RU186569U1 - Analog diode laser control module - Google Patents

Abstract

The technical solution relates to laser technology, in particular to control modules for a semiconductor laser. The analog module for controlling the diode laser is made according to the electric circuit for controlling the laser current to form a given waveform. The device contains electronic circuits located on a printed circuit board and connected by electrically conductive circuits: voltage follower (A1), dual operational amplifier (A 2.1), dual amplifier (A2.2), DC / DC converter (A3), Darlington transistor (VT1), resistors ( R1-R9), capacitors (C1-C9), inductance coil (L1), switch (SW1), socket (BNS) for connecting the oscilloscope. The electrical circuit of the device is shown in figure 1. The technical result consists in providing the ability to control the shape of the emitted pulse and high reproducibility of the radiation parameters. The achievement of the technical result provides additional modulation of the current during the pulse, which makes it possible for one pulse to scan the region in the region of the absorption line of the analyzed gas; the autonomous nature of the module, which makes it possible to integrate it into various modifications of gas detection systems. 3 ill., 2 tablets

Description

The technical field to which the utility model relates.

The technical solution relates to the field of safety systems for transporting and storing gas using an active tunable diode laser. The main application of such systems: remote measurement of the concentration of various gases in the atmosphere. Main purpose: methane detection in order to detect natural gas leaks from high and low pressure gas pipelines and other natural and industrial sources of methane. The systems can be used on open gas platforms of gas compressor stations, liquefied gas terminals, etc., as well as, with a certain modification, at metallurgical enterprises for the detection of coke oven, blast furnace and converter gases. This technical solution itself is an active laser control module and is an integral part of these systems

State of the art

Known semiconductor laser described in patent RU 2172514, class. G05D 6/02, H01S 5/06, 2001.08.20, “Semiconductor Laser Driver”.

The known device comprises a pump current regulator for a semiconductor laser, a semiconductor laser itself, a current sensor, a direct laser radiation power sensor, a laser temperature sensor, differential, linear and exponential amplifiers, an adder, a discriminator and inputs for the control voltage and for setting the maximum current signal.

The prior art device is also known for controlling a laser diode (options) (RU 2222078, H01S5 / 00, H01S5 / 026, publ. 20.01.2004). The control device for a semiconductor laser diode with a grounded cathode is designed for high-speed modulation of the optical radiation of a laser diode with digital or analog signals, for primary use in optical communication systems. The proposed laser diode control device comprises a start-up and stabilization circuit connected to it and a modulation unit made with an open collector or open emitter circuit, the output of which is connected to the laser diode. In this case, the device, depending on the implementation variant, is equipped with various correcting chains, which are made in the form of active resistances and capacitors, the parameters of which are selected according to certain experimentally mathematical dependencies, and the elements of the chains are placed and connected depending on the type of modulation block.

Utility Model Disclosure

The problem solved by the claimed utility model is to create a device with the ability to control the laser current to generate the waveform necessary to modulate the radiation at a specific wavelength with a specific waveform, with the ability to scan the wavelength for each pulse.

The technical result of the claimed utility model is to provide the possibility of regulating the shape of the emitted pulse and the high reproducibility of the radiation parameters.

The technical result of the claimed utility model is achieved due to the fact that the analog diode laser control module, made according to the electric circuit for controlling the laser current to generate a given waveform, contains a direct current converter connected to an external DC power source, while the circuit from the converter to a pair of capacitors is connected in parallel with the power source, and an inductor is connected in series to the positive output of the power source, and the converter outputs DC current are connected to the modulated circuit of the converted supply current, made in the form of two pairs of capacitors connected in parallel and connected in series between the pairs of capacitors to the active load, with one output of the converted current modulating circuit being grounded, and the second output of the converted current modulating circuit connected to three branches: to the input of the voltage follower, which is connected to ground through a series-connected capacitor; to the input of a dual operational amplifier, which is also connected to ground through a series-connected capacitor; to the collector of the Darlington transistor, the module contains a laser current control circuit consisting of an input voltage divider made in the form of a series-connected load and a parallel connected load, and a capacitor, a voltage follower, a dual voltage amplifier and a Darlington transistor, one output of the input voltage divider with the second input of the voltage follower, and the second output of the voltage divider is grounded, the third input of the voltage follower is closed to the output of the voltage follower the second output of the voltage follower is grounded, and the output of the voltage follower is connected to the first input of the dual voltage amplifier through a series-connected load, while the output of the double voltage amplifier is connected to the base of the Darlington transistor, the emitter of which is connected through a series-connected load to the switch and to the first input of the repeater voltage, the second input of which is closed to the output of the said voltage follower, and the output of the voltage follower through successively sub The connected load is connected to the input of the dual operational amplifier, while the second output of the dual amplifier of the operational amplifier is grounded, and the third input is grounded and connected through a series-connected load to the switch through a series-connected load pair.

