RU2388213C1 - Method for measurement of grass cover crop yield - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of agriculture and forestry. In method fluctuations of crop yield are accounted depending on structure of phytocenosis in the form of grass cover, required accuracy of crop yield measurements is specified based on tests of grass on sample sites. Grass samples testing data is statistically processed from sample sites at near-bed, central and near-terrace flood plains and also in meadows with uneven and mosaic arrangement of grass types in each phytocenosis as components of grass cover. Prior to planting of sample sites, without measurement of distances between them, area is reconnoitered with grass cover selected for measurements, schematic map or topographic map is made to locate components of grass cover by results of geodesic measurements and photographs taking. Afterwards at each component of grass cover at least one temporary sample site is arranged, in cut sample of grass, raw and air-dry mass of sample is determined by weighing, and crop yield by group of components and grass cover as a whole is calculated as values of average weighted value from crop yields of grass samples.

EFFECT: invention makes it possible to improve accuracy and to reduce labour intensiveness of measurements by results of testing grass samples cut from sample sites on the territory of complex multi-component grass cover.

8 cl, 9 dwg, 3 tbl, 1 ex

Description

The invention relates to grass coverings of various types and sizes. It can be used in biotechnological and biochemical assessment of a separate component of the grass cover and in general in non-flood and floodplain meadows of small rivers and lakes, upland and mountain meadows, hayfields and pastures, meadows in glades and forest edges.

There is a method of measuring the productivity of grass cover by the phytomass of separately aboveground and underground parts of the grass cover [Soils and primary biological productivity of floodplains of the rivers of Central Russia / I.T. Kuzmenko, M.P. Pavlova, R.T. Bogomolova, A.N. Tyurukanov, L.A. Shkurenkov. - M .: Nauka, 1977. - 152 p., P.106], which includes taking phytomass once during the growing season during the mass flowering of meadow plants (late June – early July), when the herbage reaches its highest development. Measurement of pasture productivity was carried out at the same time in undetected areas. In areas with complex grass stands, productivity was taken into account separately for each component of the complex. To account for the aboveground phytomass of meadows, test sites of 1.0 × 0.5 m in size were laid in 9-fold repetition, which were located on the area of the meadow at the same, predetermined distance from each other. The distance between sites for each site was selected in accordance with its size, which made it possible to obtain data characterizing the plant community in the area occupied by it. At each accounting site, grass was cut with sheep's scissors at the soil level, weighed first in a wet, then in an air-dry state, after which the average productivity of the meadow was calculated.

The disadvantage of this method is the high complexity due to the need for a nine-fold repetition of grass samples from one grass cover. The complexity increases due to the need for marking the same predetermined distances between the test sites. This increases the measurement errors due to errors and discrepancies of these distances to the actual size of the grass cover. But the most important disadvantages are:

a) in areas with complex grass stands, productivity was taken into account separately for each component of the complex, therefore, on each component of a complex grass cover, it is required to lay test sites of 9-fold repetition;

b) the characteristic of a simple grass cover by the average yield of grass at nine test sites, and a complex plant complex by the average yield of grass from all components of the plant community, refers to the law of normal distribution, but the plant cover does not obey the Gauss-Laplace law known in the art.

As a result, it turns out that for a complex complex, for example, with five components by analogy, 9 × 5 = 45 test plots are required, the role of which is reduced only to the arithmetic average productivity of the entire complex and, at best, to five arithmetic average productivity values in five parts by area of grass cover .

There is also a method of measuring the productivity of grass cover [Soils and primary biological productivity of floodplains of the rivers of Central Russia / I.T. Kuzmenko, M.P. Pavlova, R.T. Bogomolova, A.N. Tyuryukanov, L.A. Shkurenkov. - M .: Nauka, 1977. - 152 p., Pp. 106-107], which includes taking into account fluctuations depending on the structure of the phytocenosis in the form of grass cover, when the required number of repeated measurements varies greatly both for individual phytocenoses and for years of measurements in the same areas. At the same time, for meadows located in the near-river and central floodplains, the number of required repeated measurements with the required accuracy of 15% varied from 1 to 6, and for meadows located in the near-floodplain, from 1 to 10, which is explained by a less uniform distribution of species in the grass terraced meadows. With the required accuracy of 10%, the number of repeated measurements increases from 2 to 14 for meadows of the riverbed and central floodplains and from 3 to 22 for meadows of the near-floodplain. In general, the data of statistical processing showed that the 9-fold repetition accepted for the study was sufficient on average to obtain data with an accuracy of 15%. However, to obtain more accurate data, it is advisable to increase the number of test sites in meadows located in the terraces, as well as in meadows with uneven, mosaic distribution of grass species in the phytocenosis.

