JP2000124746A - Optical reception circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical reception circuit for simplifying circuit constitution and lowering a cost. SOLUTION: In this optical reception circuit, an optical current I4 generated corresponding to the intensity of optical signals 29 made incident on a PD (photodiode) 20 connected through a protective resistor 21 to a power supply voltage VCC is detected for the portion of a voltage drop by the protective resistor 21 from the power supply voltage VCC and it is compared with a prescribed reference voltage. By the compared result, when the output of an invertible amplifier 24 is fed back to an input side, either one of the feedback resistors 26 and 27 of mutually different resistance values is selected by a switch 25. When the intensity of the incident optical signals is small, by enlarging a feedback resistance value, a feedback amount is enlarged and the gain of the amplifier is enlarged. When the intensity of the incident optical signals is large, by reducing the feedback resistance value, the feedback amount is reduced and the saturation of the amplifier is evaded.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an optical receiving circuit, and more particularly, to an optical receiving circuit that realizes a wide dynamic range.

[0002]

2. Description of the Related Art In recent years, with the development of information processing technology and optical transmission technology, a transmission speed exceeding 10 gigabits per second has been required due to an increase in optical transmission capacity and an increase in optical transmission distance. As one form of this large-capacity optical transmission, wavelength-division multiplexing, linear repeater transmission using optical amplifiers, and optical transmission using ultra-long-distance transmission technology have become practical, from those using conventional time-division multiplexing. It has become.
With the introduction of such new optical transmission technology, optical receiving circuits are also required to have high optical receiving sensitivity characteristics. But,
Optical receiver circuits may receive optical signals transmitted over short distances such as intra-office transmissions, or large signals for the return test of the local station in systems using optical amplifiers. The circuit requires a very wide dynamic range.

FIG. 4 shows an outline of the configuration of a conventionally proposed optical receiving circuit having a wide dynamic range. This light receiving circuit has a photodiode (Photo Diode: hereinafter, abbreviated as PD) 10 as a photoelectric conversion element. The cathode terminal of the photodiode 10 is a power supply voltage VCC, and the anode terminal is a voltage signal. Are connected to a preamplifier 11 for converting the data into a preamplifier. An output terminal of the preamplifier 11 is connected to an input terminal of a main amplifier 12 that amplifies an electric signal at a predetermined amplification factor. An output terminal of the main amplifier 12 is connected to a waveform shaping circuit 13 for shaping a signal waveform. The preamplifier 11 includes an inverting amplifier 14, a current distribution control circuit 15, and feedback resistors 16 and 17.
The anode terminal of the PD 10 is connected to the inverting amplifier 14 and the current distribution control circuit 15. The output terminal of the inverting amplifier 14 is connected to the main amplifier 12 and to the current distribution control circuit 15 via feedback resistors 16 and 17 connected in parallel.

In the optical receiving circuit having such a configuration, the PD1
Electrical signal is generated as a photocurrent I ₁ according to the intensity of the incident optical signal 18 to zero. The current distribution control circuit 15 can change the current distribution ratio between the current I ₂ flowing through the feedback resistor 16 and the current I ₃ flowing through the feedback resistor 17 according to the photocurrent I ₁ . Therefore, when the photocurrent I ₁ is small, that is, when the intensity of the optical signal 18 incident on the PD 10 is small, the conversion gain of the preamplifier 11 is reduced by reducing the current I ₃ so that the resistance of the feedback resistor 16 and the current it can be a large value determined by I _2. On the other hand, when the optical current I ₁ is large, that is, when the intensity of the optical signal 18 incident on the PD 10 is large, the current I ₃ starts to flow, so that the feedback resistors 16 and 17 are connected in parallel. You. Conversion gain of this time the preamplifier 11, and the resistance value of the feedback resistor 16, the current I _2, and the resistance value of the feedback resistor 17 can be a small value determined by the current I _3. By controlling the feedback rate in accordance with the photocurrent I ₁ in this manner, the output signal of the inverted gain 11 having a wide dynamic range is voltage-amplified by the main signal 12 at a predetermined gain, and then the waveform shaping circuit 13 Performs waveform shaping based on a predetermined threshold. Thereby, a digital electric signal corresponding to the optical signal input to the PD 10 can be output.

A technique relating to such an optical receiving circuit is disclosed, for example, in Japanese Patent Application Laid-Open No. 10-79625, entitled "Optical Receiving Circuit".

