JP2007287936A - Optical output control circuit, optical communication device, and method and program for controlling optical output - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical output control circuit, an optical communication device, and a method and a program for controlling the optical output capable of relaxing a complexity of a temperature compensation control. <P>SOLUTION: The optical output control circuit for conducting the temperature compensation control of a laser diode (1) by the use of a bias current (8) and a pulse current (7) adjusted in response to an ambient temperature determines the bias current (8) by the use of a common reference voltage value (11) to conduct the temperature compensation control of the diode (1) by the use of the determined bias current (8) at the time of a first optical output state (OUT 1) and a second optical output state (OUT 2) when controlling the optical output state of the diode (1) by switching the optical output state of the diode (1) to the state (OUT 1) and the state (OUT 2). <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical output control circuit, an optical output control method, and an optical output control program for controlling the optical output of a laser diode, and in particular, an optical output control circuit suitable for an optical communication apparatus that performs communication using an optical signal, optical The present invention relates to an output control method and a light output control program.

  As an optical output control circuit mounted on an optical communication device that performs communication using an optical signal, for example, a circuit configuration shown in FIG. The optical communication apparatus controls an optical signal used for communication by the optical output control circuit shown in FIG. 7, and performs communication using the controlled optical signal. Hereinafter, the circuit configuration of a conventional light output control circuit will be described with reference to FIG.

  As shown in FIG. 7, the conventional light output control circuit includes an LD (Laser Diode) (1), a monitor PD (Photo Diode) (2), an I / V conversion circuit (9), and a comparison amplifier (10). ), A reference voltage (11), a bias current control circuit (8), a pulse current control circuit (7), a switching control unit (6), a first switch (5), and a second switch ( 19), a temperature sensor (12), an A / D converter (13), a memory (14), and a plurality of D / A converters (15 to 18).

  In the optical output control circuit configured as described above, the monitor PD (2) receives at least one portion of the optical signal output from the LD (1), and the optical output state of the optical signal output from the LD (1) Is output to the I / V conversion circuit (9). The I / V conversion circuit (9) converts the photodetection current output from the monitor PD (2) into a voltage value corresponding to the photodetection current value, and compares the converted voltage value with the comparison amplifier (10). ).

  The comparison amplifier (10) compares the output voltage value output from the I / V conversion circuit (9) with the reference voltage value output from the reference voltage (11), and outputs the output voltage value and the reference voltage value. The difference value (| output voltage value−reference voltage value |) is calculated, and the difference voltage value obtained by amplifying the calculated difference value is output to the bias current control circuit (8).

  The bias current control circuit (8) is output from the output voltage value output from the I / V conversion circuit (9) and the reference voltage (11) based on the differential voltage value output from the comparison amplifier (10). The bias current flowing through the LD (1) is controlled so that the reference voltage value is equal to the reference voltage value.

  As described above, the optical output control circuit shown in FIG. 7 includes the monitor PD (2), the I / V conversion circuit (9), the comparison amplifier (10), the reference voltage (11), and the bias current control circuit ( 8) and a negative feedback control circuit, and the LD (1) outputs an optical signal corresponding to the reference voltage value output from the reference voltage (11).

  The memory (14) stores a management table (see FIG. 8) for performing temperature compensation control of the LD (1).

  As shown in FIG. 8A, the management table manages the pulse current setting data in association with the address value corresponding to the ambient temperature, and as shown in FIG. 8B. The bias current setting data is managed in association with the address value corresponding to the ambient temperature. Note that the setting data of the pulse current and the bias current are determined and managed so that the light output state and the extinction ratio of the LD (1) are constant with respect to fluctuations in the ambient temperature. Thus, when a digital value obtained by digitally converting the temperature signal indicating the ambient temperature detected by the temperature sensor (12) is input to the memory (14) via the digital A / D converter (13), the memory (14 ) Outputs the setting data of the pulse current corresponding to the address value corresponding to the digital value to the D / A converter (15, 16) using the management table shown in FIG. 8A. The setting data of the bias current corresponding to the address value is output to the D / A converter (17, 18) using the management table shown in FIG.

  The first switch (5) is one of the pulse current setting data output from the D / A converter (15, 16) based on the control signal output from the switching controller (6). The setting data is output to the pulse current control circuit (7). The pulse current control circuit (7) outputs the pulse current corresponding to the setting data output from the first switch (5) to the LD (1). The optical output state of the optical signal output from the LD (1) is controlled.

  The second switch (19) is one of the bias current setting data output from the D / A converter (17, 18) based on the control signal output from the switching control unit (6). The setting data is output to the reference voltage (11), the reference voltage (11) is set to a reference voltage value corresponding to the setting data output from the second switch (19), and the bias current control circuit (8) The bias current flowing through the LD (1) so that the reference voltage value set to the reference voltage (11) and the output voltage value output from the I / V conversion circuit (9) are equal to each other. To control.

  It is assumed that the first optical output state of the optical signal output from LD (1) constituting the optical output control circuit shown in FIG. 7 is OUT1, and the second optical output state is OUT2. In this case, the current value of the photodetection current I1 corresponding to OUT1 output from LD (1) and the photodetection current I2 corresponding to OUT2 output from LD (1) are different.

  Therefore, in order to perform temperature compensation control of LD (1), the management table in which the setting data of the pulse current for OUT1 and the address value corresponding to the ambient temperature are managed in association with each other, and the pulse current for OUT2 The management table in which the setting data and the address value corresponding to the ambient temperature are managed in association with each other, the setting data of the bias current (reference voltage) for OUT1 and the address value corresponding to the ambient temperature are associated with each other. A managed management table and a management table managed by associating the bias current (reference voltage) setting data for OUT2 with the address value corresponding to the ambient temperature are stored in the memory (14). It will be. That is, the management table shown in FIG. 8A for performing temperature compensation control of the pulse current is prepared for each light output state of OUT1 and OUT2, and for performing temperature compensation control of the bias current. The management table shown in FIG. 8B is prepared for each light output state of OUT1 and OUT2.

  Then, the memory (14) stores setting data corresponding to the address value of the ambient temperature detected by the temperature sensor (12) based on the four management tables, respectively, as D / A converters (15, 16, 17, 18). Will be output. In this case, the memory (14) outputs the pulse current setting data for OUT1 to the D / A converter (15), and the pulse current setting data for OUT2 to the D / A converter (16). The bias current setting data for OUT1 is output to the D / A converter (17), and the bias current setting data for OUT2 is output to the D / A converter (18).

  The first switch (5), based on the control signal output from the switching control unit (6), sets the pulse current setting data for OUT1 output from the D / A converter (15), and D / The pulse current setting data for OUT2 output from the A converter (16) and any pulse current setting data are output to the pulse current control circuit (7).

  In addition, the second switch (19), based on the control signal output from the switching controller (6), sets bias current setting data for OUT1 output from the D / A converter (17), and D / The bias current setting data for OUT2 output from the A converter (18) and any bias current setting data are output to the reference voltage (11).

  By switching control between the first switch (5) and the second switch (19), the combination of the D / A converter (15, 17), the combination of the D / A converter (16, 18), And the optical output state of the optical signal output from the LD (1) is switched between OUT1 and OUT2.

