RU2369866C1 - Method of complex enviromental region monitoring - Google Patents

Abstract

FIELD: ecology.

SUBSTANCE: invention relates to method of complex environmental monitoring of region, divided into administrative-territorial formations, which include control objects. Method consists in the fact, that for collecting information measured are values of control objects characteristics by remote and contact methods and estimation of changing in time of environment quality indices is estimated. Before information collecting starts in center of processing and controlling data base is formed by characteristics of region environment and rules of formalisation of results of environment condition and its changing estimation. On control means formed are local data bases with permissible values of control objects characteristics and common rules of formalisation of results of their condition estimation. On each control means measured and permissible values of control objects characteristics are compared, facts of their correspondence and discrepancy to permissible values are recorded. Then results of comparison are formalised in form of standardized protocols, which contain graphical and tabular forms, reflecting recorded facts of correspondence and discrepancy of controlled characteristics values to their permissible values, value of time of protocol formation end, names, numbers and factual values of control objects characteristics, which do not correspond to permissible characteristics. Formed protocols are given by communication lines to centre of processing and control, where united protocol of estimation of region's environment is formed, for which purpose superposed are graphic forms and combined are tabular forms of protocols obtained by centre of control and processing, facts of presence and direction of changes of environment characteristics are recorded by graphic forms of previous and last of formed united protocols, and by tabular forms - factual values of characteristics and moments of time of end of forming protocols on means of control. Then time line is formed from recorded values and used in predicting changes of region's environment characteristics in time.

EFFECT: achieved technical result consists in increase of efficiency of correspondence of region's environment condition to set norms and its changes.

7 dwg, 10 tbl

Description

The invention relates to monitoring methods and can be used for a comprehensive assessment of compliance with established standards and environmental changes in the region.

Under the environment of the region is understood the totality of the components of the natural environment, natural and natural-anthropogenic objects, as well as anthropogenic objects. Environmental monitoring is a comprehensive system for monitoring the state of the environment, assessing and predicting its changes under the influence of natural and anthropogenic factors. The main objectives of monitoring are to ensure that the environmental management and environmental safety management system is provided with timely and reliable information that allows us to evaluate indicators of the human environment, identify the causes of changes in these indicators and evaluate the consequences of such changes, create the prerequisites for determining measures to correct negative situations that arise before how the damage will be caused [1. Mikryukov V.Yu. Life safety. Rostov-on-Don, Phoenix, 2007, p.346]. For local monitoring, mobile stations and stationary control centers (posts) for various physical fields are used, and for regional monitoring, in addition to local monitoring, helicopters, airplanes and spacecraft are used to monitor the state of the earth's surface, mineral resources of the subsoil, preservation of animal and plant life, etc. [2. Korobkin V.I., Peredelsky L.V. Ecology. Rostov-on-Don, Phoenix, 2007, p.531-533, 586, 589].

In addition, the development of promising monitoring methods and systems is underway, involving the coupling of existing heterogeneous monitoring systems (operational control). So, for example, in [3. Patent for invention, Russia, No. 2296421, IPC Н04В 7/185, 2007] a system for automated monitoring of the state of potentially dangerous objects of the Russian Federation is proposed in the interest of providing protection against technological, natural and terrorist threats. In the process of developing such methods and systems, the main problematic issues are differences in the methods of obtaining and presenting information in interfaced systems.

Currently, several methods for integrated monitoring of the region are proposed.

So, for example, methods for integrated monitoring of a settlement are known [4. Patent for invention, Russia, No. 2217804, IPC G09B 29/00, G01C 11/00, 2003; 5. Patent for invention, Russia, No. 2234085, IPC G01N 33/00, G01N 33/18, 2004] and the surveyed earth's surface [6. Application for invention, Russia, No. 2003115635, IPC G09B 29/00, 2006], including remote sensing (space and (or) aerial photography in the visible and infrared spectra of electromagnetic radiation) and sampling, transferring the results of remote sensing and samples to the processing center, interpretation of photographs and analysis of samples, processing of results and assessment of the state of a settlement or the earth's surface. The disadvantages of these methods are: large time costs for the transmission of measurement information, its updating and processing to assess the state of a settlement or the earth's surface and the operational forecasting of changes in their condition.

