with respect to the average optical input power of the monitor circuit according to Embodiment 3 of the present invention.
In FIG. 5, the horizontal axis represents the average optical input power Pin of the APD 12 by dBm. The vertical axis is the output of the A / D converter 26, and the unit is mV.
A curve c is an output of the A / D converter 26 in the monitor circuit of the optical receiver 50 according to the third embodiment shown in FIG. A curve a is an output of the A / D converter 26 in the monitor circuit of the optical receiver 10 of the first embodiment shown for comparison.

The curve c, which is the output of the A / D converter of the monitor circuit according to the third embodiment compared to the curve a of the first embodiment, is subjected to the logarithmic conversion of the former stage current mirror circuit 42 and the latter stage current mirror circuit 22 again. Therefore, it is clear that the curve rises from a lower average optical input power Pin, and that the monitor circuit of the optical receiver 50 has a wider dynamic range than the monitor circuit of the optical receiver 10, and at the same time, A The value of the / D converter output is also high.
Therefore, the monitor circuit of the optical receiver 50 according to the third embodiment can realize a wider dynamic range in addition to the effects of the optical receiver 10 according to the first embodiment and the optical receiver 40 according to the second embodiment. .
In the third embodiment, by connecting a predetermined resistance in series between the cathode of the diode 22d of the rear-stage current mirror circuit 22 and the ground terminal, in the region of the high average optical input power Pin in FIG. The tendency for the A / D converter output of the curve c to be saturated can be reduced.

  As described above, the monitor circuit according to the present invention includes the first transistor connected to the first constant voltage source via the diode and the second transistor connected to the first constant voltage source via the constant resistance load. Having a first connection end on the first transistor side and a second connection end on the second transistor side, the first connection end being connected to the light receiving element, and receiving light from the second connection end A first current mirror circuit corresponding to the output of the element and outputting a logarithmically converted first monitor current and the first current mirror circuit are connected, and the output of the first current mirror circuit is used as a voltage signal. A current-voltage conversion circuit for conversion, a first A / D conversion circuit connected to the current-voltage conversion circuit for converting the output of the current-voltage conversion circuit into a digital signal, and the proximity of the light receiving element and the first current mirror circuit Arranged A temperature detection unit, a second A / D conversion circuit that converts an output of the temperature detection unit into a digital signal, and a first and second A / D conversion circuit, and a second A / D conversion circuit And an arithmetic unit that corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the first constant voltage source, and has a second constant voltage lower than that of the first constant voltage source via the diode. The first transistor connected to the voltage source, the second transistor connected to the second constant voltage source via the constant resistance load, the first connection end on the first transistor side, and the second transistor side And a second current mirror circuit having a second connection end, the first current mirror circuit being connected to the current-voltage conversion circuit via the second current mirror circuit, and the first current mirror A second current current from the circuit The first monitor current input to the first connection end of the circuit is further logarithmically converted and output as a second monitor current from the second connection end of the second current mirror circuit to the current-voltage conversion circuit. Is.

With this configuration, the first monitor current logarithmically converted and output in the first current mirror circuit is logarithmically converted again by the second current mirror circuit and level-shifted and output as the second monitor current. The connection to the voltage conversion circuit and the first A / D conversion circuit is facilitated, and the calculation unit is processed in consideration of the temperature of the temperature detection unit, so the optical reception level is accurately monitored in a wide dynamic range. be able to.
As a result, it has a simple circuit configuration, low noise, low power consumption, a wide dynamic range area, and a monitor circuit that can output optical reception level signals with high accuracy and high speed. An optical receiver capable of receiving operation can be configured.