The disadvantage of the prototype is the explicit averaging of not only the values of the yield indicator, but even the number of necessary repetitions on the test sites. Arithmetic tricks allow you to use an analog instead of a prototype. Otherwise, the laboriousness of measurements increases sharply, and at the same time, low accuracy in estimating grass yields or meadow soil productivity over the aerial part of the grass cover is again achieved due to calculation of arithmetic mean values, therefore, the authors of this method considered it possible to choose an analogue instead of the prototype, since even when taking grass samples up to 22 pieces for the meadows of the terraced floodplain of the river the result is the same - according to the arithmetic mean value of grass yields in wet and air-dry state in the form of hay .

EFFECT: increased accuracy and reduced laboriousness of measurements according to the results of testing grass samples cut from test sites on the territory of a complex grass cover multicomponent by types of grass.

This technical result is achieved in that a method for measuring the productivity of grass cover, including accounting for yield fluctuations depending on the structure of the phytocenosis in the form of grass cover, establishing the required accuracy of yield measurements from grass tests at test sites, conducting statistical processing of test data from grass samples from test sites to near-river, central and near floodplains, as well as in meadows with uneven and mosaic distribution of grass species in each phytocenosis as components of a distinct cover, characterized in that prior to laying the test sites without measuring the distances between them, reconnaissance of the terrain with the grass cover selected for measurements is carried out, a map or topographic map of the location of the components of the grass cover is made according to the results of geodetic measurements and photographs, after which on each component of the grass at least one temporary test site is laid, the wet and air-dry mass of the sample is determined by weighing the cut grass sample, and the yield is determined by groups of components and, as a whole, over grass cover are calculated as the values of the weighted average value from the yields of grass samples.

Moreover, a schematic map is made, and a topographic map is specified, annually with changes in the relief and landscape of the studied grass cover.

A map or topographic map of the location of the components of the grass cover is made with marks of characteristic places of relief and landscape, moreover, characteristic places are taken as lakes and swamps, ponds and ponds, streams and watercourses, the bottom of dried up streams and ravines, the edges of the banks of hollows and valleys, the borders of groves and forest stands and other natural and natural-anthropogenic objects, as well as anthropogenic objects for geodetic measurements.

For separate groups of components of the grass cover are land plots of grass cover for individual phytocenoses, as well as located near natural, natural-anthropogenic and anthropogenic objects.

Productivity by groups of components and generally by compact grass cover is calculated as the values of the weighted average of the yields of grass samples according to the equations:

- specific gravity of samples on wet grass, g / m ²

;

;

- specific gravity of samples on air-dry grass (hay), g / m ²

;

;

- the productivity of the meadow or its plot by the wet weight of grass samples, kg / ha

;

;

- meadow productivity by air-dry mass of grass samples, kg / ha

;

;

- mass of raw aerial parts of grass, tons

;

;

- mass of dry grass or hay, tons

;

;

- средневзвешенная по площади компонент травяного покрова удельная масса проб сырой травы по всем временным пробным площадкам, г/м²;Where

- weighted average area component of the grass cover, the specific gravity of samples of raw grass for all temporary test sites, g / m ² ;

i is the number in the order of the test site of a given size or the number of the component in a compact grass cover;

n is the number of test sites or components of a compact grass cover, provided that one sample is taken from the component;

m _i is the specific gravity of the i-th grass sample on the component, weighed immediately after cutting at a temporary test site, g / m ² ;

S _i - the area of the i-th component of the grass cover, from which one sample of grass was taken with the laying of one temporary site, m ² ;

- удельная средневзвешенная по площади компонент травяного покрова масса проб высушенной травы по всем временным пробным площадкам травяного покрова или группы площадок, сгруппированных по характерным местам рельефа или ландшафта, г/м²;

