SU1163217A1 - Method of determining transparency of atmosphere - Google Patents

Abstract

THE METHOD OF DETERMINING THE TRANSPARENCY OF THE ATAOSPHERE'S BEETS by filing into the atmosphere at an angle to the horizon along the light impulse sounding path, converting the backscattered signals into electrical current and accumulation signals within the examined layer and the entire path is probed with subsequent determination of their ratio, differing from that, in order to increase accuracy, an additional light pulse is sent to the atmosphere at a different angle to the horizon, which transforms and accumulates back scattered signals in the same way as conversion and accumulates The backscattered signals of the main light pulse, the time from the moment of sending an additional pulse to the beginning of accumulation, and the accumulation time intervals are set proportional to the corresponding time intervals when the main light pulse is sent with a proportionality factor equal to the ratio of the sines of the sprinkling angles of the main and additional pulses, and two ratios of accumulated signals are judged on their desired parameter. y

Description

7

The invention relates to atmospheric optics, can be used in the lidar sounding of the atmosphere to determine the parameters of the atmosphere to attenuate light signals in the lower layers of the atmosphere and is primarily intended to determine the slant visual range at aerodromes; when using dual-frequency sounding, it can be used to determine the concentration of gas components in the atmosphere, study sources of pollution, and so on in monitoring the state of the environment.

A known method for determining the transparency of the atmosphere, the essence of which is that the received lidar echoes accumulate over two different periods of time corresponding to the length of the entire sounding route and its part equal to the elementary resolvable volume of the atmosphere and relative to the accumulated signals judgment t on transparency p J.

The disadvantages of this method are the low accuracy and ambiguity of the results obtained in the absence of additional information about the optical state of the atmosphere.

The closest to the invention is a method for determining the transparency of the atmosphere by sending an optical pulse at an angle to the horizon, converting the backscattered light signals into electrical current signals and accumulating within the layer under study and the entire sounding route followed by determining their ratio 2 J,

The disadvantage of this method is the possibility of significant and difficult to control measurement errors in cases where the maximum value of the accumulated signal does not reach saturation, i.e. when the optical thickness T of the atmosphere, within the range, the action of the lidar's action is less than the values at which occurrence occurs. This leads to the fact that in determining the transparency profile there appears a fictitious increase in the attenuation indicators, especially significant at the end of the probe path. To eliminate this, additional information is required on the optical state of the atmosphere in any part of the probed path.

The aim of the invention is to increase the accuracy of the method.

This goal is achieved by the fact that with the method of determining the transparency of the atmosphere by putting it into the atmosphere at an angle to the horizon along the route of sounding a light pulse, transforming; backscattered light signals, corrected for the square of the distance, to the signals of electric current and accumulation within the studied layer and the entire sounding route with the subsequent determination of their ratio, send an additional light pulse at a different angle to the horizon, convert And accumulate backscattered signals similarly the transformation and accumulation of backscattered signals of the main light pulse, while the time from the moment of the additional impulse to the beginning of the accumulation and accumulation time is set proportional to the corresponding periods of time when sending a primary light pulse with a coefficient of proportionality relative ravnm sines of the angles of sending basic and additional pulses, and the ratio m of two signals accumulated judged on the desired parameter.

The drawing shows a sounding scheme.

In the diagram, line 1 corresponds to the surface of the Earth, lines 2 and 3 correspond to the lower and upper boundaries of the horizontal layer of LN, within which the accumulation of signals takes place: o - the point where the source of light impulses (lidar) is installed; H - the angle at which the main light pulse is sent; H is the angle at which an additional light pulse is sent; i. the horizontal layer, the transparency of which at a given angle H is determined; l, the horizontal layers of the atmosphere, which are part of the layer under study,

The accumulation of signals is carried out in areas "c and bc when sounding at a given angle S to the horizon and in areas oJ and e {when sounding at an angle (instead of 3 accumulation areas bc and ef, select the areas offc and o1e, respectively.) ratios sinV sin The additional sounding angle can be selected or greater or less than a predetermined angle При. Moreover, if the given angle H is large and the sine of its block is one, the additional angle Y must be less than the angle V; if the given angle H is small, then follows in Selecting angle V is greater than angle V. To simplify the mathematical calculations that clarify the essence of the method, a special case of solution is given, When the ratio of the sines of the angles Y to the Ratio of the accumulated signals Jtf and Jy is:

) o (R

 ъ

 (2)

: ..

h-BT: -3

14

(ABOUT

1- J, 17 d- and oL are the average attenuation indices of the L and LN layers, respectively; The values of T and Tu determine the transparency of the atmosphere on the sections of the route db and rtc. When форму formula (4) and (5), the condition for the constancy of the mean attenuation coefficients oi- and oly within the respective horizontal layers db and dn is assumed, we have introduced the auxiliary parameter B to solve the system of equations (4) and (6); Layer at an angle C (BJ) as well as the general transparency of the Tu layer DN at the same angle 7

Sq.CR) olR

Si (R) dR

J (-rr

Sy (, R) cJR

: where SI (R) and Sy (() are square-offset distances of the backscatter signal obtained from distances (from the lidar at the angles of sounding h and V, respectively.