Brief Description of the Drawings

Details, features, as well as advantages of this utility model follow from the following description of the implementation options of the claimed technical solution using the drawings, which show:

FIG. 1 is a circuit diagram of a laser current control module.

FIG. 2 - general view of the module from the component side

FIG. 3 is a general view of the module from the side of the printed circuit board.

The following positions are indicated in the figures:

A1 - voltage follower; A2.1 - dual operational amplifier; A2.2 - dual amplifier; A3 - DC converter; VT1 - Darlington Transistor; R1 is the resistor; R2 is a resistor; R3 is a resistor; R4 is a resistor; R5 is the resistor; R6 is a resistor; R7 is a resistor; R8 is the resistor; R9 is a resistor; C1 is a capacitor; C2 is a capacitor; C3 is a capacitor; C4 is a capacitor; C5 is a capacitor; C6 is a capacitor; C7 is a capacitor; C8 is a capacitor; C9 is a capacitor; L1 - inductor; SW1 - switch; X1 - BNC socket;

1 - output dual operational amplifier A2.1; 2 - input dual operational amplifier A2.1; 3 - input dual operational amplifier A2.1; 4 - input dual operational amplifier; 5 - input of a dual amplifier A2.2; 6 - input of a dual amplifier A 2.2; 7 - output of a dual amplifier A2.2; 8 - input of a dual amplifier A2.2; 9 - input voltage follower A1; 10 - input voltage follower A1; 11 - output voltage follower A1; 12 - input voltage follower A1; 13 - input voltage follower; 14 - output converter A3; 15 - input converter A3; 16 - output converter A3; 17 - input converter A3; 22 - input converter A3; 23 - input converter A3.

Utility Model Implementation

The device is an active laser current control module for a gas detection system of the DLS-KS type and its various modifications. The material embodiment of the module is a board with components, which is inserted into the corresponding block of the DLS-KS system.

The device is a laser current control circuitry for generating a given waveform. The electrical circuit of the laser current control module contains, located on a printed circuit board and connected by electrically conductive circuits, electronic circuits: a voltage follower (A1), necessary to reduce the influence of the control voltage source; dual operational amplifier (A 2.1), necessary for controlling the laser current; dual amplifier (A2.2), DC / DC converter (A3), designed to provide power to the module; Darlington Transistor (VT1), required to control the laser current; a resistor (R1) that implements the function of the input voltage divider; a resistor (R2) that implements the function of the input voltage divider; a resistor (R3) necessary to receive the output signal from the repeater A1; a resistor (R4) that implements a buffer function between the emitter of the transistor (VT1) and the input (2) of the dual amplifier (A 2.1); a resistor (R5) that implements the function of a buffer between the ground and the input (2) of the dual amplifier (A 2.1); a resistor (R6) that implements the function of a buffer between the output of a dual amplifier (A.2.2) and the input (3) of a dual amplifier (A 2.1); a resistor (R7) that implements the function of the current-setting laser control; a resistor (R8), which implements the function of additional oscillographic control of the values of the current flowing through the laser; resistor (R9) required to modulate the converted supply current; a capacitor (C1) that implements the function of smoothing the fronts of the control voltage pulses; a capacitor (C2) that implements the modulation function of the input power current; a capacitor (C3) that implements the modulation function of the converted supply current; a capacitor (C4) that implements the modulation function of the converted supply current; a capacitor (C5) that implements the modulation function of the converted supply current; a capacitor (C6) that implements the modulation function of the converted supply current; a capacitor (C7) that implements the modulation function of the input laser control voltage; a capacitor (C8) that implements the function of the input filter (12) of the voltage follower (A1); a capacitor (C9) that implements the function of the input filter of the input (8) of the voltage follower (A2.1); an inductance coil (L1), which implements the function of the filter of the input current supply; a switch (SW1) required to connect to the BNC jack; jack (BNS) required to connect the oscilloscope.