  As described above, the conventional light output control circuit manages the setting data for determining the pulse current for performing the temperature compensation control of the LD (1) and the address value corresponding to the ambient temperature in association with each other. A management table shown in FIG. 8A is prepared for each light output state of OUT1 and OUT2, and setting data for determining a bias current for performing temperature compensation control of LD (1); A management table shown in FIG. 8B for managing the address values according to the ambient temperature in association with each other is prepared for each light output state of OUT1 and OUT2, and the four management tables are stored in the memory (14). ) And the four management tables stored in the memory (14) are used to determine the pulse current and bias current to be used in each of the optical output states of OUT1 and OUT2. It will perform temperature compensation control of the LD (1) by using the pulse current and the bias current in the decision.

  For this reason, the number of management tables for performing temperature compensation control of LD (1) increases, and temperature compensation control becomes complicated. Further, since four management tables are stored in the memory (14), a large memory space in the memory (14) must be secured.

  As a technical document filed prior to the present invention, a laser diode driving circuit for driving a laser diode with a current obtained by superimposing a bias current near the light emission threshold current value of the laser diode and a pulse current for causing light emission is superimposed. The laser diode drive that can control the light output and extinction ratio constant against deterioration of the laser diode over time by adjusting the bias current and pulse current according to the ambient temperature and controlling the light output and extinction ratio constant There is a document disclosing a circuit (for example, see Patent Document 1).

  Further, it comprises a photodiode 2 for detecting the optical output of the laser diode 6, a current amplification circuit 7 for amplifying the output current of the photodiode so that the gain can be switched, and an I / V conversion circuit 8 for converting the amplified current into a voltage. Optical output monitor voltage generator 9, reference voltage source 3 that outputs a reference voltage, comparative rectifier circuit 4 that negatively feeds back the difference between the output of the optical output monitor voltage generator and the reference voltage to the laser drive source, and comparative rectification Even when the laser output circuit of the semiconductor laser is configured with the laser drive circuit 5 that generates the drive current of the laser diode based on the output of the circuit 4 to secure a wide dynamic range of the optical output and set the optical output low. There is a document disclosing an optical output control circuit of a semiconductor laser that can obtain a stable optical output without increasing the ratio of the variation amount to the optical output set value (for example, , See Patent Document 2).

In addition, a semiconductor laser output control unit 110 that emits laser light, a photodetector 120 that detects the emitted laser light, a sample processing unit 140 that performs sample processing, an erase current pulse, a write current pulse, and a read current pulse A pulse current generation unit 160 for generating and a control unit 180 for controlling each of the above-described units, generating sample processing and each pulse current based on preset APC timing, and based on each pulse current and sample processing Document that discloses an optical pickup device that controls the semiconductor laser output control unit and can independently change the light intensity of the laser light when the intensity level of the laser light output from the semiconductor laser is modulated (For example, refer to Patent Document 3).
Japanese Patent Laid-Open No. 11-135871 JP 2003-8139 A JP 2004-220663 A

  However, in Patent Document 1, the bias current and the pulse current are adjusted according to the ambient temperature, and the light output and the extinction ratio are controlled to be constant so that the light output and the extinction ratio are reduced with respect to the deterioration of the laser diode over time. Although a laser diode drive circuit that can be controlled to be constant is disclosed, no consideration is given to reducing the complexity of temperature compensation control.

  Further, in Patent Document 2, a wide dynamic range of light output is ensured so that a stable light output can be obtained without increasing the ratio of variation to the light output setting value even when the light output is set low. Although the semiconductor laser light output control circuit is disclosed, no consideration is given to reducing the complexity of temperature compensation control.

  Further, Patent Document 3 discloses an optical pickup device that can independently change the light intensity of laser light when the intensity level of laser light output from a semiconductor laser is modulated. No consideration is given to reducing the complexity of temperature compensation control.

  The present invention has been made in view of the above circumstances, and provides an optical output control circuit, an optical communication device, an optical output control method, and an optical output control program that can reduce the complexity of temperature compensation control. It is for the purpose.

  In order to achieve this object, the present invention has the following features.

  An optical output control circuit according to the present invention is an optical output control circuit that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature. When the light output state of the laser diode is controlled by switching between the first light output state and the second light output state, a common reference voltage value is used in the first light output state and the second light output state. Is used to determine a bias current, and temperature compensation control of the laser diode is performed using the determined bias current.

  In addition, the light output control circuit according to the present invention manages the temperature sensor for detecting the ambient temperature and the value of the first pulse current used in the first light output state in association with the ambient temperature. The first management means for outputting the first pulse current value corresponding to the detected ambient temperature and the second pulse current value used in the second light output state are managed in association with the ambient temperature. The second management means for outputting the value of the second pulse current corresponding to the ambient temperature detected by the temperature sensor is used in common in the first light output state and in the second light output state. A third management means for managing the bias current value in association with the ambient temperature and outputting a bias current value corresponding to the ambient temperature detected by the temperature sensor; a first pulse current value; and a second Pulse current value and any pulse current value The current is determined, the pulse current control means for performing temperature compensation control of the laser diode using the determined pulse current, the bias current value is used as a common reference voltage value, the bias current is determined, and the determined Bias current control means for performing temperature compensation control of the laser diode using the bias current.

  The light output control circuit according to the present invention further includes a selection unit that selects one of the first pulse current value and the second pulse current value. The means is characterized in that the pulse current is determined based on the value of the pulse current selected by the selection means.

  The light output control circuit according to the present invention includes a monitor photodiode that outputs a light output current in accordance with a light output state of the laser diode. The monitor photodiode is in the first light output state and in the second light output state. The bias current control means outputs a light output current having a value different from that in the light output state, and the bias current control means outputs the light output current output from the monitor photodiode in the first light output state and in the second light output state. The bias current is determined so that the output voltage value corresponding to the converted light output current is equal to the reference voltage value, and the bias current is determined. Is used to perform temperature compensation control of the laser diode.

  In the light output control circuit according to the present invention, the bias current control means amplifies the light output current output from the monitor photodiode by n (n is an arbitrary positive real number) times, and outputs the first light. The light output current is converted into a common value in the output state and in the second light output state.

  The light output control circuit according to the present invention converts the light output current output from the monitor photodiode into a light output current having a common value in the first light output state and in the second light output state. A current switching unit that outputs the converted optical output current, a current-voltage conversion unit that converts the output voltage value according to the optical output current based on the optical output current output from the current switching unit, and a current The output voltage value converted by the voltage conversion means is compared with the reference voltage value, a difference value that is a difference between the output voltage value and the reference voltage value is calculated, and the difference voltage value obtained by amplifying the calculated difference value is calculated. And a bias current control unit that biases the output voltage value and the reference voltage value to be equal to each other based on the differential voltage value amplified by the comparison amplification unit. Current and determine the determined bias current It is characterized in that the temperature compensation control of the laser diode are.

  In the light output control circuit according to the present invention, the current switching unit includes a fixed resistor and a variable resistor. The fixed resistor is provided in the first light output state and in the second light output state. And switching the variable resistor to convert the light output current to a common value in the first light output state and in the second light output state, and outputting the converted light output current To do.