Substituting the values of Sif (R) and SyCR), defined by the lazen location equation, into formulas (2) and (3), and taking into account expression (1), after simple transformations, we obtain:

T; -T,

(four)

Ihl

(five)

:)

G. 1 G

DG T. exp

however, this value, as shown

the analysis is determined with a large error.

The method in determining the profile to the overall transparency of the horizontal layer of the atmosphere with thickness Db under

the specified angle H to the horizon is carried out as follows.

Depending on the specified value of the angle H and the range of measured turbidity, the value of the additional sounding angle V is selected. At the same time, with more dense values of turbidity, smaller values of τ should be chosen (, 2 - 1.5), at high transparency x 2 - 3, the Choice

values, 2 is not advisable, since the length of the paths ab and de in this case becomes almost the same and the measurement error sharply increases. For m 3 - Л, the additional angle t must be chosen to be very small in size, which is associated with large errors of its installation; on the other hand, the sounding height at different angles is different by a factor of 3-4. Research shows that optimal values are 1.5-2. The length of the layer ln-lb; , within which the accumulation of signals takes place (parts of ef and bc), it is desirable to choose the maximum possible from the point of view of the lidar range. The main requirement when choosing BbvcoTbi upper limit 3 is that the distance of the axis, corresponding to a smaller sounding angle (in this case, angle f), does not exceed the range of the lidar action. The step value of the discrete change in the length of the probe layer is determined, the minimum value This step, when probing at a large angle, should not be less than the volatility of the elementary resolvable over the range of the atmosphere. In general, this condition is formulated as follows: the minimum step size is proportional to the length of the elementary atmosphere volume permitted by distance with a proportionality factor equal to the ratio of the sine of the larger angle to the sine of the angle at which the sounding is performed (the optimal step value must be determined from the thickness of the probe layer , the required profile detail, and so on, can be many times greater than the minimum value). The lidar is set at a given angle H to the horizon, for each premise (or series), signals are accumulated within the cib layers and the ratio of the accumulated signal in one of these layers is determined, for example, to the sum of the accumulated signals in the c layer ( ab) + (); In practical implementation, it is possible to install two accumulators accumulating signals in the layers and in the total layer ac simultaneously. The minimum length of the region C is determined by the indicated condition. Repeat this, the discrete variability of the portion of the probe layer, and determine the ratios of the accumulated signals at the sites and ac, etc. The lidar is set at an angle V and the ratios of the accumulated signals .7y are sequentially determined in the regions and .b1, then ef, etc. For each pair of relations 3, .f and Hz, obtained at different angles of probing and related to the same horizontal layers by monograms or by formulas (7) and (8) if condition (1) is satisfied, at which they are derived, determine the profile and overall transparency of the probed layer at an angle H. If it is necessary to determine only the general transparency of a layer L at an angle of If, then it is sufficient to use only two ratios of the accumulated signals 3if and J by selecting the limits of accumulated signals according to formulas (2) and (3) and determine the transparency T. by formula (7). To assess the reliability of the obtained T value, it is necessary to carry out a series of measurements of the ratios Ji and J, while maintaining the boundaries of the layer 4h and the discrete height of the upper boundary of the layer dN. A series of measurements of the relations DV and J (j; for different values of the height of the upper limit a H and determining the value of T each time, we can estimate the reliability of the results: the presence of any errors or failure to fulfill the conditions underlying the method leads to to an increase in the spread of the magnitude to the appearance of its monotonous course when the height of the upper boundary of the dN layer changes. The main feature here is not an increase in the number of measurements, but a measurement of the conditions of each subsequent, next measurement. At the same time, the selection criterion The upper boundary of the 4H layer: with neighboring discrete values of the chosen lH value, the value should not have a significant stroke.If a course is observed, which indicates the presence of large-scale discontinuities, the height of the upper boundary of the iH layer should be changed in one direction or another. average attenuation in the horizontal layers of large extent and the ability to check the feasibility of this condition in real conditions allow to eliminate the appearance of uncontrollable errors Because they do not require receiving the maximum accumulated signal. The proposed method allows simple means, directly measuring the measurement results

711632178

reliability and reliability of the received-share profile, but also to clarify the value

data, while as the cree transparency of the probed layer,

Teri can be used to increase the number of angles of inclination of the stationary metrological characteristics. This greatly increases

ki, for example, the variance of the determined operability of data acquisition and

parameter. Mention of part-simplifies the rotator

accumulation, it is possible not only to determine lidar.

Claims (1)

METHOD FOR DETERMINING ATMOSPHERE TRANSPARENCY by Sending c. the atmosphere at an angle to the horizon along the path of sensing a light pulse, converting backscattered signals into electrical signals. current and accumulation within the studied layer and the entire sensing path with the subsequent determination of their ratio, characterized in that, in order to improve accuracy, they send an additional light pulse to the atmosphere at a different angle to the horizon, they convert and accumulate backscattered signals in the same way as converting and accumulating back scattered signals of the main light pulse, while the time from the moment of sending the additional pulse to the beginning of accumulation and the accumulation time intervals are set proportionally the corresponding time intervals when sending the main light pulse with a proportionality coefficient equal to the ratio of the sines of the angles of sending the main and additional pulses, and two of the desired parameters are judged by the two ratios of the accumulated signals. ... "SU .." 1163217 1 163217