The analog module for controlling the diode laser is made according to the electric circuit for controlling the laser current to generate a given waveform, the DC converter (А3) through the inputs (15,17,22,23) is connected to an external DC power source, and the circuit from the converter ( A3) a pair of capacitors (C1 and C2) is connected to the power source in parallel, and an inductor (L1) is connected in series to the positive output of the power source. The outputs (14, 16) of the DC-DC converter are connected to a modulated supply current modulation chain made in the form of two parallel pairs of capacitors (C3 and C4) and (C5 and C6) and an active load connected in series between the pairs of capacitors made in the form of a resistor ( R9). One output of the converted supply current modulation chain is grounded, and the second output of the converted supply current modulation chain is connected to three branches:

to the input (12) of the voltage follower (A1). Input (12) is also connected to ground through a series-connected capacitor (C8);

to the input (8) of the dual operational amplifier (A2.1). Input (8) is also connected to ground through a series-connected capacitor (C9);

to the collector of the Darlington transistor (VT1).

The module contains a laser current control circuit, consisting of an input voltage divider made in the form of a series-connected load (R1) and a parallel-connected load (R2), and a capacitor (C7), a voltage follower (A1), and a dual voltage amplifier (A2. 1) and Darlington transistor (VT1). The output of the input voltage divider is connected to the input (9) of the voltage follower (A1). The second output of the voltage divider is grounded. The input (10) of the voltage follower (A1) is closed to the output (11) of the voltage follower (A1). The output (13) of the voltage follower (A1) is grounded. The output (11) of the voltage follower (A1) is also connected to the input (3) of the dual voltage amplifier (A2.1) through a series-connected load (resistor R3).

In this case, the output of the dual voltage amplifier (A2.1) is connected to the base of the Darlington transistor (VT1). The emitter of the Darlington transistor (VT1) is connected through a series-connected load (R7) to the switch and to the input (5) of the voltage follower (A2.2). The input (6) of the voltage follower (A2.2) is closed to the output (7). In this case, the output (7) of the voltage follower (A2.2) is connected through a series-connected load (R6) to the input (3) of the dual operational amplifier (A2.1). In this case, the output (4) of the dual operational voltage amplifier (A2.1) is grounded. The input (2) of the dual voltage amplifier (A2.1) is grounded and connected through a series-connected load (R5 and R7) and a switch (SW1).

In this case, a signal from capacitor C7 and resistors R1, R2 is supplied to the input (9) of the voltage follower, the output (11) of the voltage follower (A1) is closed to the input (10) of the voltage follower (A1).

The output (11) is connected through a resistor (R3) to the input (3) of the dual operational amplifier (A 2.1), the input (2) of the dual operational amplifier (A2.1) is connected to the resistors (R4, R5). The output (1) of the dual operational amplifier (A2.1) is connected to the base of the transistor (VT1). An output signal from the output of the amplifier (A2.1) is supplied to the base of the transistor (VT1). The collector of the transistor (VT1) is supplied with power from the converter (A3). The transistor (VT1) is also connected to resistors (C8, C9). The signal from the emitter is fed to the resistors (R5, R7). At the inputs (15, 17, 22, 23) of the DC / DC converter (A3), a direct current of 12V voltage of 500 mA is supplied through the capacitors C1, C2 and the inductor L1. The outputs (14, 16) of the DC / DC converter (A3) provide power to the module through capacitors C3, C4, C5, C6 and resistor R9.