  The light output control circuit according to the present invention detects an average value of the light output current output from the current switching means, and outputs the detected light output current of the average value to the current-voltage conversion means. The current-voltage converting means converts the output voltage value according to the optical output current output from the average value detecting means.

  In the light output control circuit according to the present invention, the current switching means is connected to the cathode side of the monitor photodiode.

  In the light output control circuit according to the present invention, the current switching means includes a first transistor, a second transistor, a fixed resistor, a variable resistor, a second fixed resistor, and a fixed resistor or a variable resistor. A switch to be selected, and the collector terminal side of the first transistor is connected to the cathode side of the monitor photodiode, and the emitter terminal side of the first transistor is connected via the second fixed resistor Connected to the power supply, the collector terminal side of the second transistor is connected to the current-voltage conversion means, the emitter terminal side of the second transistor is connected to the fixed resistor and the variable resistor, and is selected by the switch A fixed resistor or a variable resistor is connected to a power source.

  In the light output control circuit according to the present invention, the current switching means is connected to the anode side of the monitor photodiode.

  In the light output control circuit according to the present invention, the current switching means includes a first transistor, a second transistor, a third transistor, a fourth transistor, a fixed resistor, a variable resistor, 2 fixed resistors, a third fixed resistor, a fourth fixed resistor, and a switch for selecting a fixed resistor or a variable resistor. The collector terminal side of the first transistor has a monitor photo Connected to the anode side of the diode, the emitter terminal side of the first transistor is connected to the ground via the second fixed resistor, the collector terminal side of the second transistor is connected to the collector terminal side of the third transistor The emitter terminal side of the second transistor is connected to a fixed resistor and a variable resistor, and the fixed resistor or variable resistor selected by the switch is connected to the ground, and the third transistor is connected. The collector terminal side of the transistor is connected to the collector terminal side of the second transistor, and the emitter terminal side of the third transistor is connected to the cathode side of the monitor photodiode and the power source via the third fixed resistor. The collector terminal side of the fourth transistor is connected to the current-voltage conversion means, and the emitter terminal side of the fourth transistor is connected to the cathode side of the monitor photodiode, the power supply, and the fourth fixed resistor. It is characterized by being connected to.

  In the light output control circuit according to the present invention, the current switching means includes a first transistor, a second transistor, a third transistor, a fourth transistor, a fixed resistor, a variable resistor, 2 fixed resistors, a third fixed resistor, a fourth fixed resistor, and a switch for selecting a fixed resistor or a variable resistor. The collector terminal side of the first transistor has a monitor photo Connected to the anode side of the diode, the emitter terminal side of the first transistor is connected to the ground via a third fixed resistor, the collector terminal side of the second transistor is connected to the collector terminal side of the third transistor The emitter terminal side of the second transistor is connected to the ground via the fourth fixed resistor, and the collector terminal side of the third transistor is the collector terminal of the second transistor. The emitter terminal side of the third transistor is connected to the cathode side of the monitor photodiode and the power source via the second fixed resistor, and the collector terminal side of the fourth transistor is connected to the current terminal. Connected to the voltage conversion means, the emitter terminal side of the fourth transistor is connected to a fixed resistor and a variable resistor, and the fixed resistor or variable resistor selected by the switch is connected to the cathode side of the monitor photodiode and the power source It is characterized by being connected to.

  In the light output control circuit according to the present invention, the first management means, the second management means, and the third management means are managed in a common memory space. is there.

  An optical communication apparatus according to the present invention is equipped with the above-described optical output control circuit, controls an optical signal used for communication by the optical output control circuit, and communicates using the controlled optical signal. It is characterized by performing.

  An optical output control method according to the present invention is an optical output control method performed in an optical output control device that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature, When controlling the light output state of the laser diode by switching the light output state of the laser diode between the first light output state and the second light output state, the first light output state and the second light output state The light output control device performs a step of determining a bias current using a common reference voltage value and performing a temperature compensation control of the laser diode using the determined bias current. .

  In the light output control method according to the present invention, the light output control device includes a first management unit that manages the value of the first pulse current used in the first light output state in association with the ambient temperature; Common to the second management means for managing the value of the second pulse current used in the second light output state in association with the ambient temperature, in the first light output state and in the second light output state And a third management means for managing the value of the bias current used in association with the ambient temperature, a temperature detection step for detecting the ambient temperature, and a first corresponding to the ambient temperature detected by the temperature detection step A first output step of obtaining the value of the first pulse current from the first management means, and outputting the obtained value of the first pulse current, and a second pulse corresponding to the ambient temperature detected by the temperature detection step The current value is acquired from the second management means, and the acquired second A second output step for outputting the value of the pulse current and a bias current value corresponding to the ambient temperature detected by the temperature detection step from the third management means, and outputting the acquired bias current value One of the pulse current values of the third output step, the value of the first pulse current output in the first output step, and the value of the second pulse current output in the second output step The pulse current is determined based on the pulse current control step of performing temperature compensation control of the laser diode using the determined pulse current, and the bias current value output in the third output step is set to a common reference voltage value. And a bias current control step in which a bias current is determined and temperature compensation control of the laser diode is performed using the determined bias current. .

  In the light output control method according to the present invention, the light output control device includes a selection step of selecting one of the first pulse current value and the second pulse current value. The pulse current control step is characterized in that the pulse current is determined based on the value of the pulse current selected in the selection step.

  In the light output control method according to the present invention, the light output control device includes a monitor photodiode that outputs a light output current according to a light output state of the laser diode, and the monitor photodiode includes the first light output. A light output current of a different value is output in the state and in the second light output state, and the bias current control step converts the light output current output from the monitor photodiode into the second light output state and the second light output state. The bias current is determined so that the output voltage value corresponding to the converted light output current and the reference voltage value are equal to each other. The temperature compensation control of the laser diode is performed using the determined bias current.

  In the light output control method according to the present invention, the bias current control step amplifies the light output current output from the monitor photodiode by n (n is an arbitrary positive real number) times to obtain the first light. The light output current is converted into a common value in the output state and in the second light output state.

  The light output control method according to the present invention converts the light output current output from the monitor photodiode into a light output current having a common value in the first light output state and in the second light output state. A current switching step for outputting the converted optical output current, a current-voltage conversion step for converting the output voltage value according to the optical output current based on the optical output current output by the current switching step, and a current The output voltage value converted by the voltage conversion process is compared with the reference voltage value, a difference value that is a difference between the output voltage value and the reference voltage value is calculated, and the difference voltage value obtained by amplifying the calculated difference value is calculated. The optical output control device performs a comparison amplification step for output, and the bias current control step is based on the differential voltage value amplified in the comparison amplification step, and the voltage value in which the output voltage value and the reference voltage value are equal to each other. Determine the bias current to be The bias current used is characterized in that the temperature compensation control of the laser diode.

  In the light output control method according to the present invention, the light output control device includes a fixed resistor and a variable resistor, and the current switching step is performed during the first light output state and the second light output state. And switching between a fixed resistor and a variable resistor to convert the light output current to a common value in the first light output state and in the second light output state, and converting the converted light output current It is characterized by outputting.

