RU2380890C1 - Method for testing of grass cover on near-bed floodplain - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention may be used in biotechnical and biochemical assessment of grass cover in near-bed floodplain meadows and small meadows of forests. On small river or its tributary, with measured length and area of basin, section of bed is separated with dry or floodplain meadows, and biogeocenosis is identified in coastal part with borders of tested grass cover, then on this section of near-bed meadow, along with water flow, multiple temporary hydrometric sections are marked perpendicular to bed with measurement of distances between them, besides section lines are continued to the border of grass cover across bed, and number of temporary hydrometric sections is accepted as sufficient for formation of test sites network by grass cover, besides along each temporary hydrometric section, multiple test sites are marked with alternating distances between them, then grass samples are cut and exposed to tests from each test site, on completion of grass samples tests, distances are measured from shore horizon, accepted as origin of coordinates in all temporary hydrometric sections, to centres of sites, in case height difference makes more than 10.0 cm, height of each test site centre location is measured from water surface, afterwards, length and drop are measured in bed section, and also common permanent geodesic reference point is established to monitor properties of grass cover.

EFFECT: improved accuracy of measurements by test results of grass samples cut from test sites on the territory of near-bed floodplain meadow, and improved functional resources for detection of law in influence of relief parametres at crop capacity of meadow grass and soil productivity in near-bed floodplain of small river or its separate tributary, which are located in specially protected areas.

9 cl, 6 dwg

Description

The invention relates to riverbed landscapes of rivers with natural grass vegetation, for example, in specially protected areas, and can be used for biotechnical and biochemical assessment of grass cover in river bed floodplain meadows and forest meadows. The technical solution can also be applied when taking into account the influence on the productivity and other properties of grass of the orographic parameters of the riverine relief.

There is a method of testing grass cover on the riverbed and near-floodplains of the river according to Academician V.R. Williams [Mosolov V.P. Perennial grasses and agrotechnical basis of crop rotation / V.P. Mosolov. - Works. - Volume III. - M .: Gosselkhozizdat, 1953. - 536 p., P. 68], which includes the correct combination of woody vegetation with perennial herbaceous plants to combat soil erosion.

According to the academician V.R. Williams himself [Williams V.R. Collected works. Volume Four: Meadow Cultivation (1901-1933) / V.R. Williams. - M .: State. publishing house of agricultural enterprises. Liters, 1949. - 502 p., p. 91] on the lower part of the slopes in the river valley there are the best conditions for the growth and development of river bed meadow grass. Here it reaches such a degree of development that it completely suppresses the natural regeneration of woody plants of forest plant communities. Due to the predominance of plants of mycotrophic type of nutrition in floodplain meadows, even plants of the steppe herbaceous formation do not find conditions for their growth here.

The structure of phytocenoses and the distribution of grass and other vegetation across the river and its floodplains were considered by V. R. Williams in detail in the book [V. Williams. Selected Works / V.R. Williams; Ed. V.P. Bushinsky. Volume III The scientific basis of meadow farming (1922-1933). - M.: Publishing House of the Academy of Sciences of the USSR, 1955. -1008 p., P. 734-747, 898-905].

The disadvantage of this method is the low accuracy of assessing the quality of the near-river floodplain meadow, that is, the plant formation along the banks of rivers and their tributaries. Moreover, rivers of different sizes not only have a difference in hydrometric properties along the slopes, but also different pictures of the biotechnical and biochemical distribution of grass by yield in wet and air-dry conditions. As a result, by analogy, it is not possible to quantitatively measure the properties of the grass cover as a whole on the most vulnerable coastal relief of the river valley. In addition, according to many experimental data, at least nine repetitions in the same meaning observations are required to identify the average grass yield and the average productivity of the near-bed soil. However, even this does not allow to obtain patterns of grass distribution in the near-river meadow with errors of less than 15%.

There is also a method of measuring grass cover on the catchment area according to the length and fall of the tributaries according to patent No. 2293290, MKI G01C 13/00, including measuring the length of the tributaries and the catchment area of the river tributaries, as well as the fall of the tributaries as the height difference between their sources and mouths, distribution of tributaries by distinguishing groups on the presence of vegetation in the territories of the river basin and its tributaries, an assessment of the influence of the distinctive orographic features of the relief located on the territory of the river tributary.

