RU2755602C1 - Method for threshold detection of optical signals - Google Patents

Abstract

FIELD: optical signal detection.SUBSTANCE: invention relates to the technique of isolating signals from noise using avalanche photodiodes. A method for threshold detection of optical signals using an avalanche photodiode, including threshold signal processing and the formation of output pulses when the signal from the output of the photodiode exceeds the specified threshold of operation is presented. The frequency f0of noise crossing the zero threshold and the frequency fopof noise triggers in the operating mode is predetermined, the avalanche-free mode of the photodiode offset is turned on, the trigger threshold U is set at a level corresponding to the frequency of noise triggers of the threshold device f<<f0, the threshold is increased, this threshold is fixed and such an avalanche multiplication coefficient M=Moptis set, at which the frequency of fMnoise exceeding the threshold UMbecomes equal to the frequency f in the avalanche-free mode M=1 at the threshold U, when the fMfrequency is reached, the achieved avalanche multiplication coefficient M=Moptis fixed, the threshold is increased to the operating level and optical signals are received.EFFECT: ensuring the maximum signal-to-noise ratio.3 cl, 3 dwg

Description

The proposed invention relates to the reception of optical signals, in particular, to the technique of receiving signals using avalanche photodiodes, and can be used in location, communication and other photoelectronic systems.

A known method of receiving optical signals using avalanche photodiodes [1]. There are also known methods for stabilizing the avalanche mode of a photodiode, for example, by thermal compensation of the operating point of the bias voltage [2].

The closest to the proposed technical solution is a method for threshold detection of pulsed optical signals using an avalanche photodiode, the bias voltage of which is maintained by stabilizing the frequency of noise pulses arising during threshold processing of a mixture of signal and noise [3].

The disadvantage of this method is the dependence of the avalanche mode on the set response threshold. This leads to the wrong choice of the operating point of the photodiode and deterioration of the threshold sensitivity [4].

The objective of the invention is to provide optimal sensitivity in all operating conditions with a guaranteed probability of false alarms and maximum performance.

где α - параметр шум-фактора лавинного умножения F=М^α, этот порог

фиксируют и устанавливают такой коэффициент лавинного умножения М=М_опт, при котором частота f_M шумовых превышений порога U_M становится равной частоте f в безлавинном режиме М=1 при пороге U, по достижении частоты f_M фиксируют достигнутый коэффициент лавинного умножения М=М_опт, увеличивают порог до рабочего уровня

и приступают к приему оптических сигналов.This problem is solved due to the fact that in the known method of threshold detection of optical signals using an avalanche photodiode, including threshold signal processing and the formation of output pulses using a threshold device when the signal from the output of the photodiode exceeds the specified response threshold, the frequency f _{0 of} crossing the zero noise threshold and frequency f _{pa of} noise triggers in the operating mode, turn on the avalanche-free mode of the photodiode bias, set the trigger threshold U at a level corresponding to the frequency of noise triggering of the threshold device f << f ₀ , then increase the threshold in

where α is the parameter of the avalanche multiplication noise factor F = М ^α , this threshold

fix and set such an avalanche multiplication coefficient M = M _opt , at which the frequency f _{M of} noise exceeding the threshold U _M becomes equal to the frequency f in the avalanche-free mode M = 1 at the threshold U, upon reaching the frequency f _{M, the} achieved avalanche multiplication coefficient M = M _opt , increase the threshold to the working level

and begin to receive optical signals.

то есть f>>1/Т, где Т - интервал усреднения датчиков, а верхняя граница - условием f<<f₀.The frequency f can be selected from the range, the lower limit of which is determined by the condition

that is, f >> 1 / T, where T is the averaging interval of the sensors, and the upper limit is the condition f << f ₀ .

раз и

раз можно осуществить введением в усилительный тракт перед пороговой обработкой соответствующих коэффициентов ослабления.Threshold increase in

times and

times can be carried out by introducing appropriate attenuation coefficients into the amplifying path before thresholding.

FIG. 1 shows a block diagram of the equipment that implements the method. FIG. 2 is a sequence diagram of the method. FIG. 3 shows a typical dependence of the squared signal-to-noise ratio on the avalanche multiplication factor.

