RU2589747C2 - Photodetector - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: photodetector contains an avalanche photodiode connected in series, an amplifier and a filter, a comparator, a pulse duration discriminator, a controlled power supply, a unit for signals' evaluation, a reference voltage source, a high-frequency generator and a synchronisation unit. Besides, the device also includes a series-connected additional amplifier and a detector. At that, the output of the detector is connected to the first input of the comparator, the input of the additional amplifier is connected to the filter. Used as filter is a band-pass filter with bandwidth around the middle of the operating frequency band of the amplifier frequencies.

EFFECT: increase in signal/noise ratio upon adjustment of the multiplication factor of the avalanche photodiode directly by the received optical signal.

1 cl, 2 dwg, 1 tbl

Description

The invention relates to high-speed optical radiation power meters and can be used in optical location systems.

Known photodetectors for avalanche photodiodes - US patent 4.015.118 publ. 03/29/1977, RF patent 1.679.212 publ. 09/23/1991, in which reference optical radiation is used to stabilize the avalanche photodiode (APD).

Closest to the claimed device is a photodetector on two avalanche photodiodes - g. The radio industry. Vol. 2, 1996, in which stabilization of the LFD multiplication coefficient is carried out simultaneously with stabilization of the output video signal value, directly from the received optical signal.

In the prototype, the summed signal of two channels is stabilized at a level of 0.7 V. In the range of input optical signals of 0.3 nW-3 nW, the adjustable amplifiers have a maximum gain. Balancing the sensitivity of two channels (the sensitivity of two APDs) leads, in fact, to a device on a single avalanche photodiode.

This device is described in RF patent 1.679.212 in the absence of a reference optical radiation source.

The purpose of the invention is to increase the signal-to-noise ratio by using the regulation of the LDF multiplication coefficient directly by the received optical signal.

In FIG. 1 is a block diagram of a photodetector; FIG. 2 - graphs of the coefficient of avalanche multiplication on the power of the received optical signal in the inventive device and in the prototype.

The device described in RF patent 1.679.212 consists of an avalanche photodiode 1, an amplifier 2, a filter 3, a comparator 4, a discriminator of the pulse width 5 and an adjustable power source 6. The output of the regulated power source 6 is connected to an avalanche photodiode 1. The output of amplifier 2 is also connected to the signal evaluation unit 7. In addition, the device uses a reference voltage source 8, a high-frequency generator 9 and a synchronization unit 10 connected to both the pulse duration discriminator 5 and the signal evaluation unit 7. It should be noted that, to the regulated power supply 6, after the end of the video signal of the line, one of the two control pulses is supplied from the discriminator of the pulse duration 5 to increase or decrease the voltage of the power source of the avalanche photodiode. In the prototype there is no reference source of pulsed optical radiation described in the patent of the Russian Federation 1.679.212.

As described in RF patent 1.679.212, the first input of the pulse duration discriminator 5 is connected to the output of the comparator 4. The first and second outputs of the pulse duration discriminator 5 are connected respectively to the first and second inputs of the regulated power supply 6, the output of which is connected to the avalanche photodiode 1.

In the inventive device, the stabilization of the coefficient of multiplication of the APD is carried out by the received signal. Introduction to the device of an additional amplifier 11, detector 12 and the use of a band-pass filter as filter 3 allows us to achieve the goal of the invention - to increase the signal-to-noise ratio by using the regulation of the avalanche multiplication coefficient directly from the received optical signal.

In the claimed device, the input of the additional amplifier 11 is connected to the output of the bandpass filter 3, the input of which is connected to the amplifier 2. The output of the additional amplifier 11 is connected to the detector 12, the output of the detector 12 is connected to the first input of the comparator 4.

The device contains a series-connected avalanche photodiode 1, amplifier 2, a band-pass filter 3, an additional amplifier 11, a detector 12, a comparator 4, a discriminator of the pulse duration 5 and an adjustable power supply 6. The output of the adjustable power source 6 is connected to the avalanche photodiode 1. The output of amplifier 2 is also connected to the signal evaluation unit 7. The device uses a reference voltage source 8 connected to the second input of the comparator 4, a high-frequency generator 9 connected to the second input of the discriminator pulse pulses 5 and a synchronization unit 10, the output of which is connected to the third input of the discriminator of the pulse duration 5 and the second input of block 7.

поддерживаются на уровне 0,7 В. В настоящее время, во многом благодаря переходу к записи цифровой, а не аналоговой информации, стабилизация уровня аналогового выходного видеосигнала фотоприемного устройства менее важна, чем обеспечения максимального отношения сигнал/шум во всем диапазоне мощностей принимаемых лазерных сигналов.In the prototype, stabilization of the APD multiplication coefficient is carried out by the discriminator of the pulse duration 5 simultaneously with the stabilization of the magnitude (level) of the output video signal. In the prototype, signals from areas with maximum reflection coefficients

they are maintained at 0.7 V. Currently, largely due to the transition to recording digital rather than analog information, stabilization of the level of the analog output video signal of a photodetector is less important than ensuring the maximum signal-to-noise ratio over the entire power range of the received laser signals.

