RU2428833C2 - Method to lay circular sample area for measurement of forest trees density - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: circular sample area is marked, where trees are counted, trunks of which are in the circular sample area. The centre of the circular sample area is the mother tree of the main race or the circle of its growth location. Radius of the circular sample area is increased depending on height of the central mother tree. Then circular sample sites are marked from the centre, being arranged concentrically at identical distance from the centre with the mother tree along the width of the circles.

EFFECT: method will make it possible to increase accuracy of measurements in selection and laying of the circular sample area.

3 cl, 5 dwg

Description

The invention relates to forest taxation and forest inspection and can be used in the selection and laying of permanent and temporary sample plots, and is also used in environmental engineering, protection of the natural forest environment, environmental arrangement of territories with forest areas, environmental monitoring and environmental protection by taking into account patterns of tree growth in the trial plots, as well as the population distribution of the number of forest trees and their undergrowth from the seeds of the registered mother tree. The method can also be applied in stands with random or partially evenly distributed main species. The condition for applicability of the proposed method is the presence on the forest site of maternal seed trees and their undergrowth of different ages, without biogroups of forest trees clearly expressed along their boundaries in different species.

There is a method with a constant radius of the circular test area (see book: N.P. Anuchin. Forest taxation. Publishing house 5th, add. - M .: Forestry industry, 1982. - S.53-54), for example, 7 m, including drawing a line of sight from a temporary reference point and classifying those forest trees that along the line of sight of the device are on a circular test area centered at a temporary reference point, and trees outside the circular test site are not counted in the group accounting trees, and therefore they are not accepted in density calculations forest stand in this forest area, then the taxator, turning around itself, but not stopping and not ceasing to sight the cane handle, counts on the circular test area all the trees intersected by the lines of sight from the time point of reference to the boundary of the circular test area.

The disadvantages are indicated in the description of the analogue itself (ibid., P. 54, 5 and 6 paragraphs above) and consist in the fact that the constant radius of the circular test area does not allow to expand the practical application of the method. In this case, the implementation of the device in the form of a cane of a taxator is a positive sign. Thus, the main disadvantage is that “In order for the circular test site to more fully characterize the stand, its radius (and therefore the site) is desirable to increase. However, studies have shown that with a radius exceeding 7 m, it is difficult to locate point B on the area bordering the circular platform. ”

There is also a method of measuring the density of the stand by choosing a circular test site (see, for example, the textbook: N.P. Anuchin. Forest taxation. Publishing house 5th, add. - M .: Forestry industry, 1982. - P. 45 -46), including the location of the device in a horizontal position in the hands of a taxator, then they are sighted alternately with the device at the nearest trees, and the trunk of each of the nearest to the reference point is enclosed through the reading on the device in a circular trial area, after measuring one tree, slowly turning in place count those trees If through the device they were in a circular test area, thus, after completing a full circle of rotation in one place, the taxator around itself will lay a circular test site with a certain radius, and with an increase in the diameter of the trees, the radius of the circular test site increases.

The disadvantage of this method is that the radius of the circular test site is completely dependent on the ratio of the parameters of the device itself, which contradicts the physical principle of the inadmissibility of the influence of measuring instruments on the measurement results. Moreover, the circular trial plot contains only one site, which does not allow studying the distribution of trees depending on the distance from the base tree.

EFFECT: increased accuracy of measurements during selection and laying of a circular trial area.

The technical result is achieved by the fact that in the method of laying a circular trial plot for measuring the density of forest trees, a circular trial plot is planned, on which trees whose trunks are in the circular trial plot are counted, while the mother tree of the main species or its circle is taken as the center of the circular trial plot places of growth, while the radius of the circular test area is increased depending on the height of the central mother tree, then ring test sites are marked from the center, which The rye are arranged concentrically at the same distance from the center with the mother tree along the width of the rings.

For the primary stand, the center of the circular trial plot is taken as the trunk of the mother tree, and for the secondary stand, the center of the territory of the place where the mother forest tree grows is taken as the center of the circular trial plot.

The diameter of the central circle around the parent seed tree of the secondary stand and the width of the ring test sites of the primary or secondary stand are taken based on the height of the mother tree according to the following gradation: when the height of the mother tree is between 5.0-14.9 m, the diameter of the central circle and the width of the ring are 5 m; in the range of 15.0-24.9 m take the diameter of the circle and the width of the ring 10 m; for the interval 25.0-34.9 m - respectively 15 m.