  Further, the light output control method according to the present invention detects the average value of the light output current output by the current switching step, and outputs the light output current of the detected average value to the light output control. The current-voltage conversion step performed by the apparatus is characterized in that the output voltage value corresponding to the light output current is converted based on the light output current output by the average value detection step.

  An optical output control program according to the present invention is an optical output control program that is executed in an optical output control device that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature. When the light output state of the laser diode is switched between the first light output state and the second light output state to control the light output state of the laser diode, the first light output state and the second light output are controlled. A bias current is determined using a common reference voltage value at the time of the state, and a process for performing temperature compensation control of the laser diode using the determined bias current is executed by the light output control device. It is.

  According to the present invention, when the light output state of the laser diode is switched between the first light output state and the second light output state to control the light output state of the laser diode, the second light output state and the second light output state are controlled. The bias current is determined using a common reference voltage value in the optical output state, and temperature compensation control of the laser diode is performed using the determined bias current. As a result, the bias current used when the temperature compensation control is performed is determined using the common reference voltage value in the first light output state and in the second light output state. It becomes possible to reduce the complexity of control.

  First, the features of the light output control circuit in this embodiment will be described with reference to FIG.

  The light output control circuit in the present embodiment is a light output control circuit that performs temperature compensation control of the laser diode (1) using the bias current (8) adjusted according to the ambient temperature and the pulse current (7). When controlling the light output state of the laser diode (1) by switching the light output state of the laser diode (1) between the first light output state (OUT1) and the second light output state (OUT2). The bias current (8) is determined using the common reference voltage value (11) in the optical output state (OUT1) and the second optical output state (OUT2), and the determined bias current (8) is And temperature compensation control of the laser diode (1). As a result, the bias current (8) used when the temperature compensation control is performed is the common reference voltage value (11) in the first light output state (OUT1) and in the second light output state (OUT2). Therefore, it is possible to reduce the complexity of the temperature compensation control. Hereinafter, the light output control circuit according to the present embodiment will be described in detail with reference to the accompanying drawings.

  First, the configuration of the light output control circuit in the present embodiment will be described with reference to FIG.

  As shown in FIG. 1, the light output control circuit in the present embodiment includes an LD (Laser Diode) (1), a monitor PD (Photo Diode) (2), an I / V conversion circuit (9), and a comparison amplifier. (10), a reference voltage (11), a bias current control circuit (8), a pulse current control circuit (7), a switching control unit (6), a first switch (5), a temperature sensor ( 12), an A / D converter (13), a memory (14), a plurality of D / A converters (15 to 17), and a current switching circuit (3).

  As shown in FIG. 1, the light output control circuit in this embodiment has a current switching circuit (3), and the light output current output from the monitor PD (2) is converted into the light output of the LD (1). Control is performed so that the optical output current has a common value in the first optical output state (OUT1) and in the second optical output state (OUT2), and the controlled optical output current is converted to I / V. By outputting to the circuit (9), the bias current (8) is generated using the common reference voltage value (11) in the first light output state (OUT1) and in the second light output state (OUT2). The temperature compensation control of the LD (1) is performed using the determined bias current (8).

  1 includes a switch (4), a first transistor (3A), a second transistor (3B), a fixed resistor (3D), and a variable resistor (3E). And a second fixed resistor (3C).

  In the current switching circuit (3) shown in FIG. 1, the first transistor (3A) and the second transistor (3B) constitute a current mirror circuit, and the first transistor (3A) ) Is connected to the power source (Vcc) via the second fixed resistor (3C), and the collector terminal side is connected to the cathode side of the monitor PD (2).

  The emitter terminal side of the second transistor (3B) is connected to the fixed resistor (3D) and the variable resistor (3E). The variable resistor (3E) is a resistor that determines the light output ratio between the first light output state (OUT1) and the second light output state (OUT2).

  The switch (4) is connected to the fixed resistor (3D) and the variable resistor (3E), and based on the control signal output from the switching control unit (6), the fixed resistor (3D) or the variable resistor (3E) And the selected resistor is connected to the power supply (Vcc). The control signal output from the switching control unit (6) to the switch (4) is a signal for connecting either the fixed resistor (3D) or the variable resistor (3E) to the power source (Vcc). This control signal is set by a user operation or the like.

  The collector terminal side of the second transistor (3B) is connected to the I / V conversion circuit (9). The photodetection current of the monitor PD (2) controlled by the current switching circuit (3) is output to the I / V conversion circuit (9), and the I / V conversion circuit (9) The voltage value corresponding to the value is converted, and the converted voltage value is output to the comparison amplifier (10).

  The comparison amplifier (10) has a difference value (| output voltage value−reference voltage value) between the output voltage value output from the I / V conversion circuit (9) and the reference voltage value output from the reference voltage (11). |) Is calculated, the calculated difference value is amplified, and the amplified difference voltage value is output to the bias current control circuit (8).

  The bias current control circuit (8) outputs the output voltage value output from the I / V conversion circuit (9) and the reference voltage (11) based on the differential voltage value output from the comparison amplifier (10). The bias current flowing through the LD (1) is controlled so that the reference voltage value is equal to the voltage value.

  The temperature sensor (12) detects the ambient temperature, generates a voltage value corresponding to the detected ambient temperature, and outputs an analog temperature signal corresponding to the generated voltage value to the A / D converter (13). To do.

  The A / D converter (13) converts the analog temperature signal output from the temperature sensor (12) into a digital value, and outputs the converted digital value to the memory (14).

  In the memory (14), a management table in which the setting data of the pulse current for OUT1 and the address value corresponding to the ambient temperature are managed in association with each other, the setting data of the pulse current for OUT2 and the address corresponding to the ambient temperature Management table in which values are managed in association with each other, management data in which setting data of a common bias current (reference voltage) for OUT1 and OUT2 and address values corresponding to the ambient temperature are managed in association with each other And a digital value obtained by digitally converting the temperature signal indicating the ambient temperature detected by the temperature sensor (12) is input to the memory (14) via the digital A / D converter (13). At this time, the memory (14) sends the setting data corresponding to the address value corresponding to the digital value to the D / A converter (1 , It will be output to the 16, 17). In this case, pulse current setting data for OUT1 is output to the D / A converter (15), and pulse current setting data for OUT2 is output to the D / A converter (16). The common bias current setting data for OUT1 and OUT2 is output to the converter (17).

  The first switch (5), based on the control signal from the switching controller (6), sets the pulse current setting data for OUT1 output from the D / A converter (15) and D / A conversion. The pulse current setting data for OUT2 output from the device (16) and any pulse current setting data are output to the pulse current control circuit (7). Thereby, the pulse current control circuit (7) controls the light output of the LD (1) based on the pulse current corresponding to the setting data output from the first switch (5). The control signal output from the switching control unit (6) to the first switch (5) is sent from either the D / A converter (15) or the D / A converter (16). This is a signal for causing the pulse current control circuit (7) to output the setting data of the output pulse current, and this control signal is set by an operation from the user or the like.