Japanese Utility Model Laid-Open Publication No. Sho 62-196415 discloses an "optical receiving apparatus" that includes one of feedback resistors connected in parallel between input and output terminals of an inverting amplifier circuit based on a peak value of an amplified signal.
A technique related to an optical receiving circuit that realizes a wide dynamic range by adjusting a feedback resistance value and a current value by switching one connection is disclosed.

[0007]

However, a conventional optical receiving circuit is disclosed in, for example, Japanese Utility Model Application Laid-Open No. 62-196415.
In the technique described in Japanese Patent Laid-Open No. H11-207, an additional circuit called a peak value detection circuit that detects a peak value of an amplified signal is required to control a feedback resistance value and a current value, which causes an increase in the scale and complexity of a circuit configuration. . In the technique disclosed in Japanese Patent Application Laid-Open No. H10-79625, the circuit configuration of the current distribution control circuit in the optical receiving circuit becomes complicated. That is, in this current distribution control circuit, a current flowing through one of the feedback resistors is controlled by a current mirror circuit in order to distribute the current generated by the photoelectric conversion element to the feedback resistors.
However, since the current mirror circuit requires two transistors having uniform characteristics, it must be said that the current mirror circuit is suitable only for an integrated circuit. As described above, the conventional optical receiving circuit has a problem that the circuit configuration becomes complicated and various costs are imposed to obtain desired characteristics, so that the manufacturing cost is increased.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical receiving circuit which can simplify the circuit configuration and reduce the cost.

[0009]

According to the first aspect of the present invention, (a) photoelectric conversion means for converting an incident optical signal into a current value in accordance with the intensity of the incident optical signal, and (b) this photoelectric conversion means. Amplification means for inverting and amplifying the converted current;
(C) voltage value detection means for detecting the intensity of the optical signal as a voltage value corresponding to the converted current value, and (d) a feedback amount of the amplification means based on the voltage value detected by the voltage value detection means. The feedback circuit for changing the feedback amount is provided in the optical receiving circuit.

That is, in the first aspect of the present invention, the incident optical signal is converted into a current value by the photoelectric conversion means, and the current value is inverted and amplified by the amplification means. The voltage value detecting means detects the intensity of the optical signal as a voltage value, and the feedback amount changing means changes the feedback amount of the amplifying means based on the detection result.

According to the second aspect of the present invention, (a) a photodiode to which a reverse bias voltage of a power supply voltage level is added via a first resistor, and (b) an optical signal of an optical signal incident on the photodiode. (C) a plurality of feedback resistors having different resistance values connected in parallel between an input terminal and an output terminal of the inverting amplifier for converting a photocurrent generated according to the intensity into a voltage signal; D) The optical receiving circuit is provided with path switching means for switching a feedback path by selecting one of a plurality of feedback resistors based on a voltage drop level generated at the first resistor by the photocurrent.

That is, according to the second aspect of the present invention, when an incident optical signal is converted into a current value by a photodiode, a voltage drop caused by a photocurrent flowing through the first resistor is used, and the input terminal of the inverting amplifier is used. And a plurality of feedback resistors having different resistance values connected in parallel between the output terminals and selectively switching the feedback path by the path switching means, thereby providing a feedback amount to the input side of the inverting amplifier. To change.

According to the third aspect of the present invention, (a) a photodiode to which a reverse bias voltage of a power supply voltage level is added via a first resistor, and (b) an optical signal of an optical signal incident on the photodiode. (C) a plurality of feedback resistors having different resistance values connected in parallel between the input terminal and the output terminal of the inverting amplifier for converting a photocurrent generated according to the intensity into a voltage signal; A) a feedback current changing means for changing a current flowing through the plurality of feedback resistors based on a voltage drop level generated at the first resistor by the photocurrent.

That is, according to the third aspect of the present invention, the input terminal of the inverting amplifier is determined based on the voltage drop caused by the photocurrent flowing through the first resistor when the incident optical signal is converted into a current value by the photodiode. The amount of feedback to the input side of the inverting amplifier is changed by changing the current flowing through a plurality of feedback resistors connected in parallel between the output terminals and having different resistance values.

According to a fourth aspect of the present invention, in the optical receiving circuit of the third aspect, the feedback current changing means increases or decreases the number of feedback paths of a plurality of feedback resistors connected in parallel based on the voltage drop level. It is characterized in that currents flowing through a plurality of feedback resistors are changed.