The resistor (R1) is connected to the input (9) of the repeater (A1). The resistor (R2) is also connected to the input (8) of the repeater (A1). The resistor (R3) is connected to the output (11) of the repeater (A1), and to the input (3) of the dual amplifier (A2.1). Resistor (R4) is connected to input (2) of the dual amplifier (A2.1) and resistor (R5). The resistor (R5) is connected to the input (2) of the dual amplifier (A2.1), as well as to the resistor (R4) on the one hand and on the other hand with the resistor (R7), as well as with the emitter of the transistor (VT1). The resistor (R6) is connected to the output (7) and the input (6) of the dual amplifier (A2.2) on one side and to the input (3) of the dual amplifier (A2.1). The resistor (R7) is connected to the emitter (VT1), as well as to the input (5) of the dual amplifier (A2.2), with the resistor (R5) and with the switch (SW1). Resistor (R8) is connected to ground and socket output (X1). The resistor R (9) is connected to the output (14) of the converter (A3), with capacitors (C3), (C4), (C5), (C6), (C8) and with the ground.

The novelty in comparison with the previous technical solutions is: additional modulation of the current during the pulse, which makes it possible to scan a region in the region of the absorption line of the analyzed gas in one pulse; the autonomous nature of the module, which makes it possible to integrate it into various modifications of gas detection systems.

Laser current was controlled by a voltage-to-current converter circuit for an earthed load consisting of resistors (R3-R7), a dual operational amplifier (A2.) (AD822), and a Darlington transistor VT1 (KT972), included in the feedback circuit of the operational amplifier (A2 .1) to increase the output current. The pick-up element is a resistor (R7).

The current at the output of the circuit I _o is:

I _{o (} A) = U (B) / R7 (Ohm),

where U is the voltage at the output of the voltage follower (A1);

To reduce the influence of the control voltage source (DAC output of the NIDAQ board) on the operation of the circuit, a voltage follower (A1) (AD820) was used.

The input voltage divider (resistors R1 and R2) serves to accurately establish the coefficient of conversion of the input voltage to the laser current:

I _{o (} A) = R2 / (R1 + R2) * U _in / R7,

where U _I - voltage at the input of the circuit, V;

The capacitor (C1) is used when it is necessary to smooth the edges of the control voltage pulses, forming together with the resistor (R1) an integrating circuit, and thus limiting the working frequency band.

For additional oscillographic control of the current flowing through the laser, a resistor (R8) with a nominal value of 1 ohm is connected in series with it, and the corresponding connector for connecting the oscilloscope is output to the front panel of the interface module.

To ensure high thermal and long-term stability, precision resistors with a tolerance of at least 0.5% are used in the circuit (resistors (R3-R7) are equal, their value can be in the range of 10-50 kOhm) and with a temperature coefficient of resistance of 25 ppm / C ^° , and the current-setting resistor R7 must have the appropriate power (with a laser current of up to 300 mA at least 2 W).

The maximum current I _max provided by the above circuit is

I _max = (12 - U _T ) / (R7 + R8 + R _L ),

where: U _T - voltage drop across the transistor VT1 (about 2 V);

R _L - resistance loads (laser), Ohm;

The module is powered by a DC / DC converter (A3) with an output voltage of 12 V and a current of 500 mA, connected to an external interface power source.

The operation of the device is to modulate the pulses of the active laser in order to optimize the scanning of strong absorption lines of the analyzed gas.

The laser current was controlled by a voltage-to-current converter circuit for an earthed load consisting of resistors (R3-R7), a dual operational amplifier (A2) (AD822) and a Darlington transistor (VT1) (KT972) connected to the feedback circuit of the operational amplifier ( A2.1) to increase the output current. The pick-up element is a resistor (R7).

To reduce the influence of the control voltage source (DAC output of the NIDAQ board) on the operation of the circuit, a voltage follower (A1) (AD820) was used.

The input voltage divider (resistors R1 and R2) is used to accurately establish the coefficient of conversion of the input voltage to the laser current.

The capacitor (C1) is used when it is necessary to smooth the edges of the control voltage pulses, forming together with the resistor (R1) an integrating circuit, and thus limiting the working frequency band.