  Also, common bias current setting data for OUT1 and OUT2 output from the D / A converter (17) is output to the reference voltage (11). Accordingly, the reference voltage (11) is set to a reference voltage value corresponding to the setting data output from the D / A converter (17), and the bias current control circuit (8) is set to the reference voltage (11). The bias current flowing through the LD (1) is adjusted so that the adjusted reference voltage value and the output voltage value output from the I / V conversion circuit (9) are equal, and the adjusted bias current Based on this, the light output of the LD (1) is controlled.

  Next, a control operation in the light output control circuit according to the present embodiment will be described with reference to FIG.

  In the following control operation, the resistance ratio of the second fixed resistor (3C), the fixed resistor (3D), and the variable resistor (3E) constituting the current switching circuit (3) is changed to the second fixed resistor. (3C): Fixed resistance (3D): Variable resistance (3E) = 1: 1: n (n> 1).

  In the optical output control circuit according to the present embodiment, the monitor PD (2) receives at least one portion of the optical signal output from the LD (1), and sets the optical output state of the optical signal output from the LD (1). The corresponding photodetection current is output to the current switching circuit (3). The current switching circuit (3) controls the photodetection current output from the monitor PD (2) and outputs the controlled photodetection current to the I / V conversion circuit (9). The I / V conversion circuit (9) converts the photodetection current output from the current switching circuit (3) into a voltage value corresponding to the photodetection current value, and converts the converted voltage value into a comparison amplifier ( To 10).

  The comparison amplifier (10) compares the output voltage value output from the I / V conversion circuit (9) and the reference voltage value output from the reference voltage (11), and the output voltage value and the reference voltage value. Is output to the bias current control circuit (8).

  The bias current control circuit (8) outputs the output voltage value output from the I / V conversion circuit (9) and the reference voltage (11) based on the differential voltage value output from the comparison amplifier (10). The bias current flowing through the LD (1) is controlled so that the reference voltage value becomes equal to the voltage value.

  Thus, the light output control circuit in the present embodiment includes the monitor PD (2), the current switching circuit (3), the I / V conversion circuit (9), the comparison amplifier (10), and the reference voltage (11 ) And the bias current control circuit (8) constitute a negative feedback control circuit, and the LD (1) outputs an optical signal corresponding to the reference voltage value output from the reference voltage (11). .

<When Fixed Resistor 3D is Connected to Power Supply (Vcc)>
In the light output control circuit constituting the negative feedback control circuit described above, first, the switch (4) selects the fixed resistance (3D) based on the control signal from the switching control section (6), and the fixed resistance (3D ) Is connected to the power supply (Vcc).

  In this case, the ratio of the emitter current flowing through the first transistor (3A) to the emitter current flowing through the second transistor (3B) is the resistance value of the second fixed resistor (3C) and the fixed resistor (3D). In this embodiment, since the second fixed resistance (3C): fixed resistance (3D) = 1: 1, the photodetection current of the monitor PD (2) and the I / V The current flowing through the conversion circuit (9) is equal.

  When the reference voltage value output from the reference voltage (11) by the negative feedback control is equal to the output voltage value output from the I / V conversion circuit (9), the current switching circuit (3 ) To I / V conversion circuit (9) is assumed to be I1.

<When the variable resistor 3E is connected to the power source (Vcc)>
Next, the case where the switch (4) selects the variable resistor (3E) and the variable resistor (3E) is connected to the power source (Vcc) based on the control signal from the switching control unit (6) will be described. .

  In this case, the ratio of the emitter current flowing through the first transistor (3A) to the emitter current flowing through the second transistor (3B) is the resistance value of the second fixed resistor (3C) and the variable resistor (3E). In this embodiment, since the second fixed resistance (3C): variable resistance (3E) = 1: n, the emitter current flowing through the first transistor (3A): first The emitter current flowing through the second transistor (3B) = n: 1.

  In order to set the current value flowing through the I / V conversion circuit (9) to I1 with respect to the reference voltage value output from the reference voltage (11) by feedback control, the emitter flowing through the first transistor (3A) The current, that is, the light detection current of the monitor PD (2) needs to be n × I1, and the light output state of the LD (1) is the case where the fixed resistor (3D) is selected by the switch (4). n times. This light output ratio can be arbitrarily set by the resistance value of the variable resistor (3E), and is kept constant regardless of the ambient temperature detected by the temperature sensor (12).

  That is, the light detection current output from the monitor PD (2) is converted to n (n is an arbitrary positive real number) times by using the switch (4), and the light output state of the LD (1) is OUT1 and OUT2. And setting data for determining a bias current for performing temperature compensation control by controlling the optical output current to be output to the I / V conversion circuit (9) in the optical output state. In association with the address value corresponding to the ambient temperature, setting data for determining the bias current for performing the temperature compensation control without managing in the management table for each light output state of OUT1 and OUT2 In association with an address value corresponding to the ambient temperature, it is possible to manage by one management table common to the optical output states of OUT1 and OUT2. Then, one management table common to the optical output states of the OUT1 and OUT2 is stored in the memory (14). The memory (14) stores the OUT1 and OUT1 corresponding to the address value of the ambient temperature detected by the temperature sensor (12). The setting data of the bias current common to OUT2 is output to the D / A converter (17), and the setting data output to the D / A converter (17) is output to the reference voltage (11). Become. Thereby, the reference voltage (11) sets a reference voltage value corresponding to the setting data output from the D / A converter (17), and the bias current control circuit (8) sets the reference voltage (11). The bias current flowing through the LD (1) is adjusted so that the adjusted reference voltage value and the output voltage value output from the I / V conversion circuit (9) are equal, and the adjusted bias current Based on this, the light output of the LD (1) is controlled.

  Further, when the light output state of LD (1) is the light output state of OUT1 and OUT2, the setting data of the pulse current for realizing a desired extinction ratio is associated with the address value corresponding to the ambient temperature, and OUT1 And OUT2 are managed in the management table for each light output state, and the management table for each light output state of OUT1 and OUT2 is stored in the memory (14), and the memory (14) is stored in the temperature sensor (14). The output data of the pulse current of OUT1 corresponding to the address value of the ambient temperature detected by 12) is output to the D / A converter (15), and OUT2 corresponding to the address value of the ambient temperature detected by the temperature sensor (12). The pulse current setting data is output to the D / A converter (16). Then, the first switch (5), based on the control signal from the switching control unit (6), sets the setting data of the pulse current of OUT1 output from the D / A converter (15) or the D / A One of the pulse current setting data of OUT2 output from the converter (16) is output to the pulse current control circuit (7), and the pulse current control circuit (7) to the LD (1). The pulse current to be output is determined.

  As described above, the light output control circuit in the present embodiment converts the light output current output from the monitor PD (2) in the current switching circuit (3), and the light output state of the LD (1) is OUT1 and OUT2. By controlling so that a common optical output current is output to the I / V conversion circuit (9) in the optical output state, the optical output state of the LD (1) is common in the optical output states of OUT1 and OUT2. It is possible to perform temperature compensation control of the optical output power in the optical output state of OUT1 and OUT2 output from the LD (1) using the bias current setting data. Accordingly, it is only necessary to prepare one management table for managing the setting data of the bias current for performing the temperature compensation control, and the bias current for performing the temperature compensation control as in the conventional optical output control circuit is prepared. Since it is not necessary to prepare a management table for managing setting data for each light output state of OUT1 and OUT2, the complexity of temperature compensation control can be reduced. Further, the temperature compensation control can be performed only by storing one less management table than the conventional light output control circuit in the memory (14), so that the memory space can be reduced.