A known method of conducting integrated monitoring of natural environments [7. Application for invention, Russia, No. 99104970, IPC G01W 1/00, 2001], including the collection of information on the state of the environment by remote (space or aerial photography) and contact (sampling) methods, data transmission to a stationary information processing center and its processing. The disadvantages of this method are: the low efficiency of updating the measurement information and obtaining the results of assessing the state of the environment, due to the need for transmission of large amounts of measurement information via communication lines and, as a result, the limited suitability of the results of predicting changes in the state of the environment to prevent the occurrence and development of emergencies; the possibility of applying the method to solve only a specific problem and, as a consequence, insufficient suitability to obtain a comprehensive (taking into account the entire list of normalized parameters) assessment of the state of the environment.

The closest analogue (prototype) of the claimed method is the method [8. Patent for invention, Russia, No. 2243554, IPC G01N 33/00, 2004], which allows a comprehensive assessment of the environmental situation and its changes in the region, divided into administrative-territorial entities, including objects of control. The specified method involves collecting data by measuring the values of the characteristics of the objects of control by remote and contact methods, their processing and assessment of the environmental situation by individual indicators of environmental quality with the definition of territories with different environmental conditions.

The disadvantages of this method are: the large time spent on the transfer of measurement information, its updating and processing and, as a result, the limited suitability of the results of the assessment and prediction of changes in the state of the environmental situation for the formation of control actions for adjusting the values of environmental characteristics; limited opportunities for the simultaneous presentation (display) of the results of assessing the state of the entire set of controlled characteristics and the dynamics of changes in the ecological situation of the region and, as a result, the low efficiency of assessing the conformity of the environment of the region to established standards and its changes.

The objective of the present invention is to increase the efficiency of assessing the compliance of the environment of the region with established standards and its changes.

The solution of the problem and obtaining the technical result is ensured by the method of integrated monitoring of the environment of the region, divided into administrative-territorial formations, including control objects, in which to collect data, measure the characteristics of the control objects by remote and contact methods and evaluate the change in time of environmental quality indicators , in this case, before the start of data collection in the processing and control center, they form a database on the characteristics of approx the environment of the region and the rules for formalizing the results of assessing the state of the environment and its changes, moreover, on the means of control, local databases with acceptable values of the characteristics of the objects of control and uniform rules for formalizing the results of the assessment of their state are formed, then on each means of control the measured and acceptable values of the characteristics of the objects are compared control, record the facts of their compliance and non-compliance with acceptable values, formalize the comparison results in the form of unified ducts data containing graphical and tabular forms, showing recorded facts of compliance and non-compliance of the values of the controlled characteristics with their permissible values, the value of the time of completion of the protocol, the names, numbers and actual values of not corresponding to the acceptable characteristics of the objects of control, transmit the generated protocols to the processing center via communication lines and management, where they form a joint protocol for assessing the environment of the region, for which they combine graphic and integrated they take tabular forms of the protocols received by the control and processing center, record the facts of the presence and direction of changes in environmental characteristics according to the graphic forms of the previous and the last of the combined protocols, and the table shows the actual values of the characteristics and the timing of the end of the formation of protocols on control means, form recorded values of the time series and use it when predicting changes in the environmental characteristics of the region in time.

The method is implemented by forming a processing and control center in the hardware and software complex prior to the start of data collection of the database on the characteristics of the control and environment of the region;

the formation in the hardware-software complex of the processing and control center before the start of data collection, the rules for the formation of the integrated protocols of the results of the assessment of the state of the environment of the region and their use after receiving from the protocol monitoring means the results of the assessment of the state of the objects of control;

the formation of control tools in the hardware and software complexes before the start of collecting data from local databases on the characteristics of the objects of control;

the formation of control tools in the hardware and software complexes before the start of data collection of uniform unified rules for formalizing the results of assessing the state of objects and using them after comparing the collected data with valid values to obtain protocols for the results of assessing the state of objects of control;

transmission via communication lines of protocols of the results of the assessment of the state of objects, and not of all data arrays obtained by means of control;

using in the processing and control center the rules for the formation of joint protocols for the results of environmental assessment of the region, eliminating the need for data processing operations used on control tools to obtain protocols for the results of assessing the status of objects of control.