For additional oscillographic control of the current flowing through the laser, a resistor R8 with a nominal value of 1 ohm is connected in series with it, and the corresponding connector for connecting the oscilloscope is output to the front panel of the interface module.

To ensure high thermal and long-term stability, precision resistors with a tolerance of at least 0.5% are used in the circuit (resistors (R3-R7) are equal, their value can be in the range of 10-50 kOhm) and with a temperature coefficient of resistance of 25 ppm / C ^° , and the current-setting resistor (R7) must have the appropriate power (with a laser current of up to 300 mA not less than 2 W).

The module is powered by a DC / DC converter (A3) with an output voltage of 12 V and a current of 500 mA, connected to an external interface power source.

Table No. 1 nominal values of the parameters of the corresponding circuit elements

room Identification Type of Face value Note one A1 AD820AN Production "Analog Devices" 2 A2 AD822AN Production "Analog Devices" 3 A3 TEN5-1212 12 V / 12 V, 500mA production "Traco" four VT1 KT972A 5 R1 C2-29V-0.25 10 kOhm accuracy 0.5% 6 R2 C2-29V-0.25 15 kOhm selected during setup 7 R3 C2-29V-0.25 24 kOhm accuracy 0.5% 8 R4 C2-29V-0.25 24 kOhm accuracy 0.5% 9 R5 C2-29V-0.25 24 kOhm accuracy 0.5% 10 R6 C2-29V-0.25 24 kOhm accuracy 0.5% eleven R7 C2-29V-2 20 ohm accuracy 0.5% 12 R8 C2-29V-0.5 1 ohm accuracy 0.5% 13 R9 S2-23-0.5 1 ohm fifteen C1 GL 33 μF 16 V production of "CapXon" 16 C2 K10-17b 0.1 uF 17 C3 K10-17b 0.1 uF eighteen C4 GL 2200 uF 16 V production of "CapXon" 19 C5 K10-17b 0.1 uF twenty C6 GL 4700 μF 16 V production of "CapXon" 21 C7 K10-17b 100-1000 pF installed if necessary 22 C8 K10-17b 0.1 uF 23 C9 K10-17b 0.1 uF 24 L1 EC24-R39 0.39 μg 25 SW1 SS309 1A / 250B mounted on front
interface panels 26 X1 BNC-7035 BNC socket

Table No. 2 Structural elements and relationships of the device in accordance with the circuit diagram of FIG. one