- specific weighted average area component of the grass cover for the samples of dried grass over all temporary test sites of the grass cover or group of sites grouped by characteristic places of relief or landscape, g / m ² ;

- удельная воздушно-сухая масса i-ой пробы травы, высушенной в условиях естественной сушки после срезания на временной пробной площадке, г/м²;

- specific air-dry mass of the i-th sample of grass, dried under natural drying after cutting at a temporary test site, g / m ² ;

- средневзвешенная урожайность травы луга или его компонентного участка по сырой массе, ц/га;

- weighted average yield of grass of the meadow or its component plot in terms of wet weight, kg / ha;

- средневзвешенная урожайность луга или его компонентного участка по воздушно-сухой массе сена, ц/га;

- weighted average productivity of the meadow or its component plot by air-dry mass of hay, kg / ha;

M - the total mass of the aerial parts of the grass cover or a group of its components in the wet state, tons;

M _c - total mass of the aerial part of the grass cover or a group of its components in the air-dry state after drying, tons.

For meadows located in the riverbed and central floodplains of a small river or its tributary, the number of necessary temporary test plots is determined after marking the grass cover according to hydrometric gauges and the distances from the river edge or its tributary to the centers of the test plots, while the grass cover components are taken as one group part or all of the temporary test sites on this temporary gauge gauge, the origin of coordinates on all gauge gauges from the water mirror is set approximately in the summer low water approximately and the same distance, for example 40-50 meters or more with an accuracy of 0.1 m.

And for meadows located in the near-river floodplain, the height of the center of each test site from the surface of the water is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this parameter of the relief in other seasons of the year are performed using constant reference marks.

When measuring grass cover annually and several times during the growing season, grass samples are taken at temporary test sites laid without measuring the distance between them at some distance from past temporary test sites.

The essence of the invention lies in the fact that it is proposed first to abandon the Gauss-Laplace law of the distribution of productivity by simple and complex by species components in the territory of the studied grass cover. Therefore, it is calculated not the arithmetic average value of the yield even within the components of the herbaceous phytocenosis, but the weighted average over the area of influence of each trial site on the characteristics of the component, as well as the weighted average value of the yield for a complex grass cover according to the "weight coefficients" equal to the area of grass cover occupied by each component of the phytocenosis.

The essence of the invention lies in the fact that for small values of the area of the components in a compact grassy phytocenosis (now it is difficult to find large meadows due to their fragmentation by human activity and the variability of soil and climatic conditions of growth) in the territory of each component in an arbitrary place and without measurement only one test site with the dimensions 0.50 × 0.50, 0.50 × 1.00 or 1.00 × 1.00 m is laid (the decimal point indicates the required measurement accuracy of one centimeter).

The essence also lies in the fact that the relief parameters in the form of distances from the lines of watersheds or other characteristic places (lakes and swamps, streams and watercourses, the bottom of dried out streams and ravines, the edges of the banks of groves and valleys, the boundaries of groves and stands, etc.) of this territory. At the same time, at least one test site is laid on each land plot, uniform in relief and landscape, occupied by meadow grass, and if the number of test plots is more than one from one land and land, uniform in landscape and landscape, meadow grass arithmetic mean value is calculated on this land.

The positive effect is that in measurements of the productivity of grass cover, the structure of the relief and landscape throughout the entire territory of the grass cover with one or more phytocenoses is taken into account. Moreover, in the future it becomes possible to measure a complex vegetation combining meadow and steppe grass, bushes and shrubs, individual trees or tree communities in the form of a grove, garden, forest area.

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 invention have not been found.

The method for measuring the productivity of the aerial part of the grass on the grass cover on test sites with sizes of 1.00 × 1.00, 1.00 × 0.50 or 0.50 × 0.50 m includes such actions.

First, the terrain and grass cover in the given meadow are visually examined and the locations of the components of individual phytocenoses are noted.

Prior to laying temporary test sites without measuring the distances between them, reconnaissance of the terrain with the grass cover selected for measurements is carried out, a map-diagram or topographic map of the location of the components of the grass cover is made according to the results of geodetic measurements and photographs. After that, at least one temporary test site is laid on each component of the grass cover. Then, by weighing the cut grass sample, the wet and air-dry mass of the sample is determined by weighing, and the yield by groups of components and the grass cover as a whole is calculated as the values of the weighted average of the yield of grass samples.