The disadvantage is the use of measurements only by visual estimation of the catchment area as a whole for each tributary by the presence of vegetation cover. Therefore, the influx of a small river is considered entirely by the catchment area without separation according to individual biogeocenoses, in particular, many tributaries and floodplain meadows located on them are not considered on the tributary. Therefore, such a rough estimate over the entire tributary does not allow us to measure the effect of the river and its channel on the properties of grass cover on trial sites.

EFFECT: increased accuracy of measurements based on test results of grass samples cut from test sites on the territory of a river bed of one floodplain meadow, and increased functionality to identify patterns of influence of relief parameters on the yield of meadow grass and soil productivity on the river bed of a small river or its individual tributary in specially protected areas (reserves and national parks).

This technical result is achieved by the fact that the method of testing grass cover in the riverbed meadow, including measuring the length of the tributaries and the catchment area of the river tributaries, as well as the fall of the tributaries as the height difference between their sources and estuaries, the distribution of the tributaries according to the distinctive groups by the presence of vegetation in the basin areas catchment of the river and its tributaries, assessment of the influence of distinctive orographic features of the relief and landscape located on the catchment area of tributaries, characterized in that the length of the catchment area of a small river or its tributary, a section of the channel in a river valley with an empty or floodplain meadow is visually identified on a map or in situ, and a land plot in the form of a biogeocenosis is identified on the coastal part of this valley with the definition of the boundaries of the test grass cover, then a land plot of a river bed in the course of the water marks a lot of temporary hydrometric gauges perpendicularly to the channel with a measurement of the distances between them, with the line lines extending to the boundary of the grass cover and across the channel, and the number of temporary hydrometric sections is taken sufficient to form a network of test sites throughout the test grass cover, along with each temporary hydrometric gauge, many test sites with variable distances between them are marked, then grass samples are cut and tested from each test site , after testing grass samples, measure the distance from the water line taken as the origin at all temporary hydrometric gauges to prices of sample plots cleared of grass samples, with a difference in the height of the test plots of more than 10.0 cm, the height of the center of each test site from the surface of the river’s water surface or its tributary is also measured, then the length and fall of the river or its tributary in the selected channel section are measured, and they also establish a common permanent geodetic benchmark for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover.

Visually, on a map or in-situ, in the especially unprotected territories of river valleys, a land plot of the entire non-flood or floodplain meadow with the tested ecosystem grass cover before haying is carried out, and the sizes of the test sites take 0.50 × 0.50 m.

In the course of the small river or its tributary, bends and other forms of channel formation of the small river or its tributary are taken as natural characteristic places, moreover, tests of grass cover are performed in specially protected areas, and then, taking into account the revealed patterns of spatial changes in the properties of grass samples, the tests continue near-river meadows with an increasing anthropogenic load on biogeocenoses.

On small grassy biogeocenoses, at least three temporary hydrometric gauges are marked in the transverse direction to the far boundary of the riverbed meadow with distances between them along the course of the small river or its tributary not less than 5.0 m and not more than 50.0 m, and trial plots placed at intervals between them of not less than 2.00 m between themselves and not more than 20.0 m, and the numbering of temporary hydrometric sections is carried out by the water flow from the beginning of the boundary of the tested grass cover.

At least three test sites are marked out on a small area of grass cover along each hydrometric gauge, and the numbering of test sites measuring 0.50 × 0.50 m is carried out from the channel to the far boundary of the test grass cover.

After taking all grass samples along each temporary hydrometric gauge, a reference test site with the highest or lowest height compared to other test sites is selected, and relative to the reference test sites selected at all temporary hydrometric gauges, they are surveyed relative to a predetermined common permanent geodetic reference point for long-term measurements of the riverbed topography and landscape.

The height of the center of each test site from the water surface in a given section of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter in other seasons of the year are performed using constant geodetic reference points.

According to the results of tests of grass samples, patterns of the influence of the distance along each temporary hydrometric gauge, as well as the influence of the height of the test sites above the water edge, on the biophysical and biochemical parameters of grass samples throughout the network of test sites are revealed, and the effect of the distinctive orographic features of the river channel or its tributary, coastal topography, and natural and anthropogenic objects located inside and outside the territory of the tested grass cover.