In the claimed device, the regulation of the coefficient of multiplication of the APD is carried out by the magnitude of the noise of the amplified received optical signal by stabilizing the size of the shot noise of the APD.

The purpose of the invention is achieved by introducing into the device an additional amplifier 11, detector 12, and using as a filter 3 a bandpass filter with a passband near the middle of the working frequency band of the amplifier or slightly less than the middle of the working frequency band of the amplifier.

Band-pass filter - a filter that transmits electrical signals in the frequency range from f _n to f _in . The upper transmittance f _is approximately 20-30% greater than the lower transmittance f _n . Shot noise of the APD depends on the power of the received optical signal - P _s and the avalanche multiplication coefficient M. The voltage of the APD noise at the output of the additional amplifier 11:

where L is a constant value depending on the circuitry of the device, primarily on the gain of the amplifiers 2 and 11, as well as the characteristics of the filter 3.

This alternating voltage _Uoutputs to the detector 12, is detected, filtered, and compared to the reference voltage of the source 8 in the comparator 4. A more accurate formula for shot noise of the APD (2.32) is given in the book - Fundamentals of Optoelectronics. Per. with yap. - M.: Mir, 1988.

In the device, depending on the power of the received optical signal in the range of 0.3 nW-12 nW, the avalanche multiplication factor M is adjusted. The input signal range of 1 nW-6 nW is the most informative. This is the power of reflected laser signals from terrain with maximum reflection coefficients at typical altitudes of the carrier.

The photodetector is stabilized by the maximum signals during the line (more precisely, by their noise level). Table 1 shows the values of the maximum output signal of the photodetector - U _c , mV, the signal-to-noise ratio - S / N, as well as the decrease in the avalanche multiplication coefficient K = M _0.5 / M _Pc and the normalized value of the APD noise figure - F * (relative to F at P _c = 0.5 nW), at different signal powers P _c , nW.

The plots of the avalanche multiplication coefficient M versus the received signal power P _s in the range from 0.3 nW to 12 nW in the inventive device and in the prototype are shown in FIG. 2

The reference power of the input optical signal during stabilization of the APD is 0.5 nW. In FIG. 2, the avalanche multiplication factor M y of various photodetectors is the same (optimized) at P _c = 0.5 nW. The purpose of this optimization is to obtain the maximum possible, at least 10, signal-to-noise ratio necessary for the operation of infrared laser equipment for surveying the area at maximum heights. When the fractional noise of the APD and the thermal noise of the amplifier are equal, the optimal multiplication coefficient takes place at which the signal-to-noise ratio is maximum. In the prototype, the total noise current level of the two channels, brought to the input, is 0.4 nA, the noise of the feedback resistance R _OS = 330 kOhm is equal to the noise of field-effect transistors with a pn junction. With the optimal avalanche multiplication coefficient and the characteristics of the bandpass filter determined by the claims, the shot noise of the APD is 1.3-1.4 times higher than the thermal noise of the amplifier, since in this frequency band the noise of the preamplifiers of the photodetector is mainly determined by the feedback resistance noise.

Table 1 shows the characteristics of the FPU in the range of received signal powers of 1.0 nW-6 nW. In the power range of the maximum signal during a line of 6 nW-12 nW, it is advisable to use the avalanche multiplication factor adjustment similar to that used in the RF patent 1.679.212 (in the second AGC loop, the reference voltage is 2.5 V). The use of two AGC loops is possible when prioritizing control commands, so the command of the second AGC loop to reduce M is a priority. In the range of 6 nW-12 nW, the output signal of the FPU stabilizes at 2.5 V - while the signal-to-noise ratio is more than 40.

In the inventive device provides a significantly higher signal to noise ratio than in the prototype, which allows its use in infrared laser equipment for surveying the area to well recognize objects of observation in night conditions.

Claims (1)

A device containing a series-connected avalanche photodiode, amplifier and filter, as well as a comparator, a pulse duration discriminator, the first input of which is connected to the comparator, an adjustable power source, the output of which is connected to the avalanche photodiode, and the first and second inputs are connected respectively to the first and second the outputs of the discriminator of the pulse duration, the signal evaluation unit, the first input of which is connected to the output of the amplifier, a reference voltage source connected to the second input of the comparator RA, a high-frequency generator connected to the second input of the pulse duration discriminator, and a synchronization unit, the output of which is connected to the third input of the pulse duration discriminator and the second input of the signal estimation unit, characterized in that, in order to increase the signal-to-noise ratio when using the multiplication factor control an avalanche photodiode directly by the received optical signal; an additional amplifier and detector are connected in series to the device; the detector output is soy is dined with the first input of the comparator, the input of the additional amplifier is connected to the filter, and a bandpass filter with a passband near the middle of the working frequency band of the amplifier or slightly less than the middle of the working frequency band of the amplifier is used as a filter.

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