The proposed method differs from the known in the presence and sequence of new actions:

Prior to the start of data collection, a database on the characteristics of the control and environment of the region is formed in the hardware and software complex of the processing and control center;

Prior to the start of data collection, hardware-software complexes of control facilities form databases on the characteristics of objects;

prior to the start of data collection in the hardware and software complex of the processing and control center, formulate the rules for formalizing the results of the assessment of the environment of the region and use them after the processing and control center receives protocols from monitoring facilities;

prior to the start of data collection in the hardware-software complexes of control tools, formulate unified rules for formalizing the results of assessing the state of controlled objects and use them on control tools after collecting data and comparing them with acceptable values;

transmit to the processing and control center from means of control over communication lines only unified protocols of the results of assessing the state of objects, and not all data sets received by means of control;

in the hardware-software complex of the processing and control center they process the data contained in the unified protocols of the results of the assessment of the state of objects.

Figure 1 presents the implementation diagram of the proposed method, which shows: region 1, divided into administrative-territorial formations 2.1, (, 2.v *, including objects of control 3.1, (, 3.I, as well as funds dispersed in the region control 4.1, (, 4.η *, communication lines 5.1, (, 5.η * for transmitting standardized protocols 6.1, (, 6.η * the results of assessing the state of objects of control 3.1, (, 3.I from control means 41, ( , 4.η * to the processing and control center 7.

Figure 2 presents the diagram used to illustrate the feasibility of the proposed method.

In accordance with the claimed method, before the start of data collection in region 1, divided into administrative-territorial formations 2.1, (, 2.v *, including objects of control 3.1, (, 3.I, in the processing and control center 7 form:

database 8 containing identifiers ID = {IS, IO, IY}, where IS = {ISη} are identifiers of controls, IO = {IO _i }, i = 1, (, I are identifiers of objects of control and IY = {y _ij } - identifiers of the controlled environmental characteristics of the region;

a sequence of time points {t _n }, n = 1, (, N (transmission of unified protocols 6.1, (, 6. η * from control means 4.1, (, 4.η * to the processing and control center 7, with t _n = t ₀ + nΔη, where t ₀ is the monitoring start time, Δ _η , is the time interval for the transmission of unified protocols specified for the η-means, the value of which may decrease depending on the dynamics of changes in the state of the objects under control;

set of rules providing:

display of the content received from means 4.1, (, 4.η * of control of unified protocols 6.1, (, 6.η) * of results of assessment of the state of objects of control 3.1, (, 3.1;

formation of joint protocols for 9 results of the assessment of the environment of the region.

On each means of control 4.1, (, 4.η * form the local database 10.1, (, 10.η *, containing:

number (means of control, numbers {j} _iη ∈J assigned by the processing and control center of 7 characteristics, according to which on the η-th means they assess the compliance of the state of the object of control 3.1 with the established standards, while J = {1,2, ..., J} - numbers of environmental characteristics of the region;

нижних и верхних границ интервалов допустимых значений для каждой из контролируемой конкретным средством 4.1,…,4.η^* совокупности характеристик

, по которым производят оценку соответствия состояния объекта контроля 3.1,…,3.I установленным нормам;the matrix

the lower and upper boundaries of the intervals of acceptable values for each of a particular means controlled by 4.1, ..., 4.η ^* set of characteristics

which assess the conformity of the state of the object of control 3.1, ..., 3.I with established standards;

glossary of terms that are used to form the text part of the tabular form Ŧ = {Ŧ ₁ , Ŧ ₂ } of unified protocols 6.1, ..., 6.η ^{* of the} results of the assessment of the state of control objects 3.1, ..., 3.I that are part of the region. Wherein

Ŧ ₁ - the text part of a uniform form for all means, which is intended to display the time of completion of the formation of protocols 6.1, ..., 6.η ^* , identifiers (names) of types of controls 4.1, ..., 4.η ^* , numbers of objects of control 3.1, ... , 3.I and location coordinates of objects and controls; Ŧ ₂ - the text part of the tabular form, the content of which is formed depending on the results of monitoring the characteristics of the objects of control 3.1, ..., 3.I by a specific means of control;

a set of unified rules that ensure the conversion of heterogeneous data collected by means of control 4.1, ..., 4.η ^* for calculating the values of characteristics by which the state of the objects of control 3.1, ..., 3.I is evaluated, the formation and transmission to the processing and control center of 7 messages, formalized in the form of unified protocols 6.1, ..., 6.η ^{* of the} results of the assessment of the state of objects 3.1, ..., 3.I of the control.