Moreover, a schematic map is made, and a topographic map is updated annually with changes in the relief and landscape of the studied grass cover.

A map or topographic map of the location of the components of the grass cover is made with marks of characteristic places of relief and landscape, moreover, characteristic places are taken as lakes and swamps, ponds and ponds, streams and watercourses, the bottom of dried up streams and ravines, the edges of the banks of hollows and valleys, the borders of groves and forest stands and other natural and natural-anthropogenic objects, as well as anthropogenic objects for geodetic measurements.

For separate groups of components of the grass cover are land plots of grass cover for individual phytocenoses, as well as located near natural, natural-anthropogenic and anthropogenic objects.

Productivity by groups of components and generally by compact grass cover is calculated as the values of the weighted average of the yields of grass samples according to the equations:

- specific gravity of samples on wet grass, g / m ²

;

;

- specific gravity of samples on air-dry grass (hay), g / m ²

;

;

- the productivity of the meadow or its plot by the wet weight of grass samples, kg / ha

;

;

- meadow productivity by air-dry mass of grass samples, kg / ha

;

;

- mass of raw aerial parts of grass, tons

;

;

- mass of dry grass or hay, tons

;

;

- средневзвешенная по площади компонент травяного покрова удельная масса проб сырой травы по всем временным пробным площадкам, г/м²;Where

- weighted average area component of the grass cover, specific gravity of raw grass samples for all temporary test sites, g / m ² ;

i is the number in the order of the test site of a given size or the number of the component in a compact grass cover;

n is the number of test sites or components of a compact grass cover, provided that one sample is taken from the component;

m _i is the specific gravity of the i-th grass sample on the component, weighed immediately after cutting at a temporary test site, g / m ² ;

S _i - the area of the i-th component of the grass cover, from which one sample of grass was taken with the laying of one temporary site, m ² ;

- удельная средневзвешенная по площади компонент травяного покрова масса проб высушенной травы по всем временным пробным площадкам травяного покрова или группы площадок, сгруппированных по характерным местам рельефа или ландшафта, г/м²;

- specific weighted average area component of the grass cover for the samples of dried grass over all temporary test sites of the grass cover or group of sites grouped by characteristic places of relief or landscape, g / m ² ;

m _ci — specific air-dry mass of the i-th sample of grass dried under natural drying after cutting at a temporary test site, g / m ² ;

- средневзвешенная урожайность травы луга или его компонентного участка по сырой массе, ц/га;

- weighted average yield of grass of the meadow or its component plot in terms of wet weight, kg / ha;

- средневзвешенная урожайность луга или его компонентного участка по воздушно-сухой массе сена, ц/га;

- weighted average productivity of the meadow or its component plot by air-dry mass of hay, kg / ha;

M - the total mass of the aerial parts of the grass cover or a group of its components in the wet state, tons;

M _c - total mass of the aerial part of the grass cover or a group of its components in the air-dry state after drying, tons.

For meadows located in the riverbed and central floodplains of a small river or its tributary, the number of necessary temporary test plots is determined after marking the grass cover according to hydrometric gauges and the distances from the river edge or its tributary to the centers of the test plots, while the grass cover components are taken as one group part or all of the temporary test sites on this temporary gauge gauge, the origin of coordinates on all gauge gauges from the water mirror is set approximately in the summer low water approximately and the same distance, for example 40-50 meters or more with an accuracy of 0.1 m.

And for meadows located in the near-river floodplain, the height of the center of each test site from the surface of the water is measured using geodetic instruments with an accuracy of one centimeter, and measurements of this parameter of the relief in other seasons of the year are performed using constant reference marks.

When conducting measurements of grass cover annually and several times during the growing season, sampling of grass is carried out at temporary test sites laid without measuring the distance between them at some distance from past temporary test sites.

The method for measuring the yield of grass cover on the riverbed floodplain of a small river from test sites measuring 1.00 x 1.00 m located across the small river within the water protection strip, taking into account the influence of hydraulic structures and the village, includes such actions.

