CS258398B1 - Ultra-short-pulse sequence laser detector - Google Patents

Abstract

The detector for lasers with a sequence of ultrashort pulses consists of a switching silicon transistor, connected to electrical components and provided with a matrix in the upper part of the housing. A resistor is connected to the collector of the transistor and the middle conductor of another coaxial cable is connected to the emitter of the transistor at one end, the conductor of which is grounded and the opposite end forms the output of the device. The emitter of the transistor is further grounded through another resistor, while the base and emitter of the transistor are conductively connected to each other. Either a capacitor is connected to the collector of the transistor at one terminal, the other terminal of which is grounded, or the middle conductor of a coaxial cable is connected to it at one end, the outer conductor of which is grounded and the opposite end is open. The detector for lasers with a sequence of ultrashort pulses is usable in laser technology and in measurement technology.

Description

The invention relates to a device for detecting laser radiation in the form of ultra-short pulse sequences and at the same time solves the problem of amplitude discrimination with very small time scattering.

Various arrangements for this purpose are known to date, for example a circuit consisting of a fast photodiode whose output signal is routed through a coaxial cable and processed by an amplitude discriminator. However, this circuit does not allow detection of a sequence of ultra-short light pulses with distances between units of ns with a time scatter of less than 300 ps, throughput delay of more than tens of ns, also equipment manufacture is complicated, requires special electronic components. for external disturbing electromagnetic field. Furthermore, a circuit consisting of a fast photodiode is known whose signal is amplitude discriminated against by a immediately adjacent monostabble flip-flop circuit with a tunnel diode.

However, this circuit does not allow the detection of a sequence of ultra-short light pulses with distances between units of ns with a time scatter of less than 150 ps, a throughput delay of 5 ns, circuit setup difficult and circuit overloading by an input signal 10 times stronger than the minimum detectable. Also known is an Auston electro-optical switch, which is a semiconductor crystal element that is part of the output tape line.

This switch allows the detection of a sequence of ultra-short light pulses with distances between units ns with unit time scattering up to tens of picoseconds depending on the length of the optical input pulses, throughput delay is less than 1 ns, supply voltage exceeds 1000 volts. power supplies, the amplitude of the output electric pulses reaches 1000 volts, for use in measuring technology it is necessary to attenuate the signal more than 25 times, which complicates the device and leads to a deterioration of the output pulse shape.

As an explanation, the pass delay is the time interval between the impact of the detected light pulse and the generation of the electrical pulse at the discriminator output, the time scattering is the passage delay scattering. Values corresponding to the mean square deviations of the measured intervals are given.

These drawbacks are eliminated by an ultra-short pulse laser detector consisting of a switching silicon transistor connected to electrical components and provided with a matte top in the housing according to the invention, in which a resistor is connected to the transistor collector and a transistor emitter connected at one end, the middle conductor of another coaxial cable, the outer conductor of which is grounded and the other end forming the output of the device, and the emitter of the transistor is further grounded through another resistor, the base and emitter of the transistor being conductively connected.

A capacitor whose other terminal is grounded can be connected to the transistor collector by one terminal, or the middle conductor of the coaxial cable, the outer conductor of which is grounded and the other end open, can be connected to one end.

The higher effect of the detector according to the invention compared to detectors using fast photodiode input is that it achieves the proposed significantly better parameters, for example the throughput delay is at least 5 times lower, the time scatter is at least 5 times lower, better immunity to interfering electromagnetic fields, , easier setup and commissioning and lower cost. The described detector according to the invention achieves comparable throughput and time scattering values as Auston's electro-optical switch, but has advantages over simplified design and manufacture, lower supply voltage and lower cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows schematically the silicon transistor of an ultra-short pulse laser detector according to the invention; FIGS. The ultra-short pulse sequence of the invention and FIG. 4 illustrate the dependence of the intensity of the laser radiation incident on the detector over time as well as the amplitude of the detector output voltage versus time, both for a laser detector with the ultra-short pulse sequence of the invention.

The ultra-short pulse laser detector according to the invention is an electro-optical avalanche switch formed by a modified switching silicon transistor JL which is used for a new purpose. It is used as a light switch avalanche switch. The repair of the transistor 2 consists in removing the upper part 2 of the housing and replacing it with a glass focusing glass 2- The repair of the transistor 2 3® shown in Fig. 1.

Original housing transistor 2 is in the upper part 2 ubroušeno and the hole is covered by the focusing screen 2 · wiring diagram of the detector shown in FIG. 2. In the collector of the transistor ³ and 2 connected coaxial cable center conductor i_, an outer conductor of the cable is grounded, opposite end open. Positive supply voltage U is applied to the collector of transistor 2 via resistor 2 · Transistor emitter 2 3 ^{e is} grounded through another resistor 2 · The output pulse is taken from the transistor emitter by another coaxial cable T, whose outer conductor is grounded. The base of transistor 2 is coupled to the emitter.

Alternatively, the coaxial cable 2 may be replaced by a capacitor 2, one end of which is connected to the collector of the transistor 2 ^{and the} other end is grounded, as shown in FIG. 3.

The laser radiation falls off on the matrix 2 and is scattered by it and further impinges on the transistor 2 system. If the current flowing through the transistor 2 falls below the minimum required holding value, the transistor 2 opens and the coaxial cable 2 ^is recharged via a resistor 2 ^{from the} source to + U.