значений характеристик, по которым оценивают состояние объектов 3.1,…,3.I контроля.From the time t _{0 of the} beginning of monitoring on each means 4.1, ..., 4.η ^{* of the} control, K _j measurements of the values of each of the characteristics assigned to control the means are carried out. Then, in accordance with the introduced rules on the measured values of y _ijk , k = 1, ..., K _j on each tool 4.1, ..., 4.η ^* form a population

values of characteristics by which the state of objects 3.1, ..., 3.I is evaluated.

. В случаях их невыполнения находят величины Δ_ij, являющиеся мерой несоответствия измеренных значений характеристик объектов контроля допустимым значениям:Next, verify the conditions

. In cases of non-compliance, Δ _ij values are found, which are a measure of the mismatch of the measured values of the characteristics of the objects of control with the permissible values:

проконтролированных характеристик, не соответствующих допустимым значениям.The values Δ _ij are placed in a tabular form of a unified protocol for assessing the state of the object of monitoring results with the identifiers IY _j and the actual values

controlled characteristics that do not meet acceptable values.

Next, a set of values δ1 _{ij of} indicators of compliance of the values of the controlled characteristics with the permissible values is formed:

Then form the graphic form of the protocols 6.1, ..., 6.η ^* , which contain the results of comparing the actual and allowable values of all the controlled characteristics of the objects under control, formalized in the form of a closed polyline (Fig. 3).

Formalization is carried out according to the following uniform rules for all means of control.

находится в поле допуска (например,

), в полярной системе координат фиксируют точки с координатами

на окружности, где ρ_ij=δ1_ij=1 - единичный радиус и θ_ij - угол поворота радиуса (так, для

это будут

(фиг.3). Значения θ_ij находят по формуле:In case the actual value

is in the tolerance field (e.g.

), in the polar coordinate system fix points with coordinates

on the circle, where ρ _ij = δ1 _ij = 1 is the unit radius and θ _ij is the angle of rotation of the radius (so, for

it will be

(figure 3). The values of θ _{ij are} found by the formula:

where R is the degree measure of the radian.

находится вне поля допуска, фиксируют точки с координатами (δ1_ij, θ_ij), не находящиеся на окружности, так как ρ_ij=δ1_ij, а δ1_ij=Δ_ij≠1. Все зафиксированные точки последовательно, начиная с первой, соединяют линией. При этом образуются изломы линии (например,

) в местах расположения точек, не находящихся на окружности (фиг.3).In case the actual value

is outside the tolerance field, fix the points with coordinates (δ1 _ij , θ _ij ) that are not on the circle, since ρ _ij = δ1 _ij and δ1 _ij = Δ _ij ≠ 1. All fixed points are connected in series, starting with the first, by a line. In this case, line breaks are formed (for example,

) at the locations of points that are not on the circle (figure 3).

или верхней

границы допуска. То есть при условии, если фактические значения контролируемых характеристик находятся в границах допуска, то показателю δ1_ij соответствия присваивают «1». В противном случае - показателюThe number of all fixed points on the circle and outside it is equal to the number J _{i of} controlled characteristics of the control object 3.i. The direction and magnitude of the fracture of the line is formed according to the analysis of the situation in which there was a violation of the bottom

or top

border tolerance. That is, provided that the actual values of the controlled characteristics are within the tolerance, then the compliance indicator δ1 _{ij is} assigned “1”. Otherwise, the indicator

это будет

и фиксируют значение j (фиг.3).δ1 _{ij of} correspondence assign the value Δ _ij (so, for example, for

This will

and fix the value of j (figure 3).

.The formed closed polygonal lines δ1 _ij = f (ρ _ij , θ _ij ) (Figs. 3-5) are interpreted as images of the actual states of objects of control 3.1 ... 3.I at the moment of termination of control. Figure 3-7 presents the values of δ1 _ij and the designation of their respective characteristics

.

размещают в текстовой части Ŧ₂ табличной формы протокола, а в текстовой части Ŧ₁ - зафиксированное значение времени t_Пη окончания формирования унифицированного протокола.For clarity, the visual display of the facts of correspondence and discrepancy between the actual and the reference state in the same coordinate system form broken lines E _ij = f (ρ _ij = 1, θ _ij ) connecting the points located on the circle J _i with the coordinates (ρ _ij = 1, θ _ij ), and interpret them as reference images of states of objects of control 3.1 ... 3.I. Values Δ _ij , j,

placed in the text part Ŧ _{2 of the} tabular form of the protocol, and in the text part Ŧ ₁ - the fixed value of time t _{Пη of the} end of the formation of the unified protocol.