That is, according to the present invention, the number of feedback paths of a plurality of feedback resistors connected in parallel between the input side and the output side of the inverting amplifier is increased or decreased based on the drop voltage level, so that these feedback resistors are connected to the inverting amplifier. Change the flowing current,
The amount of feedback to the input side of the inverting amplifier is changed.

According to a fifth aspect of the present invention, in the optical receiving circuit according to the third aspect, the feedback current changing means includes a voltage dividing means for dividing a voltage that changes in accordance with the intensity of the photocurrent, and the voltage dividing means. And a feedback path increasing / decreasing means for increasing / decreasing the feedback paths of a plurality of feedback resistors connected in parallel based on the divided voltage level value.

In other words, according to the fifth aspect of the present invention, the voltage which varies in accordance with the intensity of the photocurrent is divided by the voltage dividing means so that the voltage is divided in parallel between the input side and the output side of the inverting amplifier. The feedback paths of the plurality of feedback resistors are increased or decreased.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to embodiments.

First Embodiment

FIG. 1 shows an outline of the configuration of an optical receiving circuit according to a first embodiment of the present invention. This optical receiving circuit has a PD 20 as a photoelectric conversion element,
The cathode terminal is connected to the power supply voltage VC via the protection resistor 21.
C, the anode terminal is connected to a feedback amplifier circuit 22 for converting an input current signal into a voltage signal.
The cathode terminal of the PD 20 is connected to one input terminal of the comparison circuit 23, and the reference voltage Vref is constantly applied to the other input terminal of the comparison circuit 23. Comparison circuit 2
3 is input to the feedback amplifier circuit 22.
The feedback amplifier circuit 22 includes an inverting amplifier 24 for inverting and amplifying an input signal, a switch 25 for switching a path, and feedback resistors 26 and 27 having different resistance values.
The anode terminal of the PD 20 is connected to the input terminal of the inverting amplifier 24 and the switch 25. The output terminal of the inverting amplifier 24 is connected to the output terminal 28 of the optical receiving circuit, and is also connected to the switch 25 via feedback resistors 26 and 27 connected in parallel. Switch 2
Reference numeral 5 indicates that the path of the anode terminal of the PD 20 can be switched to either the feedback resistor 26 or the feedback resistor 27 based on the output signal of the comparison circuit 23.

In the optical receiving circuit having such a configuration, the PD2
Electrical signal is generated as a photocurrent I ₄ according to the intensity of the optical signal 29 incident to zero. Assuming that the connection point between the PD 20 and the protection resistor 21 is a point A, the potential at the point A is the power supply voltage VC.
A voltage drop occurs from C in accordance with the photocurrent I ₄ flowing through the protection resistor 21. The voltage at the point A is compared with a predetermined reference voltage Vref by a comparison circuit 23, and the comparison result is referred to as a switch 2
5 is output. Since the resistance value of the feedback resistor of the inverting amplifier 24 can be changed according to the comparison result, the feedback amount of the inverting amplifier 24 can be changed, and the inverting amplifier 2 can be changed.
4 can be configured with a wide dynamic range without saturating the output signal.

Here, it is assumed that the resistance R ₁ of the feedback resistor 26 is larger than the resistance R ₂ of the feedback resistor 27. Therefore, when the intensity of the optical signal 29 incident on the PD 20 is small, the generated photocurrent I ₄ is also small. Power supply voltage VCC
, The potential at the point A due to the voltage drop generated by the protection resistor 21 is compared with the reference voltage Vref by the comparison circuit 23. Since the voltage drop due to the protection resistor 21 is small, the comparison result is output as a value larger than the reference voltage Vref. The comparison result is input to the switch 25. In this case, the switch 25 is set to the path of the feedback resistor 26 of resistance R _1. Thereby, the inverting amplifier 24
Can be increased, the gain of the feedback amplifier circuit 22 can be increased.

On the other hand, when the intensity of the optical signal 29 incident on the PD 20 is high, the generated photocurrent I ₄ also increases. Then, the power supply voltage VCC is switched to the protection resistor 21
The potential at the point A due to the voltage drop generated by the comparison circuit 23 is compared with the reference voltage Vref by the comparison circuit 23. But,
Since the voltage drop due to the protection resistor is large, the reference voltage Vr
The comparison result is output as a value smaller than ef. As a result of the comparison is input to the switch 25, the switch 25 is routed switching the path of the feedback resistor 27 of the resistance value R _2. As a result, the feedback resistance of the inverting amplifier 24 can be reduced, so that the output signal of the feedback amplifier circuit 22 can be prevented from being saturated.