  In the first, second, and third embodiments described above, the constant resistance at a position symmetrical to the diode of the current mirror circuit having the logarithmic conversion function, that is, the constant resistance of the subsequent stage current mirror circuit 22 of the first embodiment. 22f, the constant resistance 42f of the current mirror circuit 42 in the second embodiment, the constant resistance 42f of the front-stage current mirror circuit 42 in the third embodiment, and the constant resistance 22f of the rear-stage current mirror circuit 22 can be adjusted. By doing so, the gain of the input / output characteristic of the photocurrent monitor, that is, the gradient can be finely adjusted, and the characteristics of the diodes at the symmetrical positions of these resistors, that is, the diode 22d and the diode 42d, can be obtained. It becomes possible to eliminate the variation.

Further, by applying a resistance having a temperature coefficient such as a thermistor or a posistor to these constant resistances, simple temperature compensation can be realized only by H / W (hardware).
In Embodiments 1 and 2, and 3 of the embodiment, the main circuit of each of the optical receiver converts into a voltage signal a light signal current I _PD than APD12 by the transimpedance circuit 14, as a data signal and further amplified by the amplifier 16 The data is output from the data output terminal 18 to the electric circuit. An identification / reproduction circuit for separating the data signal and the clock signal is further provided after the amplifier 16 of the main circuit, and the information of the optical signal current _IPD is separated into the data signal and the clock signal and output from the data output terminal 18. May be.
Furthermore, in the first, second, and third embodiments, each optical receiver can be reduced in circuit scale and digitized, leading to a reduction in energy consumption. Furthermore, since the number of parts is reduced and power consumption is reduced, the environmental load at each stage in the product life cycle is reduced.

Embodiment 4 FIG.
FIG. 6 is a circuit diagram of an optical receiver including a partial block diagram according to one embodiment of the present invention.
An optical receiver 60 in FIG. 6 is obtained by connecting an external memory 62 as a memory to the MCU 32 in the optical receiver 50 of the third embodiment. In this embodiment, the optical receiver 50 is described as an example. However, an external memory 62 as a memory is connected to the MCU 32 of the optical receiver 10 of the first embodiment or the optical receiver 40 of the second embodiment. But you can.
The external memory 62 stores an input light intensity monitor table and a temperature compensation table in advance.

As described above, assuming that the value of the monitor signal input from the A / D conversion circuit 26 is X and the physical quantity indicating the optical reception level is Y, the physical quantity Y is expressed by Expression (1).
Y = AX ⁿ + BX ⁿ⁻¹ + CX ⁿ⁻² +... + PX ² + QX + R (1)
Here, the coefficients A, B, C,..., P, Q, R are functions of temperature.
In order to process the monitor signal with higher accuracy, the equation (1) becomes a high-order polynomial, and the functions of the coefficients A, B, C,..., P, Q, R also become higher-order equations. I must. In this case, it is easier to store and process the physical quantity Y corresponding to X as the monitor signal value in the external memory 62 in the form of a numerical value as the input light intensity monitor table, and to perform the process quickly. Can do. Similarly, in the temperature compensation, the compensation value based on the temperature measured by the temperature sensor 28 is stored in advance as a temperature compensation table in the external memory 62 as a numerical value, and the processing is simple, and the processing can be performed quickly.

Therefore, in the optical receiver 60 according to this embodiment, in addition to the effects of the optical receivers of the first, second, and third embodiments described above, the influence of the ambient temperature is reduced, and high-precision light is obtained. A reception level signal can be output.
That is, in the optical receiver according to this embodiment, a simple monitor circuit can output a signal with a high-accuracy optical reception level in a wide dynamic range region with low noise and low power consumption. it can.