At the appointed time points {t _n } ∈t, from each means 4.1, ..., 4.η ^{* of the} control, they are transferred via communication lines 5.1, ..., 5.η ^* to the processing and control center 7 unified protocols 6.1, ..., 6.η ^* the results of assessing the state of objects of control by the totality of characteristics controlled by these means, and not all the data obtained by means of control, which reduces the time for their transmission.

To analyze the results of integrated monitoring and decision-making on the state of the environment in the processing and control center 7 after receiving unified protocols 6.1, ..., 6.η ^* from control means by combining their graphic forms (Figs. 3-5) and combining tabular forms (tab. .3-5) protocols form the combined protocols 9 of the state of the environment of the region (Fig.6 and table.9).

и времени окончания формирования протоколов t_Пη.Next, they combine the graphic forms of the previous and last of the generated combined protocols 9 (Fig. 7) and record the facts of the presence and direction of changes in the environmental characteristics Δ _ij (t _n -t _n-1 ), and the actual values of the characteristics are recorded from their tabular forms

and the time of completion of the formation of protocols t _Пη .

,

и модель изменения характеристик во времени

, где а₀, a₁,… - коэффициенты модели, вычисленные по значениям временного ряда, F_j - оператор, определяющий форму зависимости, экстраполируют, получают точечную и интервальную оценку значений [9. Елисеева И.И., Юзбашев М.М. Общая теория статистики, Москва, Финансы и Статистика, 1995, с.245-256, с.304-313] характеристик окружающей среды

, при которых может возникнуть чрезвычайная ситуация, и фиксируют моменты времени t_ЧС достижения этих значений.Then, a time series (

,

and model of change in characteristics over time

, where a ₀ , a ₁ , ... are the coefficients of the model calculated from the values of the time series, F _j is the operator that determines the form of the dependence, extrapolated, get a point and interval estimate of the values [9. Eliseeva I.I., Yuzbashev M.M. General Theory of Statistics, Moscow, Finance and Statistics, 1995, p.245-256, p.304-313] environmental characteristics

at which an emergency may occur, and fix the moments of time t _{ES of} reaching these values.

Next, subtract from the fixed values of the time t _{ES the} values of the time t _{C of} their receipt at the processing and control center, and from the difference values determine the duration of the intervals ΔT = t _ES- t _C time for measures to prevent emergencies. Then, taking into account the results of forecasting changes in the values of the environmental characteristics, decisions are made on the use of monitoring forces and means, as well as units designed to eliminate or prevent violations of established norms.

The set of essential features of the proposed method for integrated monitoring of the environment of the region exhibits new properties of the method, namely, that by transmitting unified protocols for the results of assessing the state of the objects of control formed on the means of control according to pre-established formalization rules and containing the effective part of assessing the state of the objects of control, the assessment efficiency increases compliance of the environment of the region with established standards and the level of pollution is reduced Handsets with limited bandwidth; The formation of the unified protocol of the results of the assessment of the environment of the region eliminates the need for special methodological support for processing heterogeneous data, and thus reduces the time, unification and compactness of the presentation of the results of the assessment of the state of the environment of the region and its changes, regardless of the number and types of controlled objects, the conditions of their functioning, the quantity and physical nature of their controlled characteristics; Processing the combined protocols of the results of the assessment of the state of the environment of the region reduces the time it takes to prepare the initial data to predict changes in the state of the environment of the region.

The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed invention with the “novelty” protection criteria.

Search results for known solutions in this and related fields of technology in order to identify features that match the distinguishing features of the proposed method have shown that no solutions having features matching its distinctive features have been identified in publicly available information sources. The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed invention on the technical result indicated by the applicant, therefore, the claimed invention meets the condition of "inventive step".

The possibility of implementing the proposed method of integrated environmental monitoring of the region is confirmed by the following example.