The ultra-short pulse laser detector of the invention detects the first of the ultra-short pulse train whose amplitude exceeds a set level, with a time variance of typically 30 picoseconds and a throughput delay of less than 1 nanosecond. The time course of detection is shown in Fig. 4. The upper curve is the dependence of the intensity E of the laser radiation striking the detector on time t. The lower curve a is the dependence of the amplitude of the output voltage of the detector over time t. t for alternative detector wiring. The detector detects a second pulse whose amplitude exceeds the trigger level h.

The energy of the laser pulse required to close the switch, i.e. the detector function, is 10 microJoules. Without deterioration of parameters it is possible to use the detector even to detect signals up to 100 times stronger than the specified minimum. The detector can be used in the laser wavelength range of 400 to 1100 nm. The device is not sensitive to optical signal overload; it can withstand overloads of up to 10,000 times without damage. The function of the detector is not dependent on fluctuations in the intensity distribution within the laser beam.

The detector output signal is a positive electrical pulse with an amplitude of typically 25 V with a very steep leading edge, or face, of a pulse of 1 ns. In one third of the pulse amplitude, the steepness of the pulse increase is greater than 10 mV / ps. The output pulse length can be varied within the range of 1 to 200 nanoseconds by varying the length of the coaxial cable in the transistor collector within the range of 0.1 to 20 meters. The output pulse length of the detector in an alternative circuit is 5 to 500 ns with a capacitance range of 30 to 300 pF.

The device is very resistant to disturbing electromagnetic fields, it can work in close proximity to sources of intensive interference such as pulse laser lamps, switching spark gap and others without deterioration of parameters. The device has very small dimensions and simple construction, it can be placed directly into the laser head.

The function of the detector can be verified by simply increasing the supply voltage to the value at which the avalanche switch vibrates. In this setting, the circuit generates electrical pulses of the same waveform as when laser radiation is detected. The optimum operating voltage is set so that the minimum voltage at which self-oscillations occur is reduced by ten percent. The intensity of incident radiation is reduced by neutral optical filters in front of the detector. When attenuating the optical signal below 1 microJoule, the detector acts as a fast photocell with a bandwidth of 700 MHz and can be used to monitor the progress of the laser pulse train on an oscilloscope.

Example 1

The proposed detector according to the invention was assembled along the circuit shown in Fig. 2.

A KSY62A transistor, modified as described above, as a coaxial cable 4, a coaxial cable with an impedance of 50 Ohms, 0.5 m long with a full PVC dielectric, as a resistance 5 resistor M1, as a resistor 6, a 56 ohms resistor, was used as transistor 1. , inductive and, as an additional coaxial cable, a 50 Ohm coaxial cable for pulse output. The + U supply voltage was set individually for each of the transistors used in the range of +70 to +90 V. The detector detected laser pulses from a sequence of ultra-short pulses generated by a Nd YAP laser operating in passive mode synchronization mode. The length of the ultra-short pulses was 12 ps, the intervals between pulses were 2 ns.

The detector of the invention achieved a throughput delay of less than 1 ns, a time scatter of less than 30 picoseconds, an output pulse amplitude of 25 volts, and an output pulse length of 5 ns.

Example 2

In an alternative variant, the detector was assembled according to FIG. 3, using a KSY62A transistor adapted as a transistor 1, modified as described above, as a fast capacitor of 30 pF capacitance, as a resistor 5 resistor M1, as a resistor 6 resistor 56 Ohm, inductive and as an additional coaxial cable 2 coaxial cable with an impedance of 50 Ohms for pulse output. The output pulse length was 5 ns, the shape of the output pulse is in Fig. 4, curve b. All other features of the detector are identical to the original variant with coaxial cable 4 ^. The output pulse parameters of the detector were measured with a digital oscilloscope with a width of 400 MHz and a time resolution of 10 seconds per channel. Pass-through delay and time-scatter values were measured using three independent methods using the digital oscilloscope, fast cameras with a 10 ps time resolution and an equivalent bandwidth of 40 GHz, and a 10 ps time interval meter. The values measured by the individual methods coincide in the range of measurement errors.

The use of the detector according to the invention has been verified in a laser satellite rangefinder to detect the emitted laser radiation. The use of the detector has increased the accuracy of rangefinder distance measurement from 8 to 4.5 c. The detector was also used in laser laboratories to develop new solid state lasers for triggering a fast camera. The use of this detector significantly increased the measurement yield of a fast camera, since unlike previously used detectors, the camera was always started at the same time due to the sequence of ultra-short pulses. To achieve the same effect, a very complex device has yet to be used to separate a single ultra-short pulse from a sequence. The detector was also successfully used to trigger the laser pulse divider.

In all of these applications, the benefit was low time scattering, low throughput delay, steep rise of the output pulse front, and output pulse amplitude. The detector was used at 532, 534, 1,064 and 1,079 nm wavelengths without changing the parameters achieved.

The ultra-short pulse laser detector according to the invention can be used in laser and measuring technology.

Claims (3)

An ultra-short pulse laser detector consisting of a switching silicon transistor connected to electrical components and provided with a matrix at the top of the housing, characterized in that a resistor (5) and a transistor emitter (1) are connected to the transistor collector (1). ) is connected at one end by the middle conductor of another coaxial cable (7), the outer conductor of which is grounded and the opposite end forms the output of the device, and the emitter of transistor (1) is further grounded via another resistor (6); they are conductively connected to each other. Detector according to Claim 1, characterized in that a capacitor (8) is connected to the collector of the transistor (1) with one terminal, the other terminal of which is grounded. Detector according to Claim 1, characterized in that the collector of the transistor (1) is connected at one end to the middle conductor of the coaxial cable (4), the outer conductor of which is grounded and the opposite end is open.