Prior to laying the temporary test sites, reconnaissance of the terrain with the selected grass cover for measurements is carried out, a map is made of the location of the components of the grass cover in the form of territories relative to temporary hydrometric sections and land plots for each section of the small river. After that, one temporary test site is laid on each component of the grass cover. Then, by weighing the cut grass sample, the wet and air-dry mass of the sample is determined by weighing, and the yield from the groups of components located relative to the temporary hydrometric gauge on the left and right parts of the riverbed floodplain, and as a whole from the grass cover within the water protection strip of a small river or its tributary, is calculated as the values of the weighted average of the yields of grass samples.

A map or topographic map of the location of the components of the grass cover is made up with marks of characteristic places of relief and landscape, moreover, dams and their dams, meanders of the river or its tributaries, edges of the river banks, boundaries of the influence of hydraulic structures and bridges, and also anthropogenic objects are taken as characteristic places in the form of hayfields and pastures inside the water-protection strip and a village outside the water protection zone of a small river.

Productivity by groups of components and generally by compact grass cover is calculated as the values of the weighted average of the yields of grass samples according to the equations:

- specific gravity of samples on wet grass, g / m ²

;

;

- specific gravity of samples on air-dry grass (hay), g / m ²

;

;

- the productivity of the meadow or its plot by the wet weight of grass samples, kg / ha

;

;

- meadow productivity by air-dry mass of grass samples, kg / ha

;

;

- mass of raw aerial parts of grass, tons

;

;

- mass of dry grass or hay, tons

;

;

- средневзвешенная по площади компонент травяного покрова удельная масса проб сырой травы по всем временным пробным площадкам, г/м²;Where

- weighted average area component of the grass cover, the specific gravity of samples of raw grass for all temporary test sites, g / m ² ;

i is the number in the order of the test site of a given size or the number of the component in a compact grass cover;

n is the number of test sites or components of a compact grass cover, provided that one sample is taken from the component;

m _i is the specific gravity of the i-th grass sample on the component, weighed immediately after cutting at a temporary test site, g / m ² ;

S _i - the area of the i-th component of the grass cover, from which one sample of grass was taken with the laying of one temporary site, m ² ;

- удельная средневзвешенная по площади компонент травяного покрова масса проб высушенной травы по всем временным пробным площадкам травяного покрова или группы площадок, сгруппированных по характерным местам рельефа или ландшафта, г/м²;

- specific weighted average area component of the grass cover for the samples of dried grass over all temporary test sites of the grass cover or group of sites grouped by characteristic places of relief or landscape, g / m ² ;

m _ci — specific air-dry mass of the i-th sample of grass dried under natural drying after cutting at a temporary test site, g / m ² ;

- средневзвешенная урожайность травы луга или его компонентного участка по сырой массе, ц/га;

- weighted average yield of grass of the meadow or its component plot in terms of wet weight, kg / ha;

- средневзвешенная урожайность луга или его компонентного участка по воздушно-сухой массе сена, ц/га;

- weighted average productivity of the meadow or its component plot by air-dry mass of hay, kg / ha;

M - the total mass of the aerial parts of the grass cover or a group of its components in the wet state, tons;

M _c - total mass of the aerial part of the grass cover or a group of its components in the air-dry state after drying, tons.

For meadows located in the near-river floodplain, the height of the center of each test site from the surface of the water is measured using geodetic instruments with an accuracy of one centimeter. At the same time, the height of the centers of the test sites above the surface of the river is measured with an accuracy of one centimeter.

Example. According to the results of testing grass samples for 18 components of the riverbed grass cover of the small river Irovka, located near the village of Yandemirovo, Paranginsky district of the Mari El Republic, weighted average yields were calculated for the left and right parts of temporary hydrometric gauges, the three hydrometric gauges and three grass strips along the river.

The test results for all 18 samples and a quantitative assessment of the productivity of grass cover within the water protection strip with a width of about 200 m and a length of more than 800 m are given in Table 1. At the same time, on the map and visual inspection, at first, the boundaries of the elementary sections of the grass cover were determined, having a homogeneous species composition of grass and grass plants, as well as the approximate anthropogenic impact on the bend of the river in the middle of the studied section of the small river Irovka, dams along the village, dam dam below the village, the road bridge in the middle of the village, the left-bank hay section, the right-bank section, which was a pasture about 15 years ago, and also the dirt road from the beginning, sulfur dyne and to the end of the village.