Suppose that it is required to conduct (Fig. 2) a comprehensive environmental monitoring of region 1, consisting of two administrative-territorial associations 2.1 and 2.2, while 2.1 contains two objects of control: 3.1 and 3.2, and 2.2 - one object of control 3.3.

j={1,2,3},

j={4,5,6,7} и

j={8,9,10,11) соответственно. Измерение значений характеристик

j={1,2,3},

j={4,5,6,7} и

j={8,9,10,11}, а также оценка состояния объектов 3.1, 3.2 и 3.3 должны проводиться средствами контроля 4.1, 4.2 и 4.3 соответственно.The environmental condition of the region must be estimated by 11 characteristics J ^* = {1, ..., j, ..., 11}. In this case, the state of objects 3.1, 3.2 and 3.3 should be evaluated according to the characteristics

j = {1,2,3},

j = {4,5,6,7} and

j = {8,9,10,11), respectively. Characteristic Measurement

j = {1,2,3},

j = {4,5,6,7} and

j = {8,9,10,11}, as well as an assessment of the state of objects 3.1, 3.2 and 3.3 should be carried out by means of control 4.1, 4.2 and 4.3, respectively.

It is known that the environmental monitoring of the region should begin at 11 hours and 40 minutes, and the transmission time interval for the unified protocols should be 20 minutes.

Prior to the start of data collection, a database 8, shown in table 1, and local databases 10.1, 10.2, and 10.3 in the hardware-software complexes of control tools, shown in table 2, respectively, were formed in the hardware-software complex of the processing and control center.

, j={1,2,3},

, j={4,5,6,7} соответственно, а на средстве 4.3 проведены измерения значений четырех характеристик

j={8,9,10,11} с частотой 100 измерений в секунду и сформирован массив y_3jk, k=1,…,K_j объемом 40 Мб.At time t ₀ = 11 hours and 40 minutes, means of control 4.1, 4.2 and 4.3 started and within 20 minutes measured K _j values of 11 characteristics and at time t ₁ = 12 hours 00 min the means values 4.1 and 4.2 were obtained

, j = {1,2,3},

, j = {4,5,6,7}, respectively, and on the means of 4.3 measurements of the values of four characteristics

j = {8,9,10,11} with a frequency of 100 measurements per second and an array of y _3jk , k = 1, ..., K _j of 40 Mb volume is formed.

значений характеристик, по которым оценивают состояние объекта контроля 3.3.Then, according to the measured values of y _3jk , k = 1, ..., K _j on the tool 4.3 form a set

values of characteristics by which the state of the control object is evaluated 3.3.

,

и

объектов контроля 3.1, 3.2 и 3.3 и результаты сравнения этих значений с имеющимися в локальных базах данных 10.1, 10.2 и 10.3 средств контроля допустимыми значениями

,

, i=1…3, j=1…11 приведены в таблицах 3-5 соответственно.The actual values of the controlled characteristics obtained by means of control 4.1, 4.2 and 4.3

,

and

objects of control 3.1, 3.2, and 3.3 and the results of comparing these values with the available control values available in local databases 10.1, 10.2, and 10.3

,

, i = 1 ... 3, j = 1 ... 11 are given in tables 3-5, respectively.

Next, on the basis of the data from tables 3-5, graphical and tabular forms of unified protocols 6.1, 6.2 and 6.3 of the results of the assessment of the state of the objects of control 3.1,3.2 and 3.3, presented in Figures 3-5 and in tables 6-8, respectively, are formed. The volume of the unified protocol generated by means of 4.3 of the results of the assessment of the state of the control object 3.3 is ~ 30 Kb.

Then, from control means 3.1, 3.2 and 3.3, unified protocols 6.1, 6.2 and 6.3 of the results of the assessment of the state of the objects of control, and not all the heterogeneous data received by the control means, are transmitted to the processing and control center 7 via communication lines 5.1, 5.2 and 5.3, as is done in known monitoring methods. The time required to transmit each protocol is no more than 15 seconds. The transfer of a 40 MB data array would lead to an increase in the transmission time from the 4.3 monitoring tool to approximately 5 hours when using modern communication tools that provide a data transfer rate of 16 Kb per second [10. Communication in the Armed Forces of the Russian Federation - 2007. Thematic collection. Moscow, LLC "Company" Information Bridge ", 2007, p.128].

After completion of the transfer of unified protocols 6.1, 6.2 and 6.3 of the results of the assessment of the state of the objects of control on the control means, the next cycle of measurements of the values of the characteristics of the objects of control, the formation and transmission of unified protocols is performed.