A possible version of the receiver according to the proposed method (Fig. 1) contains an avalanche photodiode 1, the output of which through a matching amplifier 2 and controlled attenuators 3 and 4 is connected to the input of the threshold pulse shaper 5. The output of the latter is connected to the inputs of the frequency sensors 6 and 7. Sensor 6 is connected to the control input of the threshold shaper 5, and the sensor 7 to the bias source of the photodiode 8. Sensors 6 and 7 and attenuators 3 and 4 are connected to the control unit 9. At the output of the threshold shaper there is a key 10 connected to the control unit.

The method is carried out as follows.

Preliminarily (at the design stage) set: frequency f ₀ , determined by the bandwidth of the receiving path 1-4 to the entrance of the threshold shaper; frequency f, satisfying the above limitations and the characteristics of the applied hardware; frequency f _pab - according to the technical requirements; parameter a, determined by the design of the photodiode; averaging interval T of the frequency sensor.

означающее малое влияние среднеквадратического разброса

оценки на ее среднее значение fT [7]. Например, при f_o=10⁷ Гц и времени усреднения Т=0,1с этим условиям отвечает частота f в диапазоне от 10² до 10⁶ Гц.Before receiving the signals, a preparatory mode is turned on, during which the optimal parameters of the receiving path are set - the avalanche multiplication coefficient of the photodiode and the threshold of the threshold device. To this end, at the first stage, using the control unit 9, the attenuators 3 and 4 are opened and a low bias voltage level is set at the bias source 8, corresponding to the avalanche multiplication factor M = 1. At the same time, the response threshold U of the shaper 5 is set so that the frequency f of noise thresholds exceeding the threshold is significantly lower than the limiting frequency f ₀ . This is necessary to provide a wide range of adjustment of the receiver parameters. At the same time, the frequency of noise alarms must be high enough for the frequency estimate over the averaging period T to be reliable. This requirement is met by the condition

meaning little effect of rms spread

estimates for its mean value fT [7]. For example, with f _o = 10 ⁷ Hz and averaging time T = 0.1 s, these conditions are met by the frequency f in the range from 10 ² to 10 ⁶ Hz.

тем самым, поднимающий эквивалентный порог до уровня

Одновременно с помощью блока управления включают датчик частоты 7, управляющий коэффициентом лавинного умножения фотодиода путем подачи на него напряжения смещения, при котором частота шумовых срабатываний в лавинном режиме f_M снова станет равна частоте f, установленной в безлавинном режиме.Upon reaching the steady-state value of the threshold U, the control unit turns on the attenuator 3, which introduces an attenuation

thereby raising the equivalent threshold to the level

At the same time, using the control unit, the frequency sensor 7 is turned on, which controls the avalanche multiplication factor of the photodiode by applying a bias voltage to it, at which the frequency of noise operations in the avalanche mode f _M will again become equal to the frequency f set in the avalanche-free mode.

Одновременно открывают ключ 10, пропускающий выходные импульсы формирователя 5 на выход. Таким образом осуществляется переход в рабочий режим приема оптических сигналов. При этом частота шумовых срабатываний на выходе не превышает заданного допустимого значения f_paб, а коэффициент лавинного умножения фотодиода М=М_опт обеспечивает максимальное отношение сигнал/шум.After reaching the mode f _M = f, the bias voltage of the photodiode is fixed at the achieved level with the help of the control unit and the attenuator 4 is switched on by the command from the control unit, which introduces attenuation

At the same time, the key 10 is opened, which passes the output pulses of the shaper 5 to the output. Thus, the transition to the operating mode of receiving optical signals is carried out. In this case, the frequency of noise alarms at the output does not exceed the specified permissible value f _pa , and the avalanche multiplication factor of the photodiode M = M _opt provides the maximum signal-to-noise ratio.

Figure 2 shows a sequence diagram of the method.

T ₁ - duration of the first preparatory mode - setting the threshold U.

T ₂ - the duration of the transition process from the first to the second preparatory mode, setting the threshold U _M.

T ₃ - the duration of the second preparatory mode - setting the optimal avalanche.