As described above, the monitor circuit according to the present invention is connected to the arithmetic unit of the monitor circuit according to the present invention which has already been described, and the first current mirror circuit, the second current mirror circuit, or the first and second current circuits. A memory in which the temperature coefficient data of the diode arranged in the current mirror circuit is further stored, and the current coefficient of the monitor current is corrected by calculation using the temperature coefficient data of the memory.
With this configuration, it is possible to further reduce the influence of the ambient temperature and output a signal with a high-accuracy optical reception level.
As a result, it has a simple circuit configuration, low noise, low power consumption, a wide dynamic range area, and a monitor circuit that can output a signal with a high-accuracy optical reception level. An optical receiver capable of receiving operation can be configured.
The first to third embodiments will be described using theoretical formulas.
In the case of a current mirror circuit using a constant resistance, if the average optical input power P _in [dBm], the photoelectric conversion efficiency R “A / W” of the light receiving element, and the photomultiplier gain M when using the APD, the photocurrent I _pd [mA] The output current I _mon1 of the first-stage current mirror circuit and the output current I _mon2 [mA] of the second-stage current mirror circuit are expressed by Equations (2), (3), and (4). Indicated by.

Here, R _20d and R _20f are the resistance values of the first-stage current mirror circuit, respectively, and in the case of FIG. 1, are the resistance values of the constant resistances 20d and 20f. R _22d and R _22f are resistance values of the second-stage current mirror circuit, respectively, and in the case of FIG. 1, are the resistance values of the diode 22d and the constant resistance 22f.
For the diode, the diode forward voltage _{V Diode} and the relationship between current _{I Diode} flowing from the anode to the cathode, the saturation current _{I s} of the reverse voltage is applied, electrons of the charge ^{q (= 1.6 × 10 -19 [} C ], The Boltzmann constant K _B (= 1.38 × 10 ⁻²³ [J / K]), and the absolute temperature T [K], the equation (5) shows.

The forward voltage V _diode of the _diode is expressed by Expression (6) by _modifying Expression (5).

In the case of the optical receiver 10 according to the first embodiment, I _mon1 = I _diode , and the output current I _mon2 of the second-stage current mirror circuit is _expressed by Expression (7).

And using the equation (3) and Equation (7), the average optical input power _{P in,} the output current _{I mon2} of the current mirror circuit of the second stage is obtained.
In the case of the optical receiver 40 in the second embodiment, I _pd = I _diode , and the output current I _mon1 of the current mirror circuit is expressed by Expression (8).

And using equations (2) and Equation (8), the average optical input power _{P in,} the output current _{I mon1} of the current mirror circuit is obtained.
In the case of the optical receiver 50 of the third embodiment, by combining the equations (7) and Equation (8), the average optical input power P _in, the output current I _mon2 of the current mirror circuit of the second stage is determined It is done.

FIG. 7 is a graph showing the relationship of the monitor current to the average optical input power of the monitor circuit according to the present invention.
In FIG. 7, the curve a indicates the output current I _mon2 of the second-stage current mirror circuit in the case of the optical receiver 10 in the first embodiment or the output current of the current mirror circuit in the case of the optical receiver 40 in the second embodiment. in I _mon1, curve b is the output current _{I mon2} of the second stage of the current mirror circuit in the case of the optical receiver 50 in the third embodiment.
Curves c and d are described for comparison with curves a and b, and are obtained when a constant resistance is used in a conventional current mirror circuit. Curve c has a resistance ratio of 1 and a monitor gain. This is a case of 1 time. Curve d represents the case where the resistance ratio is 10 times and the monitor gain is 10 times.

The curve a was obtained using the formula (3) and the formula (7). Compared to the curve c having a resistance ratio of 1 and the curve d having a resistance ratio of 10 times, a wide dynamic range can be ensured. Therefore, monitoring can be performed up to a lower light input power, and the monitor current can be suppressed so as not to exceed the drive limit even on the maximum light input side.
The curve “b” is obtained using the equations (7) and (8). A wider dynamic range is ensured as compared with the curve a of one stage of the current mirror circuit using a diode. Therefore, it is possible to monitor to a lower optical input power, and it is possible to suppress the monitor current so as not to exceed the drive limit even on the maximum optical input side.