Table 1 Summary of 18 test sites of three small river sections Trial No.
i Height from water edge H, m Distance Alignment
L m Alignment rank, r Area Components
S
× 10 ⁴ m ² Grass sample weight, g / m ² The humidity of the grass W,% The average dehydration rate v, g / (m ² h) raw grass m dry hay m _c , moisture in the grass m _b0 one 2.00 10 0 1.260 880 248.2 624.5 251.6 1.870 2 1.85 twenty 0 0.420 580 174.7 403.9 231.2 0.889 3 1.68 thirty 0 0.630 420 149.5 273.8 183.1 1.037 four 1.65 57 0 0.630 475 138.0 338.5 245.3 1.282 5 1.85 67 0 0.420 600 179.9 416.8 231.7 1.579 6 2.00 77 0 1.680 440 125.6 318.4 253.5 1.206 7 1.10 0 one 0.425 340 105.7 232.0 219.6 0.879 8 1.07 10 one 0.170 390 111.3 277.0 248.8 1.049 9 1.03 twenty one 0.425 780 192.2 577.1 297.1 1.270 10 1.15 58 one 0.510 630 155.3 478.3 308.0 1.812 eleven 1.32 68 one 0.170 490 125.4 365.6 291.5 1.385 12 1.50 78 one 0.680 315 91.0 225.2 247.5 0.853 13 1.20 10 2 0.805 565 186.2 378.5 203.2 1.434 fourteen 1.14 twenty 2 0.230 460 123.7 335.1 270.8 1.269 fifteen 1.07 thirty 2 0.345 380 119.8 260.6 217.5 1.816 16 1.30 53 2 0.460 595 150.4 437.8 291.1 1.658 17 1.60 63 2 0.230 415 114.7 307.1 267.7 1.163 eighteen 1.90 73 2 1.380 430 126.3 305.9 242.3 1.159

Note. According to the dry hay, values calculated by the dynamics of drying are accepted. The calculation results are given in table.2.

table 2 Productivity of the grass cover of the left and right parts of three sections of a small river Trial No.
i The area of the component S, × 10 ⁴ m ² Specific gravity, g / m ² Productivity, t / ha Mass of grass, t raw grass m dry hay
m _c raw grass q dry hay q _c raw grass M dry hay M _c The first hydrometric target to the village of Yandemirovo The left-bank side of the river bed floodplain of the Irovka River one 1.260 880 248.2 88.0 24.82 11.09 3.13 2 0.420 580 174.7 58.0 17.47 2.44 0.73 3 0.630 420 149.5 42.0 14.95 2.65 0.94 Amount 2.310 - - - - 16.17 4.80 Weighted average 700.0 207.8 70.0 20.78 - - The right-bank side of the river bed floodplain of the Irovka River four 0.630 475 138.0 47.5 13.80 2.99 0.87 5 0.420 600 179.9 60.0 17.99 2.52 0.76 6 1.680 440 125.6 44.0 12.56 7.39 2.11 Amount 2.730 - - - - 12.90 3.74 Weighted average 472.5 137.0 47.25 13.70 - -

Continuation of Table 2 The second hydrometric target near the bend and in the village of Yandemirovo The left-bank side of the river bed floodplain of the Irovka River 7 0.425 340 105.7 34.0 10.57 1.45 0.45 8 0.170 390 111.3 39.0 11.13 0.66 0.19 9 0.425 780 192.2 78.0 19.22 3.32 0.82 Amount 1.020 - - - - 5.42 1.46 Weighted average 531.4 143.1 53.14 14.31 - - The right-bank side of the river bed floodplain of the Irovka River 10 0.510 630 155.3 63.0 15.53 3.21 0.79 eleven 0.170 490 125.4 49.0 12.54 0.83 0.21 12 0.680 315 91.0 31.5 9.10 2.14 0.62 Amount 1.360 - - - - 6.19 1.62 Weighted average 455.1 119.1 45.51 11.91 - - The third hydrometric target after the dam at the end of the village of Yandemirovo 13 0.805 565 186.2 56.5 18.62 4.55 1.50 fourteen 0.230 460 123.7 46.0 12.37 1.06 0.28 fifteen 0.345 380 119.8 38.0 11.98 1.31 0.41 Amount 1.380 - - - - 6.92 2.20 Weighted average 501.4 159.4 50.14 15.94 - - The right-bank side of the river bed floodplain of the Irovka River 16 0.460 595 150.4 59.5 04/15 2.74 0.69 17 0.230 415 114.7 41.5 11.47 0.95 0.26 eighteen 1.380 430 126.3 43.0 12.63 5.93 1.74 Amount 2.070 - - - - 9.63 2.70 Weighted average 465.2 130.4 46.52 04/13 - - Amount 10.870 - - - - 57.23 16.51 Average total, t / ha 526.5 151.9 52.65 15.19 5.265 1.519