T ₄ - the duration of the transition process from the second preparatory mode to the operating mode - setting the threshold U _pa .

T ₅ - the duration of the operating mode.

It is known [5-7] that in the avalanche-free mode (M = 1) the square of the root-mean-square value of the noise σ at the output of the photodiode

where σ ₀ and σ ₁ are the rms values of the non-multiplied (σ ₀ ) and multiplied (σ ₁ ) noise components, respectively.

Frequency f of crossing the threshold U by noise emissions in avalanche-free mode [7]

- частота пересечения шумом нулевого порога; R"(0) - вторая производная корреляционной функции шума на входе порогового устройства R(τ) при задержке τ=0. Зная частоты f и f₀ из (2) можно определить отношение порог/шумwhere

- frequency of crossing the zero threshold by noise; R "(0) is the second derivative of the correlation function of the noise at the input of the threshold device R (τ) with a delay τ = 0. Knowing the frequencies f and f ₀ from (2), one can determine the threshold / noise ratio

In avalanche mode [4]

where α is the parameter of the avalanche multiplication noise factor F = M ^α , determined by the material and structure of the photodiode [4-6]. Squared signal-to-noise ratio

Inverse η ² (squared noise / signal ratio)

The derivative of this quantity

The minimum noise-to-signal ratio is provided at dW / dM = 0.

Condition (8) is satisfied for

Frequency of noise exceeding the threshold in avalanche mode

Substitution of (9) into (10) gives an expression for the frequency of noise exceeding the threshold at M = M _opt. Taking into account the always present condition σ ₀ ² >> σ ₁ ²

From (2) and (11), the ratio of frequencies f (M = M _opt ) and f (M = 1) is obtained.

Substitution of (3) into (12) gives

As follows from (12) and (13), at constant values of the coefficient a, depending on the design of the photodiode, and U / σ, given by the frequency f, the ratio f (M _opt ) / f is completely determined by these parameters and is also a constant parameter of the method.

In turn, the frequency is f (M _orrr ). corresponds to the optimal value of the avalanche multiplication factor providing the maximum signal-to-noise ratio. This methodological constancy simplifies the tuning procedure both in the process of debugging the receiver and in its operating mode in preparation for receiving signals.

It also follows from this that the frequency f can be any in the widest range under the conditions

The main design ratio of the proposed method follows from (2) and (11).

следуетFrom the equality of these frequencies at

should

откуда отношение порогов во втором и первом подготовительных режимах

whence the ratio of the thresholds in the second and first preparatory modes

The jump in the threshold from the second preparatory mode to the operating mode is determined by applying expression (3) when substituting the corresponding parameters

A feature of the proposed method is the constancy of parameters (16) and (17), selected at the design stage and unchanged during operation in all conditions. The second significant feature is that the same frequency f in the first and second preparatory modes allows you to select it as close as possible to the limiting frequency f ₀ , which makes it possible to implement the minimum time to reach the operating mode and minimum random fluctuations in the hardware frequency estimation when implementing the method. The third important feature of this method is that in the region of the optimal avalanche there is a weak dependence of the signal-to-noise ratio on the avalanche multiplication coefficient. FIG. Figure 3 shows a graph typical of this dependence. With the optimal value of the avalanche multiplication coefficient M _opt = 26 at the boundaries of a wide range of M from 18 to 46, only a 5% degradation of the signal-to-noise ratio occurs.

In turn, М weakly depends on the error in setting the frequency f. It is easy to show that a 20% error in setting the frequency f leads to a deviation of M by only 10%. This makes it possible to achieve practically any accuracy M _opt with a minimum value of the parameter fT, which basically determines the random deviation of f from the nominal value.

Example 1

Initial data:

(σ ₀ / σ ₁ ) ² = 900; α = 0.5 (Si avalanche photodiode); f ₀ = 10 ⁷ Hz; f = 10 ⁶ Hz; f _pab = 10 Hz.

Example 2 (the same at high temperature or with background illumination, reducing the ratio σ ₀ / σ ₁ ).

Initial data:

(σ ₀ / σ ₁ ) ² = 100; α = 0.5 (Si avalanche photodiode); f ₀ = 10 ⁷ Hz; f = 10 ⁶ Hz; f _pab = 10 Hz.