As described above, the optical receiving circuit according to the first embodiment uses the photocurrent I ₄ generated according to the power supply voltage VCC and the intensity of the optical signal 29 incident on the PD 20 connected via the protection resistor 21. Is detected as a voltage drop by the protection resistor 21 from the power supply voltage VCC, and is compared with a predetermined reference voltage Vref. Then, based on the comparison result, when the output signal of the inverting amplifier 24 is fed back to the input side, one of the feedback resistors 26 and 27 having different resistance values is selected by the switch 25. . Thus, when the intensity of the incident optical signal is low, the amount of feedback can be increased by increasing the feedback resistance value to increase the gain of the amplifier. By reducing the resistance value, the amount of feedback can be reduced and the saturation of the amplifier can be avoided. Therefore, an optical receiving circuit having a wide dynamic range can be realized with a very simple configuration such as a comparison circuit and a switch.

Second Embodiment

The optical receiving circuit in the first embodiment selects the optimum feedback resistance value from a plurality of feedback resistors provided in advance by the switch 25.
The optical receiving circuit according to the second embodiment uses a current control circuit instead of the switch 25 to control the value of the current flowing through the feedback resistor.

FIG. 2 shows an outline of the configuration of the optical receiving circuit in the second embodiment. However, the same parts as those of the optical receiving circuit in the first embodiment shown in FIG. This light receiving circuit has a PD 20 as a photoelectric conversion element, a cathode terminal of which is connected to a power supply voltage VCC via a protective resistor 21 and an anode terminal of which is a feedback amplifier circuit 30 for converting an input current signal into a voltage signal. , Respectively. The cathode terminal of the PD 20 is also connected to the input level detection circuit 31. The feedback amplifier circuit 30 includes an inverting amplifier 24, a current control circuit 32, and feedback resistors 26 and 27 different from each other. The anode terminal of the PD 20 is connected to the inverting amplifier 2
4 and a current control circuit 32. The output terminal of the inverting amplifier 24 is the output terminal 28 of the optical receiving circuit.
, And to the current control circuit 32 via feedback resistors 26 and 27 connected in parallel. The current control circuit 32 includes the input level detection circuit 3
The current flowing through each of the feedback resistors 26 and 27 can be controlled based on one output signal.

In the optical receiving circuit having such a configuration, the PD2
Electrical signal is generated as a photocurrent I ₅ according to the intensity of the incident optical signal 29 at zero. Potential at point A which is the connection point between the PD20 and the protection resistor 21 in accordance with the photocurrent I ₅ flowing through the protection resistor 21 from the power supply voltage VCC, produces a voltage drop. The input level detection circuit 31 controls the current control circuit 32 based on the potential at the point A, and can adjust the amount of current flowing through each of the feedback resistors 26 and 27.

Here, the optical signal 29 incident on the PD 20
When the strength is small, the photocurrent I ₅ also small occur. Therefore, the input level detection circuit 31 which has detected the potential at the point A at this time controls the current control circuit 32 so that no current flows through the feedback resistor 27, thereby reducing the gain of the feedback amplifier and the feedback resistor 26. And the feedback resistance 26
Can be determined by the current flowing through In contrast, when the intensity of the optical signal 29 incident on the PD20 is large also increases the photocurrent I ₅ generated. At this time, the input level detection circuit 31 that has detected the potential at the point A controls the current control circuit 32 and shunts the current to the feedback resistor 27 to reduce the feedback amount. An optical receiving circuit can be realized.

Hereinafter, the optical receiving circuit according to the second embodiment will be described in more detail.

FIG. 3 specifically shows the main components of the optical receiving circuit according to the second embodiment. Therefore, the same portions as those of the optical receiving circuit in the second embodiment in FIG. 2 are denoted by the same reference numerals, and the description will be appropriately omitted. This light receiving circuit has a PD 20 as a photoelectric conversion element, a cathode terminal of which is connected to a power supply voltage VCC via a protective resistor 21 and an anode terminal of which is a feedback amplifier circuit 30 for converting an input current signal into a voltage signal. , Respectively. The cathode terminal of the PD 20 is connected to one end of the input level detection circuit 31. That is, the voltage dividing resistors 40 ₁ and 40 ₂ are connected in series to the cathode terminal of the PD 20, and the other terminal is grounded.
0 _1, 40 ₂ of the connection point is electrically connected to the current control circuit 32.