After taking grass samples, measurements of the length and fall of the river or its tributary in a selected section of the channel, as well as the establishment of a common constant geodetic reference point for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover, are carried out during the summer low-water period of the river and its tributary.

The essence of the invention lies in the fact that from the area of the catchment area of the tributary of a small river, they pass to the measurement object in the form of a small river bed along it, on which there is a separate river bed non-flood or floodplain meadow. This takes into account not the entire width of the basin to the border of the watershed of this tributary, but only the width of the riverbed zone to the border with the terraced floodplain (thalweg). Such a landscape unit is a biogeocenosis, therefore, the influence of the riverbed on grass productivity and its other biophysical and biochemical properties is studied under natural growing conditions, which can only be found in specially protected territories and natural reserves. As a result, it becomes possible to use the inductive approach in scientific research in biogeocenology, which is more fundamental in comparison with the deductive approach of the prototype.

The essence of the invention lies in the fact that the test site becomes one multifactorial observation, and many test sites distributed in a grid over many temporary hydrometric sections on a given section of the channel, as a rule, a small river throughout the entire section of the riverbed, taking into account the boundaries in it floodplain meadow, becomes a temporary testing ground for unique natural biogeocenoses. Due to the taking of the aerial part of the grass in the form of samples at a test site measuring just 0.50 × 0.50 m, the properties of the grass biogeocenosis practically do not change. With the advent of more accurate portable electronic scales (the measurement error is not more than 0.001 grams), it will be possible to take grass samples from test sites with a total size of 0.100 × 0.100 m (10.0 × 10.0 cm). In the dynamics of the growing season and the hydrological year, it becomes possible to assess the influence of the hydrological and channel regime of the river on grass productivity from a variety of points measured relative to the water mirror in the river.

The essence also lies in the fact that, in addition, the distances between the hydrometric gauges measured perpendicular to the river channel at variable distances of not less than 10.0 m, and the distances between test sites for each gauge are arbitrary and not less than 2.00 m, and when exceeded between the centers of the highest and lowest test sites in a floodplain meadow of at least 10.0 cm, the height of the center of each test site at one temporary hydrometric cross section of the river is measured relative to the lowest or the highest located trial plot. In this case, the lowest or highest located test sites in each temporary hydrometric gauge are measured by the height of their centers from the level of the water surface in the river in the summer low water after testing the grass cover. To ensure the accuracy of measuring the excesses of reference test sites relative to the water edge on long river beds and meadows, also measure the length of the section of the river valley or floodplain and the fall of the river in this section.

The essence also lies in the fact that the specific grass yield at each test site depends not only on the relief parameters relative to the water edge in the river, but also on the channel formation parameters in this section of the river. Herbal biogeocenosis adapts to the relief, and the relief is determined by the annual hydrological regime. Therefore, at first, the laws of the influence of the river bed should be studied in non-flood meadows, and only then it is necessary to switch to floodplain meadows with varying degrees of annual flooding of the floodplain.

The positive effect is that as the number of test plots in each riverine non-flood or floodplain meadow increases, it becomes possible to quantitatively describe the territory within the boundaries of the grass cover (and then the vegetation cover with the inclusion of areas of grass, shrubs, shrubs and trees) in the river valley biogeocenosis , and subsequently the entire influx and the entire river network in the form of a digital model. And many digital models based on the results of testing grass on a large number of temporary test sites will allow us to analyze the dynamics of the behavior of the grass cover of the river network in the space of the water protection zone and water protection zone, and then design plant complexes outside the water protection zone of the river.

Thus, the proposed technical solution has significant features, novelty and a positive effect. In the scientific, technical and patent literature, information materials discrediting the novelty of the alleged invention were not found by us.