The averaging time T of the frequency sensors is selected from condition (14) taking into account the ratio T ~ T _r [7], where T _r is the time of reaching the mode.

Example 3

Initial data:

(σ0 / σ1) ² = 900; α = 0.5 (Si avalanche photodiode); f0 = 10 ⁷ Hz; f = 10 ⁶ Hz; f _pab = 10 Hz.

откуда Т=100/f=10^-4 с.

whence T = 100 / f = 10 ^-4 s.

Preparation time for work T _n ~ 2 T = 2⋅10 ^-4 s.

In the known method, under the same assumptions, the time T _n ~ 1-3 s [7], that is, the gain in comparison with the analogue is four orders of magnitude, which makes it possible to use the proposed method in high-speed frequency systems.

Example 4

Initial data:

fT = 100. M = 26.

При этом относительное среднеквадратическое отклонение σ_м коэффициента лавинного умножения от номинального значения составит 5%. То есть в стандартных пределах ± 3σ_м окажется диапазон М от 22 до 30, что, как видно из фиг. 3 может привести к ухудшению отношения сигнал/шум относительно потенциального значения не более чем на 1%.The relative standard deviation of the frequency setting error f is

The relative standard deviation σ _m avalanche multiplication coefficient from the nominal value of 5%. That is, the range of M from 22 to 30 will be within the standard limits of ± 3σ _m , which, as can be seen from Fig. 3 can lead to a degradation of the signal-to-noise ratio relative to the potential value by no more than 1%.

Thus, the described method solves the set problem of ensuring optimal sensitivity in all operating conditions with a guaranteed probability of false alarms and maximum speed.

Sources of information

1. Ross M. Laser receivers. - M .: Mir., 1969 .-- 520 p.

2. RF patent №2248670. A device for switching on an avalanche photodiode in an optical radiation receiver. 2005 year

3. US pat. 4,077,718. Receiver for optical radar. 1978. - prototype.

4. Vilner V.G., Leichenko Yu.A., Motenko B.N. Analysis of the input circuit of a photodetector with an avalanche photodiode and anti-noise correction. Optical and mechanical industry, 1981, No. 9, - P. 59.

5. Anisimova I. D. and others. Semiconductor photodetectors: Ultraviolet, visible and near infrared ranges of the spectrum. Ed. IN AND. Stafeeva. - M .: Radio and communication, 1984 .-- 216 p.

6. Filachev A.M., Taubkin I.I., Trishenkov M.A. Solid-state photoelectronics. Photodiodes. - Moscow: Fizmatkniga, 2011 .-- 448 p.

7. Vilner VG Design of threshold devices with noise threshold stabilization. - Optical and mechanical industry, 1984, No. 5, pp. 39-41.

Claims (3)

1. A method of threshold detection of optical signals using an avalanche photodiode, including threshold processing of signals and the formation of output signals when the signal from the output of the photodiode exceeds a predetermined response threshold, characterized in that the frequency f _{0 of} crossing the zero threshold noise and the frequency f _{pa of} noise responses in the working mode, turn on the avalanche-free mode of the photodiode bias, set the triggering threshold U at a level corresponding to the frequency of noise triggering of the threshold device f << f ₀ , increase the threshold in

where α is the parameter of the noise factor of the avalanche multiplication F = М ^α , this threshold

fix and set such an avalanche multiplication coefficient M = M _opt , at which the frequency f _{M of} noise exceeding the threshold U _M becomes equal to the frequency f in the avalanche-free mode M = 1 at the threshold U, upon reaching the frequency f _{M, the} achieved avalanche multiplication coefficient M = M _opt , increase the threshold to the working level

and begin to receive optical signals. 2. The method according to claim 1, characterized in that the frequency f is selected from the range, the lower limit of which is determined by the condition

where T is the averaging interval of the sensors, and the upper limit is the condition f << f ₀ . 3. The method according to claim 1, characterized in that the increase in the threshold in

times and

times, the corresponding attenuation coefficients are included in the amplifying path in front of the threshold device with the help of controlled attenuators.

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