In the processing and control center 7, a combined protocol 9 of the results of the environmental assessment of the region 1 is formed, the graphic form of which is shown in Fig.6, and its tabular form is shown in table 9.

At the time t ₂ = 12 h 20 min, the control means 4.1, 4.2 and 4.3 will form and transmit the unified protocols 6.1, 6.2 and 6.3 to the processing and control center 7, where the next unified protocol 9 of the results of the assessment of the state of the environment of region 1 will be generated.

After combining the two received at time t ₁ = 12 h 00 min and t ₂ = 12 h 20 min combined protocols 9 state assessment (Fig.7) according to Δ ₁₃ (t ₂ -t ₁ ) and

и

, по значениюΔ ₂₆ (t ₂ -t ₁ ) record the facts of increasing values of the characteristics

and

by value

и по равенству

- подтверждение факта нарушения по характеристике

соответственно.Δ ₃₁₁ (t ₂ -t ₁ ) - transition within the tolerance of the characteristic value

and by equality

- confirmation of the fact of violation according to the characteristic

respectively.

,

; t₁, t₂); (

,

; t₁, t₂), которые используют как исходные данные для прогнозирования изменений характеристик во времени.Next, form the time series: (

,

; t ₁ , t ₂ ); (

,

; t ₁ , t ₂ ), which are used as input to predict changes in characteristics over time.

According to the results of forecasting, time instants t of _{emergency situations} of emergency situations are recorded and the duration of the intervals ΔТ = t _{emergency situations} -t _C time is determined for measures to prevent emergencies.

Table 1 The method of integrated monitoring of the environment of the region Identity
fish
environmental characteristics IY Name of environmental characteristics, units rev. Maximum permissible levels (MPL) of chemical and physical pollution of the environment Remote Identifiers Remote Values y ₁₁ The concentration of nitric oxide in atmospheric air, mg / m ³

0.6 y ₁₂ The concentration of carbon monoxide in atmospheric air, mg / m ³

5,0 y ₁₃ The concentration of formaldehyde in atmospheric air, mg / m ³

0,035 y ₂₄ The concentration of lead in drinking water, mg / l

0.1 y ₂₅ The concentration of butyl acetate in drinking water, mg / l

0.1 y ₂₆ The concentration of methanol in drinking water, mg / l

3.0 y ₂₇ The concentration of strontium in drinking water, mg / l

2.0 y ₃₈ Electrostatic field strength, kV / m

60 y ₃₉ Magnetic field strength, kA / m

8 y ₃₁₀ Microwave power flux density, W / m ²

10 y ₃₁₁ Carrier frequency of microwave radiation, GHz

2.5 ... 2.65 Identity
ry controls Name of controls Identifiers of objects of control Name of objects of control 4.1 Stationary post of environmental control 3.1 Industrial facility 4.2 Mobile environmental control station 3.2 Water supply facility 4.3 Mobile electromagnetic radiation monitoring station 3.3 Electronic object

table 2 The method of integrated monitoring of the environment of the region Identity
Ry and
name of controls Identifiers and names of objects of control Identifiers of environmental characteristics to be monitored at the monitoring facility Identifiers and remote control values of controlled characteristics Remote Identifiers Remote Values 4.1 - stationary post of environmental control 3.1 - industrial facility y ₁₁

0.6 y ₁₂

5,0 y ₁₃

0,035 4.2 - mobile environmental control station 3.2 - water supply facility y ₂₄

0.1 y ₂₅

0.1 y ₂₆

3.0 y ₂₇

2.0 4.3 - a mobile station for monitoring electromagnet
radiation 3.3 - electronic object y ₃₈

60 y ₃₉

8 y ₃₁₀

10 y ₃₁₁

2.5 ... 2.65

Table 3 Controlled Features Actual Values Remote control comparison results

0.2 δ1 ₁₁ = 1

2.7 δ1 ₁₂ = 1

0.04 Δ ₁₃ = 1.14

Table 4 Controlled Features Actual Values Remote control comparison results

0.05 δ1 ₂₄ = 1

0.01 δ1 ₂₅ = 1

3,5 Δ ₂₆ = 1.21

0.09 δ1 ₂₇ = 1

Table 5 The method of integrated monitoring of the environment of the region Controlled Features Actual Values Remote control comparison results