Figure 1 shows the location of the river and its riverbed floodplain with showing the boundary of the riverbed meadow with the temporary gauging points outlined on it; figure 2 shows the location of part of the network of test sites at several temporary gauging stations; figure 3 shows a vertical section of one hydrometric alignment with a reference test site; figure 4 shows a diagram of measuring the height of one benchmark test site relative to the water edge in the river in the summer low water; figure 5 - diagram of the geodetic measurement of the height of the centers of the test sites on one temporary hydrometric alignment of the river relative to their total benchmark; Fig.6 is a diagram of a geodetic measurement of the height of the reference test sites of all or part of the temporary hydrometric sections relative to one common geodetic grass cover on the river bed of the river with test sites of 0.50 × 0.50 m in size, arranged in the form of a network with temporary hydrometric gauges on a land plot of a near-river floodplain or floodplain meadow of a small plain river, includes such actions.

First, a river or its tributary is visually examined and places with grass biogeocenoses are marked, and the order of testing of each selected grass cover is established. At the same time, the riverine meadows are subjected to tests at first, and after that they pass to floodplain meadows, and at the end to hayfields and pasture meadows.

The contours of a site of 0.50 × 0.50 m in size at the place of sampling of grass plants are marked with pegs with a cord stretched between them on the sides of the test site, and for multiple sampling of grass when studying the yield of grass and hay by several mowing in the summer season, and To conduct environmental monitoring of the impact of various natural, natural-anthropogenic and anthropogenic objects on the grass cover, they turn the test site into a reference site so that the pegs hammered into the soil are long-term and they are tagged with account number and other data.

On the measured length and area of the catchment of a small river or its tributary, a section of the channel in a river valley with a non-flood or floodplain meadow is visually identified on a map or in-situ, and on the coastal part of this valley, a land plot is allocated in the form of a biogeocenosis with determination of the boundaries of the test grass cover, then on this land plot of a river-bed meadow along the water flow mark perpendicularly to channel 1 between shore 2 and border 3 on meadow 4 a lot of temporary hydrometric sections 5 with measurement of the distances between them, and the lines Hur continues to the boundary 4 meadow grass cover across the bed, and the number of time gauging alignments take sufficient to form a network test platforms 6 across the tested grass cover. At the same time, many test sites with variable distances between them are marked out along each temporary hydrometric gauge, then grass samples are cut and tested from each test site.

After testing grass samples, the distances from the water line taken as the origin to the centers of the test sites cleared of grass samples are measured; when the height of the sample sites is more than 10.0 cm, the height of the center of each test site from the river’s water surface is also measured. inflow, then measure the length and fall of the river or its inflow on a selected section of the channel, and also establish a common constant geodetic reference point for further long-term measurements of the riverbed topography and landscape and annually th monitoring of the properties of the grass cover.

Visually, on a map or in-situ, in the especially unprotected territories of river valleys, a land plot of the entire non-flood or floodplain meadow with the tested ecosystem grass cover before haying is carried out, and the sizes of the test sites take 0.50 × 0.50 m.

Over the course of the small river or its tributary, bends and other forms of channel formation of the small river or its tributary are taken as natural characteristic places, and, first of all, tests of grass cover are carried out in specially protected areas, and then, taking into account the identified patterns of spatial changes in the properties of grass samples, the tests continue near-river meadows with an increasing anthropogenic load on biogeocenoses.

On small grassy biogeocenoses, at least three temporary hydrometric sections are marked in the transverse direction to the far boundary of the river bed with distances L _i between them along the course of the small river or its tributary not less than 5.0 m and not more than 50.0 m, and test sites have l _ij at intervals between them of not less than 2.00 m from each other and not more than 20.0 m, and the numbering of temporary hydrometric sections is carried out by the water flow from the beginning of the boundary of the tested grass cover.

At least three test sites are marked out on a small area of grass cover along each hydrometric gauge, and the numbering of test sites measuring 0.50 × 0.50 m is carried out from the channel to the far boundary of the test grass cover.

After taking all grass samples along each temporary hydrometric gauge, a reference test site 7 with the highest or lowest height compared to other test sites is selected, and relative to the reference test sites selected at all temporary hydrometric gauges, they are surveyed by the device 8 and rail 9 along the sight line 10 with respect to a predetermined common permanent geodetic reference point for long-term measurements of the riverbed topography and landscape.

The height of the center of each test site from the water surface in a given section of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter h _j in other seasons of the year are performed using constant geodetic reference points.