In the case of the curve c using the conventional constant resistance, it was obtained by substituting (R _20d / R _20f ) = (R _22d / R _22f ) = 1 into the formula (4).
Further, in the case of the curve d, it was obtained by substituting R _20d / R _20f = 10 or R _22d / R _22f = 10 into the equation (4).
In the case of the curve d, that is, when the resistance ratio is 10 times, it is possible to monitor even lower average optical input power than in the case of the curve c, that is, when the resistance ratio is 1 time.
However, in general, the maximum output current of the constant voltage source of the current mirror circuit, for example, 20c in FIG. 1, and the maximum current that can be output from the input unit of the A / D conversion circuit 26 are limited to about several mA. When the resistance ratio is 10 times, the monitor current continues to increase in the region where the optical input power is maximum, so that there is a case where the current is insufficient and monitoring cannot be performed correctly.
As described above, in the monitor circuit using the diode according to the first to third embodiments, a monitor circuit with higher accuracy can be realized than the current mirror circuit using only the resistance ratio of the constant resistance. .

FIG. 8 is a graph showing temperature characteristics of the monitor circuit according to the present invention.
8, the output current I of the current mirror circuit when the output current I _mon2 optical receiver 40 or in the second _embodiment, the second stage of the current mirror circuit in the case of the optical receiver 10 in the first embodiment _mon1 The temperature dependence of is shown.
Curve a is for −40 ° C., curve b is for 30 ° C., and curve c is for 95 ° C.
FIG. 9 is a graph showing temperature characteristics of the monitor circuit according to the present invention.
FIG. 9 shows the temperature dependence of the output current I _mon2 of the second-stage current mirror circuit in the case of the optical receiver 50 according to the third embodiment.
Curve a is for −40 ° C., curve b is for 30 ° C., and curve c is for 95 ° C.
In the case of the current mirror circuit using only the resistance ratio of the constant resistance, there is almost no temperature dependence, but as shown in the equation (5), when the diode is used, there is a fluctuation in inclination due to temperature. This temperature dependency is corrected using the MCU 32 or the external memory 62.

  As described above, the monitor circuit and the optical receiver according to the present invention are suitable for use in an optical communication system using an optical fiber.

  12 APD, 20 Pre-stage current mirror circuit, 22 Post-stage current mirror circuit 22, 24 Current-voltage conversion circuit, 26 A / D conversion circuit, 28 Temperature sensor, 30 A / D conversion circuit, 32 MCU, 42 Current mirror circuit, 44 Current Voltage conversion circuit, 62 External memory.

Claims (5)