(Second Embodiment)
Next, a second embodiment will be described.

  The light output control circuit in the first embodiment connects the current switching circuit (3) to the cathode side of the monitor PD (2), converts the light output current output from the monitor PD (2), and outputs OUT1 and OUT2. In the optical output state, the optical output current having a common value is controlled to be output to the I / V conversion circuit (9), but the optical output control circuit in the second embodiment is as shown in FIG. The current switching circuit (3) is connected to the anode side of the monitor PD (2), the light output current output from the monitor PD (2) is converted, and a common value is obtained in the light output state of OUT1 and OUT2. The optical output current is controlled to be output to the I / V conversion circuit (9). Thereby, similarly to the light output control circuit in the first embodiment, it is possible to reduce the complexity of the temperature compensation control and to reduce the memory space. The light output control circuit according to the second embodiment will be described below with reference to FIG.

  As shown in FIG. 2, the light output control circuit in the second embodiment is configured by connecting the current switching circuit (3) to the anode side of the monitor PD (2).

  In addition, as shown in FIG. 2, the current switching circuit (3) in the second embodiment includes a first transistor (3A), a second transistor (3B), a third transistor (3F), Fourth transistor (3G), fixed resistor (3D), variable resistor (3E), second fixed resistor (3C), third fixed resistor (3H), and fourth fixed resistor (3I) ) And a switch (4) for selecting a fixed resistor (3D) or a variable resistor (3E).

  The collector terminal side of the first transistor (3A) is connected to the anode side of the monitor PD (2), and the emitter terminal side of the first transistor (3A) is connected via the second fixed resistor (3C). Are connected to ground (GND).

  The collector terminal side of the second transistor (3B) is connected to the collector terminal side of the third transistor (3F), and the emitter terminal side of the second transistor (3B) is a fixed resistor (3D), The fixed resistor (3D) or the variable resistor (3E) selected by the switch (4) is connected to the ground (GND).

  The collector terminal side of the third transistor (3F) is connected to the collector terminal side of the second transistor (3B), and the emitter terminal side of the third transistor (3F) is connected to the third fixed resistor (3H). ) To the cathode side of the monitor PD (2) and the power source (Vcc).

  The collector terminal side of the fourth transistor (3G) is connected to the I / V conversion circuit (9), and the emitter terminal side of the fourth transistor (3G) is connected via the fourth fixed resistor (3I). The monitor PD (2) is connected to the cathode side and the power source (Vcc).

  As described above, the light output control circuit according to the second embodiment has a circuit configuration as shown in FIG. 2 even when the current switching circuit (3) is connected to the anode side of the monitor PD (2). Thus, as in the first embodiment, the optical output current output from the monitor PD (2) is converted, and the optical output current having a common value in the optical output state of OUT1 and OUT2 is converted to I / V. It is possible to output to the conversion circuit (9).

(Third embodiment)
Next, a third embodiment will be described.

  As shown in FIG. 3, the light output control circuit in the third embodiment connects the current switching circuit (3) to the anode side of the monitor PD (2) as in the light output control circuit in the second embodiment. Further, the variable resistor (3E) and the switch (4) constituting the power supply switching circuit (3) are connected to the power supply (Vcc) side. As a result, similarly to the light output control circuits in the first and second embodiments, the complexity of the temperature compensation control can be reduced and the memory space can be reduced. The light output control circuit according to the third embodiment will be described below with reference to FIG.

  As shown in FIG. 3, the light output control circuit in the third embodiment is configured by connecting the current switching circuit (3) to the anode side of the monitor PD (2).

  In addition, as shown in FIG. 3, the current switching circuit (3) in the third embodiment includes a first transistor (3A), a second transistor (3B), a third transistor (3F), Fourth transistor (3G), fixed resistor (3D), variable resistor (3E), second fixed resistor (3C), third fixed resistor (3H), and fourth fixed resistor (3I) ) And a switch (4) for selecting a fixed resistor (3D) or a variable resistor (3E).

  The collector terminal side of the first transistor (3A) is connected to the anode side of the monitor PD (2), and the emitter terminal side of the first transistor (3A) is connected via the third fixed resistor (3H). Are connected to ground (GND).

  The collector terminal side of the second transistor (3B) is connected to the collector terminal side of the third transistor (3F), and the emitter terminal side of the second transistor (3B) is connected to the fourth fixed resistor (3I). ) Is connected to the ground (GND).

  The collector terminal side of the third transistor (3F) is connected to the collector terminal side of the second transistor (3B), and the emitter terminal side of the third transistor (3F) is connected to the second fixed resistor (3C). ) To the cathode side of the monitor PD (2) and the power source (Vcc).

  The collector terminal side of the fourth transistor (3G) is connected to the I / V conversion circuit (9), and the emitter terminal side of the fourth transistor (3G) is connected to the fixed resistor (3D) and the variable resistor ( 3E), and the fixed resistor (3D) or variable resistor (3E) selected by the switch (4) is connected to the cathode side of the monitor PD (2) and the power supply (Vcc). .

  As described above, the light output control circuit according to the third embodiment has a circuit configuration as shown in FIG. 3 even when the current switching circuit (3) is connected to the anode side of the monitor PD (2). Thus, as in the first embodiment, the optical output current output from the monitor PD (2) is converted, and the optical output current having a common value in the optical output state of OUT1 and OUT2 is converted to I / V. It is possible to output to the conversion circuit (9).

(Fourth embodiment)
Next, a fourth embodiment will be described.

  As shown in FIGS. 4 to 6, the light output control circuit in the fourth embodiment detects the average value of the light output current output from the current switching circuit (3), and the light output of the detected average value. It has an average value detector (20) that outputs current to the I / V conversion circuit (9). Thereby, the optical output current output from the current switching circuit (3) can be averaged, and the averaged optical output current can be output to the I / V conversion circuit (9).

  FIG. 4 shows the configuration when the average value detector (20) is mounted on the light output control circuit in the first embodiment, and FIG. 5 shows the light output control circuit in the second embodiment. On the other hand, the configuration when the average value detector (20) is mounted is shown, and FIG. 6 shows the configuration when the average value detector (20) is mounted on the light output control circuit in the third embodiment. Is.

  The above-described embodiment is a preferred embodiment of the present invention, and the scope of the present invention is not limited to the above-described embodiment alone, and various modifications are made without departing from the gist of the present invention. Implementation is possible.

  For example, in the light output control circuit in the above-described embodiment, the table configuration of the management table managed in the memory (14) is not particularly limited, and is used when temperature compensation control of the LD (1) is performed. Pulse current and bias current setting data and address values corresponding to the ambient temperature can be managed in association with each other, and the pulse current used when performing temperature compensation control using any management method The bias current setting data and the address value corresponding to the ambient temperature are managed in association with each other, and the temperature compensation control of the LD (1) can be performed using the managed setting data.