59 δ1 ₃₈ = 1

9 Δ ₃₉ = 1.13

9 δ1 ₃₁₀ = 1

2,485 Δ ₃₁₁ = 0.82

Table 6 Control ID 4.1 Latitude Control Coordinate 52 ° 04 'N Longitude Control Coordinate 40 ° 04 'East Protocol completion time date, hours and min 12.12.2007 12.00 ID of the object of control 3.1 Latitude coordinate of the control object 52 ° 00 'N Coordinate of the object of control in longitude 40 ° 04 'East The identifier of the characteristics of the control object

The actual value of the characteristics of the object of control 0.04 The value of the mismatch of the characteristics of the remote control object, Δ ₁₃ 1.14

Table 7 Control ID 4.2 Latitude Control Coordinate 52 ° 02 'N Longitude Control Coordinate 40 ° 05 'East Protocol completion time date, hours and min 12.12.2007 12.00 ID of the object of control 3.2 Latitude coordinate of the control object 52 ° 00 'N Coordinate of the object of control in longitude 40 ° 00 'E The identifier of the characteristics of the control object

The actual value of the characteristics of the object of control 3,5 The magnitude of the mismatch of the characteristics of the remote control object, Δ ₂₆ 1.21

Table 8 Control ID 4.3 Latitude Control Coordinate 52 ° 03 'N Longitude Control Coordinate 40 ° 03 'East Protocol completion time date, hours and min 12.12.2007 12.00 ID of the object of control 3.3 Latitude coordinate of the control object 52 ° 03 'N Longitude 40 ° 03 'East The identifier of the characteristics of the control object

The actual value of the characteristics of the object of control 9 2,485 The value of the mismatch of the characteristics of the remote control object, Δ ₃₉ 1.13 0.82

Table 9 The method of integrated monitoring of the environment of the region 4.1 4.2 4.3 52 ° 04 'N 52 ° 02 'N 52 ° 03 'N 40 ° 04 'East 40 ° 05 'East 40 ° 03 'East 12.12.2007 12.00 12.12.2007 12.00 12.12.2007 12.00 3.1 3.2 3.3 52 ° 00 'N 52 ° 00 'N 52 ° 03 'N 40 ° 04 'East 40 ° 00 'E 40 ° 03 'East

0.04 3,5 9 2,485 1.14 1.21 1.13 0.82

Table 10 4.1 4.2 4.3 52 ° 04 'N 52 ° 02 'N 52 ° 03'N 40 ° 04 'East 40 ° 05 'East 40 ° 03 'East 12.12.2007 12.20 12.12.2007 12.20 12.12.2007 12.20 3.1 3.2 3.3 52 ° 00 'N 52 ° 00'N 52 ° 03 'N 40 ° 04 'East 40 ° 00 'E 40 ° 03 'East

0,041 3,59 9 1.37 1.24 1.13

Claims (1)

A method for integrated monitoring of the environment of a region, divided into administrative-territorial entities, including control objects, in which data values are measured by characteristics of control objects by remote and contact methods and an assessment is made of the change in time of environmental quality indicators, characterized in that before the collection begins data in the processing and management center form a database on the environmental characteristics of the region and the rules for formalizing the assessment results with the state of the environment and its changes, and on the means of control, local databases are formed with acceptable values of the characteristics of the objects of control and uniform rules for formalizing the results of the assessment of their condition, then on each means of control the measured and acceptable values of the characteristics of the objects of control are compared, the facts of their conformity and inconsistency are recorded permissible values, formalize the comparison results in the form of unified protocols containing graphic and tabular forms that display fixed The facts of conformity and non-compliance of the values of the controlled characteristics with their permissible values, the value of the time of completion of the protocol, the names, numbers and actual values of the parameters that do not correspond to the permissible characteristics of the objects of control are transmitted via communication lines to the processing and control center, where they form a joint protocol for assessing the state of the environment environment of the region, for which they combine graphic and combine tabular forms received by the control and processing center rounds, the facts of the presence and direction of changes in the environmental characteristics are recorded according to the graphic forms of the previous and the last of the generated combined protocols, and the actual values of the characteristics and the timing of the end of the formation of protocols on the control means are tabulated, form the time series from the fixed values and use it when predicting changes in the environmental characteristics of the region over time.

Images