According to the results of tests of grass samples, patterns of the influence of the distance along each temporary hydrometric gauge, as well as the influence of the height of the test sites above the water edge, on the biophysical and biochemical parameters of grass samples throughout the network of test sites are revealed, and the effect of the distinctive orographic features of the river channel or its tributary, coastal topography, and natural and anthropogenic objects located inside and outside the territory of the tested grass cover.

After taking grass samples, measurements of the length and fall of the river or its tributary in a selected section of the channel, as well as the establishment of a common constant geodetic reference point for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover, are carried out during the summer low-water period of the river.

A method for testing grass cover in a near-river non-flood meadow of a small river from test sites of 0.50 × 0.50 m in size, located on a network of temporary hydrometric gauges across the channel of a small river within the boundaries of a river floodplain, for example, in a state reserve, includes such actions.

First, grass cover is examined visually or on a map within the boundaries of 4 in a non-flood riverbed meadow in a specially protected area.

On the land plot in the form of a biogeocenosis, the boundaries of the test grass cover are determined, then, along the stream of the river 1, many temporary hydrometric sections 5 are marked perpendicular to the channel with the measurement of the distances L _i between them.

Moreover, the lines of the lines continue to the border 4 of the grass cover across the channel, and the number of temporary hydrometric sections is sufficient to form a network of test sites 6 with reference sites 7 throughout the test grass cover, while along each temporary hydrometric gauge, many test sites with variable distances between them.

Then, grass samples are cut and tested from each test site.

After conducting tests of grass samples, the distances from the water line taken as the origin at all temporary hydrometric gauges to the centers of test sites cleared of grass samples are measured; when the height of the test sites is different, the height of the center of each test site from surface of the water surface of the river or its tributary. After that, the length and fall of the river or its tributary are measured in a selected section of the channel, and a common constant geodetic reference point is established for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover.

On small grassy biogeocenoses, at least three temporary hydrometric gauges are marked in the transverse direction to the far boundary of the riverbed meadow with distances between them along the course of the small river or its tributary not less than 5.0 m and not more than 50.0 m, and trial plots placed at intervals between them of not less than 2.00 m between themselves and not more than 20.0 m, and the numbering of temporary hydrometric sections is carried out by the water flow from the beginning of the boundary of the tested grass cover.

At least three test sites are marked out on a small area of grass cover along each hydrometric gauge, and the numbering of test sites measuring 0.50 × 0.50 m is carried out from the channel to the far boundary of the test grass cover.

Let a piece of land with grass cover be allocated for many years of monitoring the quality of the environment.

In this case, after taking all grass samples along each temporary hydrometric gauge, a reference test site with the highest or lowest height is selected compared to other test sites, and relative to the reference test sites selected at all temporary hydrometric gauges, they are surveyed relative to a predetermined common permanent geodetic benchmark for measurements of the riverbed topography and landscape.

The height of the center of each test site from the water surface in a given section of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this relief parameter in other seasons of the year are performed using constant geodetic reference points.

According to the results of tests of grass samples, patterns of the influence of the distance along each temporary hydrometric gauge, as well as the influence of the height of the test sites above the water edge, on the biophysical and biochemical parameters of grass samples throughout the network of test sites are revealed, and the effect of the distinctive orographic features of the river channel or its tributary, coastal topography, and natural and anthropogenic objects located inside and outside the territory of the tested grass cover.

After taking grass samples, measurements of the length and fall of the river or its tributary in a selected section of the channel, as well as the establishment of a common constant geodetic reference point for long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover, are carried out during the summer low-water period of the river and its tributary.

The proposed method is simple in practical implementation, especially in cases of testing without fixing the distances and heights of the test sites and without conducting geodetic measurements. It allows you to learn about the behavior of the totality of grass samples, and through this about the behavior of the grass cover of the river bed in general. The properties of grass by samples can be indicators of an effective environmental assessment of any river bed landscape and topography on which meadow grass grows.