Table 2 shows the calculation data for the components of the grass cover in the form of the left and right parts of temporary hydrometric sections, in each of which there were three test sites.

The components of the grass cover of the near-river floodplain of the small river Irovka were obtained in Table 2 when grouping temporary test sites in the transverse direction to the water flow. However, a different system of components can be obtained by grouping along the river.

The near-river floodplain was divided into three grass strips along the river along its course: left-bank, riverine (central with the inclusion of a watercourse) and right-bank. Each of these three grass strips receives, due to its own features of the relief, landscape, and the influence of anthropogenic objects, the characteristic values of property indicators in parts of the grass cover. These key indicators were listed in Table 1. The results of the calculations according to the above formulas are shown in table 3.

On the right bank of the small river Irovka from the side of the village, the yield along the grass strip is almost one and a half times less compared to the left-bank grass strip. At the same time, the scatter of yield values across the river is much higher compared to the longitudinal distribution of grass cover.

Table 3 Yield of grass cover along three grass lanes along a small river Trial No.
i The area of the component S, × 10 ⁴ m ² Specific gravity, g / m Productivity, t / ha Mass of grass, t raw grass m dry hay
m _c raw grass q dry hay
q _c raw grass M dry hay M _c Left Bank Grass Strip one 1.260 880 248.2 88.0 24.82 11.09 3.13 2 0.420 580 174.7 58.0 17.47 2.44 0.73 7 0.425 340 105.7 34.0 10.57 1.45 0.45 8 0.170 390 111.3 39.0 11.13 0.66 0.19 13 0.805 565 186.2 56.5 18.62 4.55 1.50 fourteen 0.230 460 123.7 46.0 12.37 1.06 0.28 Amount 3.310 - - - - 21.25 6.28 Weighted average 642.0 189.7 64.20 18.97 - - Central (riverine) grass strip 3 0.630 420 149.5 42.0 14.95 2.65 0.94 four 0.630 475 138.0 47.5 13.80 2.99 0.87 9 0.425 780 192.2 78.0 19.22 3.32 0.82 10 0.510 630 155.3 63.0 15.53 3.21 0.79 fifteen 0.345 380 119.8 38.0 11.98 1.31 0.41 16 0.460 595 150.4 59.5 04/15 2.74 0.69 Amount 3,000 - - - - 16.22 4.52 Weighted average 540.7 150.7 54.07 07/15 - - Right Bank Grass Strip 5 0.420 600 179.9 60.0 17.99 2.52 0.76 6 1.680 440 125.6 44.0 12.56 7.39 2.11 eleven 0.170 490 125.4 49.0 12.54 0.83 0.21 12 0.680 315 91.0 31.5 9.10 2.14 0.62 17 0.230 415 114.7 41.5 11.47 0.95 0.26 eighteen 1.380 430 126.3 43.0 12.63 5.93 1.74 Amount 4.560 - - - - 19.76 5.70 Weighted average 433.3 125.0 43.33 12.50 - - Amount 10.870 - - - - 57.23 16.51 Average total, t / ha 526.5 151.9 52.65 15.19 5.265 1.519

The proposed method is simple in practical implementation and 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 floodplain meadow as a whole, many biotechnical and biochemical phenomena and processes. The properties of herbs by samples can be indicators of an effective environmental assessment of any river landscape and coastal topography on which grass grows.