The feedback amplification circuit 30 includes an input stage amplification unit 41
And a feedback section 42. The input stage amplifying unit 41
It has an npn transistor 43. The base terminal is connected to the anode terminal of the PD 20, the collector terminal is connected to the power supply voltage VCC via the resistor 44, and the emitter terminal is grounded. Return section 42
Has an npn transistor 45. Its collector terminal is at the power supply voltage VCC and its base terminal is npn
The emitter terminal is connected to the collector terminal of the type transistor 43, and the emitter terminal is grounded via the resistor 46.
The output terminal 28 is connected to the emitter terminal of the npn transistor 45.

A feedback resistor 2 is connected to this emitter terminal.
One end of each of 6, 6 is connected. Feedback resistor 2
The other end of 6 is connected to the base terminal of npn transistor 43. A current control circuit 32 is connected to the other end of the feedback resistor 27. The current control circuit 32
A p-type transistor 47 has a collector terminal connected to the other end of the feedback resistor 27 and a base terminal connected to a voltage dividing resistor 40 ₁ , 4.
At the voltage dividing point of O ₂ , the emitter terminal is connected to the base terminal of the npn transistor 43.

In the optical receiving circuit having such a configuration, the PD2
When the intensity of the optical signal 29 incident on 0 is small, PD2
Since the photocurrent _Iph generated at 0 is small and the voltage drop due to the protection resistor 21 is small, the potential at the point A remains high. Therefore, in the input level detection circuit 31 to which the potential at the point A is added to one end, the voltage dividing resistor 40
_1, 40 ₂ divided potential level at the voltage dividing point by also remains high. At this time, if the pnp transistor 47 is not operated, no current flows through the feedback resistor 27, and the amount of feedback determined by the feedback resistor 26 is fed back to the input stage amplifier 41.

[0037] On the contrary, when the intensity of the optical signal 29 incident on the PD20 is large, the photocurrent I _ph generated in PD20 increases, the voltage drop is also increased by the protection resistor 21. Therefore, the potential at point A drops,
In the input level detection circuit 31 having this added to one end,
Divided potential level at the voltage dividing point by dividing resistors 40 _1, 40 ₂ is also lowered. At this time, the pnp transistor 47
Is operated, the feedback amount determined by the ratio of the current flowing through the feedback resistor 27 to the current flowing through the feedback resistor 26 is fed back to the input stage amplifier 41.

At this time, the potential level at the voltage dividing point can be changed by changing the ratio between the resistance values of the voltage dividing resistors 40 ₁ and 40 _{2 of the} input level detecting circuit 31.
The operating point of the p-type transistor 47 can be changed. As a result, the ratio of the current flowing through each of the feedback resistors 26 and 27 can be arbitrarily adjusted. For example, by using one of the feedback resistors 26 and 27 as a variable resistor, the operating point of the pnp transistor 47 can be easily changed.

[0039] In the light receiving circuit in Fig. 3 Note that the current I _b flowing in the input level detection circuit 31, to be sufficiently smaller than the I _ph generated by PD 20, for example, I _b is I
_{The voltage dividing} resistors 40 ₁ and 40 ₂ are set to be 1/10 or less of _ph
It is desirable to select the resistance value. This power supply voltage VCC protection resistor 21, to be connected to the ground potential via the voltage dividing resistors 40 _1, 40 _2, if a mistake in the selection of the voltage dividing resistors 40 _1, 40 ₂ of the resistance value, the current consumption This is because it becomes extremely large.

As described above, the optical receiving circuit according to the second embodiment generates the photocurrent generated according to the power supply voltage VCC and the intensity of the optical signal 29 incident on the PD 20 connected via the protection resistor 21. From this power supply voltage VCC, the protection resistor 2
1 is detected as a voltage drop. The amount of current flowing through each of the feedback resistors 26 and 27 having different resistance values when the output signal of the inverting amplifier 24 is fed back to the input side is adjusted based on the potential level at which the voltage has dropped. That is, by detecting the intensity of the incident optical signal as a voltage drop of the protection resistor 21 due to the photocurrent generated by the PD 20 and dividing the voltage, it is possible to control the transistor that adjusts the current flowing through one feedback resistor. So
An optical receiving circuit with a wide dynamic range can be realized with a very simple configuration.