  In addition, the control operation in the light output control circuit in the above-described embodiment can be executed by software such as a computer program instead of a hardware configuration, and the above program is stored in an optical recording medium, a magnetic recording medium, The above-described control operation is executed in the light output control device by recording the information on a magneto-optical recording medium or a recording medium such as a semiconductor, and causing the light output control device that performs light output control to read the program from the recording medium. It is also possible to make it. It is also possible to cause the light output control device to execute the control operation described above by causing the light output control device to read the program from an external device connected via a predetermined network.

  The light output control circuit, the light output control method, and the light output control program according to the present invention are applicable to an optical communication apparatus that performs communication using an optical signal.

It is a figure which shows the structure of the light output control circuit in 1st Embodiment. It is a figure which shows the structure of the light output control circuit in 2nd Embodiment. It is a figure which shows the structure of the light output control circuit in 3rd Embodiment. It is a figure which shows the 1st structure of the light output control circuit in 4th Embodiment, and is a case where the average value detector (20) is mounted with respect to the light output control circuit in 1st Embodiment shown in FIG. It is a figure which shows a structure. It is a figure which shows the 2nd structure of the light output control circuit in 4th Embodiment, and the case where an average value detector (20) is mounted with respect to the light output control circuit in 2nd Embodiment shown in FIG. It is a figure which shows a structure. It is a figure which shows the 3rd structure of the light output control circuit in 4th Embodiment, and is a case where an average value detector (20) is mounted with respect to the light output control circuit in 3rd Embodiment shown in FIG. It is a figure which shows a structure. It is a figure which shows the structure of the conventional light output control circuit. It is a figure which shows the table structure of the management table stored in the memory (14) which comprises an optical output control circuit, (a) is the setting data of the pulse current for performing temperature compensation control of LD (1). FIG. 6B is a diagram managed in association with an address value corresponding to the ambient temperature, and FIG. 6B is an address value in which the setting data of the pulse current for performing the temperature compensation control of the LD (1) corresponds to the ambient temperature. It is a figure managed in association with.

Explanation of symbols

1 LD (Laser Diode)
2 Monitor PD (Photo Diode)
DESCRIPTION OF SYMBOLS 3 Current switching circuit 4 Switch 5 1st switch 6 Switching control part 7 Pulse current control circuit 8 Bias current control circuit 9 I / V conversion circuit 10 Comparison amplifier 11 Reference voltage 12 Temperature sensor 13 A / D converter 14 Memory 15, 16, 17, 18 D / A converter 19 2nd switch 3A 1st transistor 3B 2nd transistor 3F 3rd transistor 3G 4th transistor 3C 2nd fixed resistance 3D fixed resistance 3E variable resistance 3H 3rd Fixed resistance of 3I Fourth fixed resistance

Claims (24)