While receiving an optical signal and converting it into an electrical signal, a light receiving element having one end connected to a signal output terminal ,
First a first transistor and a second transistor connected to a first constant voltage source above via a second constant resistive load which is connected to a first constant voltage source via a constant resistance load And the first transistor and the second transistor constitute a current mirror circuit, and the first connection of the current mirror circuit facing the first constant resistance load via the first transistor One end and the other end of the light receiving element are connected to each other and correspond to the output of the light receiving element from the second connection end of the current mirror circuit facing the second constant resistance load via the second transistor . A first current mirror circuit for outputting a first monitor current;
A third transistor having a polarity opposite to that of the first transistor , connected to the diode in a forward direction and connected to a second constant voltage source having a voltage lower than that of the first constant voltage source through the diode; The fourth transistor is connected to the second constant voltage source via a third constant resistance load and has a polarity opposite to that of the second transistor. The third transistor and the fourth transistor are A first connection terminal of the current mirror circuit that constitutes a current mirror circuit and is opposed to the diode is connected to the second connection terminal of the first current mirror circuit through the third transistor. the second connecting end of the current mirror circuit which opposed with the third constant resistance load through the fourth transistor, the first current mirror circuit the second A second current mirror circuit a first monitor current and outputs a second monitor current logarithmically converted from connection end,
A current-voltage conversion circuit connected to the second connection end of the second current mirror circuit and converting the output of the second current mirror circuit into a voltage signal;
A first A / D conversion circuit connected to the current-voltage conversion circuit and converting an output of the current-voltage conversion circuit into a digital signal;
A temperature detector disposed in proximity to the light receiving element and the second current mirror circuit;
A second A / D conversion circuit for converting the output of the temperature detection unit into a digital signal;
Connected to the first and second A / D conversion circuits, corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the second A / D conversion circuit An arithmetic unit to perform,
Monitor circuit with While receiving an optical signal and converting it into an electrical signal, a light receiving element having one end connected to a signal output terminal,
A first transistor connected to the diode in a forward direction and connected to the first constant voltage source via the diode, and a second transistor connected to the first constant voltage source via a constant resistance load; The first transistor and the second transistor form a current mirror circuit, and the first connection end of the current mirror circuit facing the diode via the first transistor and the light receiving element Is connected to the other end of the current mirror circuit through the second transistor and corresponds to the output of the light receiving element and logarithmically converted from the second connection end of the current mirror circuit . A first current mirror circuit for outputting a monitor current;
A current-voltage conversion circuit connected to the second connection end of the first current mirror circuit and converting the output of the first current mirror circuit into a voltage signal;
A first A / D conversion circuit connected to the current-voltage conversion circuit and converting an output of the current-voltage conversion circuit into a digital signal;
A temperature detector disposed in proximity to the light receiving element and the first current mirror circuit;
A second A / D conversion circuit for converting the output of the temperature detection unit into a digital signal;
Connected to the first and second A / D conversion circuits, corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the second A / D conversion circuit. An arithmetic unit;
Monitor circuit with While receiving an optical signal and converting it into an electrical signal, a light receiving element having one end connected to a signal output terminal,
The first constant voltage source is connected to the first diode in the forward direction and connected to the first constant voltage source via the first diode and the first constant resistance load. And the first transistor and the second transistor form a current mirror circuit, and the current that faces the first diode through the first transistor is provided. The first connection end of the mirror circuit and the other end of the light receiving element are connected to each other from the second connection end of the current mirror circuit facing the first constant resistance load via the second transistor. A first current mirror circuit corresponding to the output of the light receiving element and outputting a logarithmically converted first monitor current;
Second and diode connected in the forward direction to each other through the second diode is connected to a second constant voltage source having a voltage lower than the first constant voltage source above, opposite polarity to said first transistor A third transistor connected to the second constant voltage source through a second constant resistance load, and a fourth transistor having a polarity opposite to that of the second transistor. And the fourth transistor constitute a current mirror circuit, the first connection terminal of the current mirror circuit facing the second diode via the third transistor, and the first current mirror circuit. The first current mirror is connected from the second connection end of the current mirror circuit connected to the second connection end and opposed to the second constant resistance load via the fourth transistor. First monitor current from said second connection end of the circuit is further logarithmic conversion, and a second current mirror circuit for outputting a second monitor current,
A current-voltage conversion circuit connected to the second connection end of the second current mirror circuit and converting the output of the second current mirror circuit into a voltage signal;
A first A / D conversion circuit connected to the current-voltage conversion circuit and converting an output of the current-voltage conversion circuit into a digital signal;
A temperature detector disposed in proximity to the light receiving element and the first current mirror circuit;
A second A / D conversion circuit for converting the output of the temperature detection unit into a digital signal;
Connected to the first and second A / D conversion circuits, corrects and outputs the digital signal from the first A / D conversion circuit based on the digital signal from the second A / D conversion circuit. An arithmetic unit;
Monitor circuit with   A memory connected to the computing unit and storing temperature coefficient data of diodes disposed in the second current mirror circuit, the first current mirror circuit, or the first and second current mirror circuits; 4. The monitor circuit according to claim 1, wherein the current value of the monitor current is corrected by using the temperature coefficient data. The monitor circuit according to any one of claims 1 to 4,
A transimpedance amplifier that converts the output current of the light receiving element of the monitor circuit into a voltage signal;
An amplifier that amplifies and outputs the output signal of the transimpedance amplifier;
With optical receiver.

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