Claims (8)

1. A method of measuring the yield of grass cover, including taking into account yield fluctuations depending on the structure of the phytocenosis in the form of grass cover, establishing the required accuracy of yield measurements by testing grass at test sites, conducting statistical processing of test data from grass samples from test sites on river, central and terraces floodplains, as well as in meadows with uneven and mosaic distribution of grass species in each phytocenosis as components of grass cover, characterized in that before laying test sites without measuring the distances between them carry out a reconnaissance of the terrain with the selected grass cover for measurements, draw up a map or topographic map of the location of the components of the grass cover according to the results of geodetic measurements and photographs, after which at least one temporary test site is laid on each component of the grass cover , by cutting the grass sample by weighing, determine the wet and air-dry mass of the sample, and the yield by component groups and grass cover in general count value is calculated as a weighted average of herbal samples on productivity. 2. The method of measuring the productivity of grass cover according to claim 1, characterized in that a map is compiled and the topographic map is updated annually with changes in the relief and landscape of the studied grass cover. 3. The method of measuring the productivity of grass cover according to claim 1, characterized in that the map or topographic map of the location of the components of the grass cover is made with marks of characteristic places of relief and landscape, moreover, lakes and swamps, ponds and ponds, streams and watercourses, the bottom of dried-up streams and ravines, the edges of the banks of hollows and valleys, the boundaries of groves and stands, and other natural and natural-anthropogenic objects, as well as anthropogenic objects for geodetic measurements. 4. The method of measuring the productivity of grass cover according to claim 3, characterized in that for separate groups of components of the grass cover take land plots of grass cover for individual phytocenoses, as well as located near natural, natural and man-made and anthropogenic objects. 5. The method of measuring the yield of grass cover according to claim 1, characterized in that the yield by groups of components and in general by compact grass cover is calculated as the values of the weighted average of the yields of grass samples according to the equations:
specific gravity of samples on wet grass, g / m ²

;
specific gravity of samples on air-dry grass (hay), g / m ²

;
productivity of the meadow or its plot according to the wet weight of grass samples, kg / ha

;
meadow productivity by air-dry mass of grass samples, kg / ha

;
mass of raw aerial parts of grass, t

;
mass of dry grass or finished hay, t

,
Where

- weighted average area component of the grass cover, specific gravity of raw grass samples for all temporary test sites, g / m ² ;
i is the number in the order of the test site of a given size or the number of the component in a compact grass cover;
n is the number of test sites or components of a compact grass cover, provided that one sample is taken from the component;
m _i - specific gravity of the i-th grass sample on the component, weighed immediately after cutting at a temporary test site, g / m ² ;
S _i - the area of the i-th component of the grass cover, from which one grass sample was taken with the laying of one temporary site, m ² ;

- specific weighted average area component of the grass cover for the samples of dried grass over all temporary test sites of the grass cover or group of sites grouped by characteristic places of relief or landscape, g / m ² ;

- specific air-dry mass of the i-th sample of grass, dried under natural drying after cutting at a temporary test site, g / m ² ;

- weighted average yield of grass of the meadow or its component plot in terms of wet weight, kg / ha;

- weighted average productivity of the meadow or its component plot by air-dry mass of hay, kg / ha;
M is the total mass of the aerial part of the grass cover or a group of its components in the wet state, t;
M _c is the total mass of the aerial part of the grass cover or a group of its components in the air-dry state after drying, t. 6. The method for measuring the productivity of grass cover according to claim 1, characterized in that for meadows located in the riverbed and central floodplains of a small river or its tributary, the number of necessary temporary test sites is determined after marking the grass cover by hydrometric gauges and distances from the river’s edge or its inflow to the centers of the test sites, while for one group of components of the grass cover take part or all of the temporary test sites at this temporary hydrometric gauge, the origin at all hydrometric FIR alignments from the water surface about summer low water set at approximately the same distance, for example 40-50 meters or more with an accuracy of 0.1 m. 7. The method for measuring the productivity of grass cover according to claim 6, characterized in that for meadows located in the river bed floodplain, the height of the center of each test site from the water surface is measured using geodetic instruments with an accuracy of one centimeter, moreover, the measurement of this relief parameter in other seasons of the year are performed on constant reference marks. 8. The method of measuring the yield of grass cover according to claim 1, characterized in that when measuring grass cover annually and several times during the growing season, grass samples are taken at temporary test sites laid without measuring the distance between them at some distance from past temporary test sites.

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