A light output control circuit that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature,
When the light output state of the laser diode is switched between the first light output state and the second light output state to control the light output state of the laser diode, the second light output state and the second light output state are controlled. An optical output control circuit, wherein the bias current is determined using a common reference voltage value in the optical output state of the laser, and temperature compensation control of the laser diode is performed using the determined bias current. A temperature sensor for detecting the ambient temperature;
The value of the first pulse current used in the first light output state is managed in association with the ambient temperature, and the value of the first pulse current according to the ambient temperature detected by the temperature sensor is output. A first management means;
The second pulse current value used in the second light output state is managed in association with the ambient temperature, and the second pulse current value corresponding to the ambient temperature detected by the temperature sensor is output. A second management means;
A bias current value commonly used in the first light output state and the second light output state is managed in association with the ambient temperature, and the value corresponding to the ambient temperature detected by the temperature sensor is Third management means for outputting a value of the bias current;
The pulse current is determined based on any one of the first pulse current value and the second pulse current value, and the laser diode is determined using the determined pulse current. Pulse current control means for performing temperature compensation control of;
A bias current control means for determining the bias current using the value of the bias current as the common reference voltage value, and performing temperature compensation control of the laser diode using the determined bias current;
The light output control circuit according to claim 1, further comprising: Selecting means for selecting any one of the value of the first pulse current and the value of the second pulse current;
The pulse current control means includes
3. The light output control circuit according to claim 2, wherein the pulse current is determined based on a value of the pulse current selected by the selection means. A monitor photodiode that outputs a light output current corresponding to a light output state of the laser diode;
The monitor photodiode is
A light output current of a different value is output between the first light output state and the second light output state;
The bias current control means includes
The light output current output from the monitor photodiode is converted into a light output current having a common value in the first light output state and in the second light output state, and the converted light output current is converted into the converted light output current. The bias current is determined so that a corresponding output voltage value and the reference voltage value are equal to each other, and temperature compensation control of the laser diode is performed using the determined bias current. The light output control circuit according to claim 2. The bias current control means includes
The optical output current output from the monitor photodiode is amplified by n (n is an arbitrary positive real number) times, and is common between the first optical output state and the second optical output state. 5. The optical output control circuit according to claim 4, wherein the optical output current is converted into a value optical output current. The light output current output from the monitor photodiode is converted into a light output current having a common value in the first light output state and in the second light output state, and the converted light output current is Current switching means for outputting;
Based on the optical output current output from the current switching means, current-voltage conversion means for converting into an output voltage value corresponding to the optical output current;
The output voltage value converted by the current-voltage conversion means is compared with the reference voltage value, a difference value that is a difference between the output voltage value and the reference voltage value is calculated, and the calculated difference value is amplified. And a comparison amplification means for outputting the differential voltage value obtained,
The bias current control means includes
Based on the differential voltage value amplified by the comparison amplification means, the bias current is determined so that the output voltage value and the reference voltage value are equal to each other, and the determined bias current is used. 6. The light output control circuit according to claim 4, wherein temperature compensation control of the laser diode is performed. The current switching means is
A fixed resistor and a variable resistor;
The fixed resistor and the variable resistor are switched between the first light output state and the second light output state to switch between the first light output state and the second light output state. 7. The light output control circuit according to claim 6, wherein the light output current is converted into a light output current having a value common to the time and the converted light output current is output. Detecting an average value of the light output current output from the current switching means, and having an average value detection means for outputting the detected light output current of the average value to the current-voltage conversion means,
The current-voltage conversion means includes
8. The light output control circuit according to claim 6, wherein the light output control circuit converts the output voltage value according to the light output current output from the average value detecting means.   8. The light output control circuit according to claim 6, wherein the current switching means is connected to a cathode side of the monitor photodiode. The current switching means is
A first transistor, a second transistor, the fixed resistor, the variable resistor, a second fixed resistor, and a switch that selects the fixed resistor or the variable resistor.
The collector terminal side of the first transistor is connected to the cathode side of the monitor photodiode, and the emitter terminal side of the first transistor is connected to a power source via the second fixed resistor,
The collector terminal side of the second transistor is connected to the current-voltage conversion means, and the emitter terminal side of the second transistor is connected to the fixed resistor and the variable resistor, and is selected by the switch. 10. The light output control circuit according to claim 9, wherein the light output control circuit is configured by connecting the fixed resistor or the variable resistor to a power source.   8. The light output control circuit according to claim 6, wherein the current switching means is connected to the anode side of the monitor photodiode. The current switching means is
A first transistor; a second transistor; a third transistor; a fourth transistor; the fixed resistor; the variable resistor; a second fixed resistor; a third fixed resistor; A fixed resistor and a switch for selecting the fixed resistor or the variable resistor,
The collector terminal side of the first transistor is connected to the anode side of the monitor photodiode, and the emitter terminal side of the first transistor is connected to the ground via the second fixed resistor,
The collector terminal side of the second transistor is connected to the collector terminal side of the third transistor, the emitter terminal side of the second transistor is connected to the fixed resistor and the variable resistor, Connecting the fixed resistor or the variable resistor selected by a switch to ground;
The collector terminal side of the third transistor is connected to the collector terminal side of the second transistor, and the emitter terminal side of the third transistor is connected to the monitor photodiode via the third fixed resistor. Connect to the cathode side and the power supply,
The collector terminal side of the fourth transistor is connected to the current-voltage conversion means, and the emitter terminal side of the fourth transistor is connected to the cathode side of the monitor photodiode via the fourth fixed resistor, The light output control circuit according to claim 11, wherein the light output control circuit is connected to a power source. The current switching means is
A first transistor; a second transistor; a third transistor; a fourth transistor; the fixed resistor; the variable resistor; a second fixed resistor; a third fixed resistor; A fixed resistor and a switch for selecting the fixed resistor or the variable resistor,
The collector terminal side of the first transistor is connected to the anode side of the monitor photodiode, and the emitter terminal side of the first transistor is connected to the ground via the third fixed resistor,
The collector terminal side of the second transistor is connected to the collector terminal side of the third transistor, the emitter terminal side of the second transistor is connected to the ground via the fourth fixed resistor,
The collector terminal side of the third transistor is connected to the collector terminal side of the second transistor, and the emitter terminal side of the third transistor is connected to the monitor photodiode via the second fixed resistor. Connect to the cathode side and the power supply,
The collector terminal side of the fourth transistor is connected to the current-voltage conversion means, and the emitter terminal side of the fourth transistor is connected to the fixed resistor and the variable resistor, and is selected by the switch. 12. The light output control circuit according to claim 11, wherein the fixed resistor or the variable resistor is connected to a cathode side of the monitor photodiode and a power source.   3. The light output control circuit according to claim 2, wherein the first management unit, the second management unit, and the third management unit are managed in a common memory space.   15. The optical output control circuit according to claim 1 is mounted, an optical signal used for communication is controlled by the optical output control circuit, and communication is performed using the controlled optical signal. An optical communication device characterized in that A light output control method performed in a light output control device that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature,
When the light output state of the laser diode is switched between the first light output state and the second light output state to control the light output state of the laser diode, the second light output state and the second light output state are controlled. The optical output control device performs a step of determining the bias current using a common reference voltage value in the optical output state of the laser and performing temperature compensation control of the laser diode using the determined bias current. A light output control method characterized by the above. The light output control device comprises:
First management means for managing the value of the first pulse current used in the first light output state in association with the ambient temperature;
Second management means for managing the value of the second pulse current used in the second light output state in association with the ambient temperature;
And third management means for managing a bias current value commonly used in the first light output state and in the second light output state in association with an ambient temperature,
A temperature detection step for detecting the ambient temperature;
A first output step of acquiring a value of a first pulse current corresponding to the ambient temperature detected by the temperature detection step from the first management means, and outputting the acquired value of the first pulse current;
A second output step of acquiring a value of the second pulse current corresponding to the ambient temperature detected by the temperature detection step from the second management means, and outputting the acquired value of the second pulse current;
A third output step of acquiring a value of a bias current corresponding to the ambient temperature detected by the temperature detection step from the third management means, and outputting the acquired value of the bias current;
Based on one of the pulse current values of the first pulse current value output by the first output step and the second pulse current value output by the second output step, A pulse current control step of determining the pulse current and performing temperature compensation control of the laser diode using the determined pulse current;
The bias current value output in the third output step is used as the common reference voltage value, the bias current is determined, and temperature compensation control of the laser diode is performed using the determined bias current. A bias current control step;
The light output control method according to claim 16, wherein the light output control device performs the following. The light output control device performs a selection step of selecting any one of the value of the first pulse current and the value of the second pulse current,
The pulse current control step includes
18. The light output control method according to claim 17, wherein the pulse current is determined based on a value of the pulse current selected in the selection step. The light output control device comprises:
A monitor photodiode that outputs a light output current corresponding to a light output state of the laser diode;
The monitor photodiode is
A light output current of a different value is output between the first light output state and the second light output state;
The bias current control step includes
The light output current output from the monitor photodiode is converted into a light output current having a common value in the first light output state and in the second light output state, and the converted light output current is converted into the converted light output current. The bias current is determined so that a corresponding output voltage value and the reference voltage value are equal to each other, and temperature compensation control of the laser diode is performed using the determined bias current. The light output control method according to claim 17. The bias current control step includes
The optical output current output from the monitor photodiode is amplified by n (n is an arbitrary positive real number) times, and is common between the first optical output state and the second optical output state. 20. The light output control method according to claim 19, wherein the light output current is converted into a value of light output current. The light output current output from the monitor photodiode is converted into a light output current having a common value in the first light output state and in the second light output state, and the converted light output current is An output current switching step;
Based on the optical output current output by the current switching step, a current-voltage conversion step of converting the output voltage value according to the optical output current;
The output voltage value converted by the current-voltage conversion step is compared with the reference voltage value, a difference value that is a difference between the output voltage value and the reference voltage value is calculated, and the calculated difference value is amplified. A comparison amplification step of outputting the differential voltage value, and the light output control device performs,
The bias current control step includes
Based on the differential voltage value amplified in the comparative amplification step, the bias current is determined so that the output voltage value and the reference voltage value are equal to each other, and the determined bias current is used. 21. The light output control method according to claim 19, wherein temperature compensation control of the laser diode is performed. The light output control device comprises:
A fixed resistor and a variable resistor;
The current switching step includes
The fixed resistor and the variable resistor are switched between the first light output state and the second light output state to switch between the first light output state and the second light output state. 24. The light output control method according to claim 21, wherein the light output current is converted into a light output current having a common value and the converted light output current is output. The light output control device performs an average value detection step of detecting an average value of the light output current output by the current switching step and outputting a light output current of the detected average value,
The current-voltage conversion step includes
23. The light output control method according to claim 21, wherein the light output current output by the average value detection step is converted into an output voltage value corresponding to the light output current. A light output control program to be executed in a light output control device that performs temperature compensation control of a laser diode using a bias current and a pulse current adjusted according to an ambient temperature,
When the light output state of the laser diode is switched between the first light output state and the second light output state to control the light output state of the laser diode, the second light output state and the second light output state are controlled. The bias output is determined using a common reference voltage value in the optical output state of the laser, and the optical output control device is caused to perform temperature compensation control of the laser diode using the determined bias current A light output control program characterized by that.

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