In the first and second embodiments, feedback using two types of feedback resistors has been described, but the number of feedback resistors is not limited. For example, three or more types of feedback resistors are switched according to the intensity of the optical signal,
Alternatively, a wide dynamic range can be realized by shunting current in parallel.

In the first and second embodiments, the optical signal is converted by the PD into an electric signal. However, the present invention is not limited to this.

[0043]

As described above, according to the present invention, the intensity of this optical signal is detected as a voltage value when the incident optical signal is converted to a current value by the amplifying means and inverted. Then, based on this, the feedback amount of the inverting amplification is changed. This eliminates the need for an additional circuit having a complicated circuit configuration, such as a conventionally used current mirror circuit, and provides a very simple circuit configuration, low cost, and wide dynamic range optical reception. A circuit can be realized.

Further, according to the present invention, the feedback paths of a plurality of feedback resistors connected in parallel between the input side and the output side of the inverting amplifier are increased or decreased based on the voltage drop level. Since the current flowing through the resistor is changed to change the amount of feedback to the input side of the inverting amplifier, an optical receiving circuit with a very simple configuration and a wide dynamic range can be realized.

According to the fifth aspect of the present invention,
The divided voltage obtained by dividing the voltage that changes according to the intensity of the photocurrent by the voltage dividing means increases or decreases the feedback paths of a plurality of feedback resistors connected in parallel between the input side and the output side of the inverting amplifier. As a result, the current flowing through the feedback resistor can be adjusted with a simpler configuration.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an outline of a configuration of an optical receiving circuit according to a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating an outline of a configuration of an optical receiving circuit according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram illustrating details of a main configuration of an optical receiving circuit according to a second embodiment;

FIG. 4 is a block diagram illustrating an outline of a configuration of a conventionally proposed optical receiving circuit.

[Explanation of symbols]

REFERENCE SIGNS LIST 20 PD 21 protection resistor 22, 30 feedback amplifier circuit 23 comparison circuit 24 inverting amplifier 25 switch 26, 27 feedback resistor 28 output terminal 29 optical signal 31 input level detection circuit 32 current control circuit 40 ₁ , 40 ₂ voltage dividing resistor 41 input stage Amplifying section 42 Feedback section 43, 45 npn-type transistor 44, 46 resistor 47 pnp-type transistor

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04B 10/06

Claims (5)

[Claims] A photoelectric conversion unit for converting an incident optical signal into a current value in accordance with the intensity of the incident optical signal; an amplifying unit for inverting and amplifying the current converted by the photoelectric conversion unit; Voltage value detecting means for detecting a voltage value corresponding to the converted current value; and feedback amount changing means for changing a feedback amount of the amplifying means based on the voltage value detected by the voltage value detecting means. An optical receiving circuit. 2. A photodiode to which a reverse bias voltage of a power supply voltage level is added via a first resistor, and a photocurrent generated according to the intensity of an optical signal incident on the photodiode is converted into a voltage value. An inverting amplifier for converting, a plurality of feedback resistors connected in parallel between an input terminal and an output terminal of the inverting amplifier having different resistance values, and a voltage drop generated by the first resistor due to the photocurrent. And a path switching unit for switching a feedback path by selecting one of the plurality of feedback resistors based on the feedback signal. 3. A photodiode to which a reverse bias voltage of a power supply voltage level is added via a first resistor, and a photocurrent generated according to the intensity of an optical signal incident on the photodiode is converted into a voltage value. An inverting amplifier for converting, a plurality of feedback resistors connected in parallel between an input terminal and an output terminal of the inverting amplifier having different resistance values, and a voltage drop level generated in the first resistor by the photocurrent. And a feedback current changing means for changing a current flowing through the plurality of feedback resistors. 4. The feedback current changing means changes a current flowing through the plurality of feedback resistors by increasing or decreasing a feedback path of the plurality of feedback resistors connected in parallel based on the voltage drop level. The optical receiving circuit according to claim 3, wherein: 5. The feedback current changing unit includes a voltage dividing unit that divides a voltage that changes according to the intensity of the photocurrent, and the parallel connection based on a divided voltage value divided by the voltage dividing unit. 4. The optical receiving circuit according to claim 3, further comprising a feedback path increasing / decreasing means for increasing / decreasing the feedback paths of the plurality of feedback resistors.