Claims (9)

1. A method of testing grass cover in a near-river meadow, including measuring the length of tributaries and the catchment area of river tributaries, as well as the fall of tributaries as the height difference between their sources and estuaries, distributing the tributaries by distinctive groups according to the presence of vegetation in the catchment areas of the river catchment and its tributaries , an assessment of the influence of the distinctive orographic features of the relief and landscape located on the territory of the catchment of tributaries, characterized in that on the measured along the length and area of the catchment of a small river or its tributary, either on a map or in situ, highlight a section of a channel in a river valley with a non-flood or floodplain meadow, and on the coastal part of this valley a land plot in the form of a biogeocenosis with the definition of the boundaries of the test grass cover is defined, then on this land plot of a river-bed meadow, mark with the flow of water perpendicular to the channel, there are many temporary hydrometric gauges with a measurement of the distances between them, and the lines of the gauges extend to the border of the grass cover across the channel, and the number of temporary hydrom etric sections are taken to be sufficient for the formation of a network of test sites throughout the test grass cover, with many test sites with variable distances between them being marked along each temporary hydrometric gauge, then grass samples are cut off and subjected to tests from each test site, after testing grass samples the distance from the water line taken as the origin at all temporary hydrometric gauges to the centers of test sites cleared of grass samples, when the height difference of the test sites is more than 10.0 cm, the height of the center of each test site from the water surface of the river or its tributary is also measured, then the length and fall of the river or its tributary in the selected section of the channel are measured, and a common constant geodetic reference point for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of the grass cover. 2. The method of testing grass cover in the near-river meadow according to claim 1, characterized in that the land plot of the entire non-flood or floodplain meadow with the tested ecosystem grass cover before the haying is carried out visually on a map or in-situ on especially unprotected areas of river valleys, and the size of the trial sites take 0.50 x 0.50 m. 3. The method of testing grass cover in a near-river meadow according to claim 1, characterized in that bends and other forms of channel formation of a small river or its tributary are taken as natural characteristic places along the course of a small river or its tributary, moreover, tests of grass cover are primarily carried out on in specially protected areas, and then, taking into account the revealed patterns of spatial changes in the properties of grass samples, testing is continued in river meadows with an increasing anthropogenic load on biogeocenoses. 4. A method for testing grass cover in a near-river meadow according to claim 1, characterized in that at least three temporary hydrometric gauges in the transverse direction to the far boundary of the near-river meadow with distances between them along the course of a small river or its tributary are marked out on small-sized grass biogeocenoses not less than 5.0 m and not more than 50.0 m, and the test sites are located at intervals between them of not less than 2.00 m between themselves and not more than 20.0 m, and the numbering of temporary hydrometric sections is carried out with the flow of water from the beginning g the borders of the test grass cover. 5. The method of testing grass cover in the near-river meadow according to claim 1, characterized in that at least three test sites are marked out on a small area of grass along each hydrometric gauge, and the numbering of test sites measuring 0.50 × 0.50 m is carried out from channel to the far border of the test grass cover. 6. The method of testing grass cover in a river near-river meadow according to claim 1, characterized in that after taking all grass samples along each temporary hydrometric gauge, a reference test site with the highest or lowest height is selected compared to other test sites, and relatively selected at all temporary hydrometric gauges of reference test sites conduct their geodetic survey relative to a predetermined common permanent geodetic reference point for long-term measurements of the river bed eleph and landscape. 7. The method of testing grass cover in a near-river meadow according to claim 1, characterized in that the height of the center of each test site from the water surface in a given section of a small river or its tributary is measured using geodetic instruments with an accuracy of one centimeter, moreover, this parameter is measured The relief in other seasons of the year is performed by constant geodetic reference points. 8. The method of testing grass cover in the near-river meadow according to claim 1, characterized in that according to the results of tests of grass samples, patterns of the influence of the distance along each temporary hydrometric gauge, as well as the influence of the height of the test sites above the water edge, on the biophysical and biochemical parameters of the samples are revealed grasses throughout the network of test sites, and also assess the impact of the distinctive orographic features of the river channel or its tributary, coastal relief and located inside and outside the test area natural grass cover of natural and man-made objects. 9. The method of testing grass cover in a riverbed meadow according to claim 1, characterized in that, after taking grass samples, measuring the length and fall of the river or its tributary in a selected section of the channel, as well as establishing a common permanent geodetic reference point for further long-term measurements of the riverbed topography and landscape and annual monitoring of the properties of grass cover is performed during the summer low-water period of the river and its tributary.

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