No. The designation in FIG. one Type of constructive
element Feature Function Constructive relationships with other structural elements one A1 Voltage follower Reducing the influence of a control voltage source An input from
capacitor C7 and resistors R1, R2.
Output (10) is closed to input (2) 2 A2.1 Dual operational amplifier Laser current control Input 3 receives a signal from resistor R3, and input 2 receives a signal from resistors R4, R5. From output 1, the signal is fed to the base of transistor VT1 3 A3 Constant converter
current Module Power Supply Inputs 15, 17, 22, 23 are supplied with a direct current voltage of 12 V with a power of 500 mA, passed through capacitors C1, C2 and an inductor L1. Outputs 14, 16 provide power to the module through capacitors C3, C4, C5, C6 and resistor R9 four VT1 Darlington transistor Laser current control The output signal from the output of amplifier A2 is fed to the base. The collector is supplied with power current from the A3 converter, it is also connected with resistors C8, C9. The signal from the emitter is fed to resistors R5, R7. 5 R1 Resistor Input voltage divider Input 9 of repeater A1 6 R2 Resistor Input voltage divider Input 9 of repeater A1 7 R3 Resistor Receiving the output signal from the repeater A1 Output 11 of repeater A1, input 3 of dual amplifier A2.1 8 R4 Resistor Buffer between emitter of transistor VT1 and input 2 of dual amplifier A2.1 Input 2 of dual amplifier A2.1, resistor R5 9 R5 Resistor Buffer between ground and input 2 of dual amplifier A2.1 Input 2 of dual amplifier A2.1, resistors R4, R7, emitter of transistor VT1 10 R6 Resistor Buffer between the output of dual amplifier A2.2 and input 3 of dual amplifier A2.1 Output 7 and input 6 of the dual amplifier A2.2, input 3 by the output of the dual amplifier A2.1, resistor R3 eleven R7 Resistor Laser pick-up control Transistor emitter VT1, input 5 of a dual amplifier A2.2, resistor R5, switch SW1 12 R8 Resistor Additional oscillographic control of the current flowing through the laser Earth, socket outlet X1 13 R9 Resistor Modulation of the converted supply current Output 14 of converter A3, capacitors C3, C4, C5, C6, C8, ground fifteen C1 Capacitor Smoothing the edges of the control voltage pulses Capacitor C2, inductor L1, inputs 15, 17, 22, 23 of converter A3 16 C2 Capacitor Power Input Current Modulation Capacitor C1, inductor L1, inputs 15, 17, 22, 23 of converter A3 17 C3 Capacitor Modulation of the converted supply current Capacitors C4, C5, C6, C8 outputs 14, 16 of converter A3, resistor R9, input 12 of voltage follower A1, ground eighteen C4 Capacitor Modulation of the converted supply current Capacitors C3, C5, C6, C8 outputs 14, 16 of converter A3, resistor R9, input 12 of voltage follower A1, ground 19 C5 Capacitor Modulation of the converted supply current Capacitors C3, C4, C6, C8 outputs 14, 16 of converter A3, resistor R9, input 12 of voltage follower A1, ground twenty C6 Capacitor Modulation of the converted supply current Capacitors C3, C4, C5, C8 outputs 14, 16 of converter A3, resistor R9, input 12 of voltage follower A1, ground 21 C7 Capacitor Laser control input voltage modulation Resistors R1, R2, input 9 of the voltage follower A1, ground 22 C8 Capacitor Filter input 12 voltage follower A1 Capacitors C3, C4, C5, C6 output 14 of converter A3, resistor R9, input 12 of voltage follower A1, ground 23 C9 Capacitor Filter input 8 voltage follower A2.1 Capacitors C3, C4, C5, C6, C8, output 14 of converter A3, resistor R9, input 12 of voltage follower A1, input 8 of voltage follower A2.1, ground 24 L1 Inductor Power Input Filter Input + power supply, capacitors C1, C2, inputs 22, 23 of converter A3 25 SW1 Switch Connect to the BNC jack Resistor R7, input 5 of repeater A2.2., Outputs + and - control voltage of the laser 26 X1 BNC jack Oscilloscope Connector

Claims (1)

An analog diode laser control module, made according to the laser current control circuitry for generating a predetermined waveform, comprising a direct current converter connected to an external direct current power source, while a pair of capacitors is connected in parallel to the positive terminal in the circuit from the converter to the power source the power source is connected in series to the inductor, and the outputs of the DC converter are connected to the modulation chain of the converted power current, made in the form of two pairs of capacitors connected in parallel and connected in series between the pairs of capacitors, the active load, and one output of the modulated circuit of the converted current supply is grounded, and the second output of the modulated circuit of the converted current supply is connected to three branches: to the input of the voltage follower, which is connected to ground through series-connected capacitor; to the input of a dual operational amplifier, which is also connected to ground through a series-connected capacitor; to the collector of the Darlington transistor, the module contains a laser current control circuit consisting of an input voltage divider made in the form of a series-connected load and a parallel connected load, and a capacitor, a voltage follower, a dual voltage amplifier and a Darlington transistor, one output of the input voltage divider with the second input of the voltage follower, and the second output of the voltage divider is grounded, the third input of the voltage follower is closed to the output of the voltage follower the second output of the voltage follower is grounded, and the output of the voltage follower is connected to the first input of the dual voltage amplifier through a series-connected load, while the output of the double voltage amplifier is connected to the base of the Darlington transistor, the emitter of which is connected through a series-connected load to the switch and to the first input of the repeater voltage, the second input of which is closed to the output of the said voltage follower, and the output of the voltage follower through successively sub The connected load is connected to the input of the dual operational amplifier, while the second output of the dual amplifier of the operational amplifier is grounded, and the third input is grounded and connected through a series-connected load to the switch through a series-connected load pair.

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