According to the results of calculations by statistical modeling, the biotechnological patterns of the influence of mother spruce on the circular trial plot as a whole and on concentrically arranged annular sites are determined by the distribution density formula for all trees, trees of the main species or its undergrowth:

n = n ₁ + n ₂ + n ₃ ,

where n is the density of trees, units / ar;

n ₁ is the distribution density on the central circle, units / ar;

n ₂ - stressful excitation of individuals adjacent to the mother tree due to the influence of its place of growth, units / ar;

n ₃ - vibrational bioenergetic effect of the mother tree on the development and growth of neighboring trees at distances from it to the middle of the rings, pcs / ar;

L is the distance from the center of the circular test area to the middle of the width of the ring test sites along the radius, m;

A - half the amplitude of the wave effect of the mother tree on the distribution of tree density, units / ar;

p - half the period of the wave influence of the mother tree on the distribution of tree density, m;

and ₁ ... a ₁₂ are the parameters of the finished statistical regularity, taking specific values for specific forest conditions.

The essence of the technical solution lies in the fact that seeds from the mother tree scatter in concentric circles and this natural phenomenon is fixed by concentrically arranged annular platforms around a circular platform in the center of which the mother tree is located.

The essence of the method also lies in the fact that the radial distribution of the undergrowth relative to the mother tree occurs with some excitation of abundance and density relative to the central mother tree.

The essence of the method also lies in the fact that over the years there is an overlay (superposition) of seeds, but a new undergrowth will appear exactly where there is a strong bioenergetic effect of the mother tree. At the same time, at this point in the forest territory, there are conditions for the germination of seeds scattered from the mother tree.

The essence of the method also lies in the fact that a new undergrowth appears among other individuals so that young individuals grow mainly in cooperation, that is, they are constantly in symbiotic relationships, and not in competition, with other trees.

The essence of the method also lies in the fact that under natural conditions, the forest environment forms a strong biofield between the mother trees and their undergrowth. Therefore, it is precisely the seed trees that collectively manage the forest stand and, accordingly, the forest with the core in the form of a diffuse system of forest stands, their individual curtains and biogroups. Due to the wind and other distribution of seeds, forest stands are moving along land, exploring new territories and forming new forest open spaces on the continents.

The positive effect is that the VNIILM showed ways to completely eliminate the symbiotic interaction, and therefore forest plantations of spruce cannot serve as an object of study of bioenergetic connections. Rather, on the contrary, after creating a theoretical base on the basis of experiments on natural, for example, spruce forests, the practical possibility of a more complex artificial organization of plantation stands may appear.

The chaos in the biofields of thinning is so great that foresters still do not even begin to study the behavior of young trees during clarification and cleaning of forest crops. Over decades, it becomes clear that one cannot ignore the natural forces of nature and thereby initially sow and plant a very dense population with the expectation that seedlings will destroy each other over time and the strongest individuals will remain. For this millennium, there has been one answer to gardening: without timely thinning, beets, carrots, and others cannot become tall and healthy forest trees.

In the forest, more precisely in its core - a tree stand, in advance, a network of optimally placed maternal individuals controls the germination of precisely those seeds that are at the right time and in the right place in the territory of the entire population, consisting of varietal and trees of different ages as members of the community.

As a result, the principle of energy saving is strictly observed inside the forest stand. There is never anywhere else inside a healthy tree stand of extra “mouths”: everything here has been verified in advance by the cyclic wave excitations of the mother spruce trees and all members of the spruce community are constantly and continuously controlled by them. Therefore, felling even one tree leads to pulsed excitation of the entire population of spruce trees. It is possible that even a man chopping birches between spruce trees leads to a spruce tree dissonance. By analogy with the behavior of wolves in the wild, trees ate, like good and reasonable predators, must graze their birches and always understand their phytopathological state. First of all, this is done by the spruce mother trees to increase the number of undergrowth and timely feed their offspring with rotting products from aged birches.

A significant novelty is that instead of one circular platform, a large circular area with a radius of up to 100 m is used, containing one small circular platform with a center relative to the trunk of the mother seed tree, around which at least 5-7 concentric annular test sites are concentrically located.

In this regard, the technical solution has significant signs of novelty, a positive effect and the prospect of expanding the application of the statistical methodology for measuring forest tree populations in forest curtains and sections in engineering ecology, environmental protection and arrangement of forest landscapes.

From the scientific, technical and patent literature, materials discrediting the novelty of the proposed method were not found.

Figure 1 shows a diagram of a circular area in a forest area of natural origin, when the mother tree is not much different in age from neighboring trees; in Fig.2 - the same in Fig.1, when the mother's old tree left after logging is surrounded by undergrowth after the natural regeneration of the forest; figure 3 shows a graph of the density of distribution of all trees of the spruce tree on a circular trial plot for all annular trial plots (hereinafter, R is the correlation coefficient of the finished statistical model); in Fig.4 - the same in Fig.3 for all trees of spruce; in Fig.5 - the same in Fig.3 for undergrowth ate up to 2 m high.

The method of laying a circular trial plot for measuring the density of forest trees includes such actions.

On the forest allotment, a trial area of a circular shape is planned, for example, according to the prototype.

Then, the mother tree of the main breed or the circle of its place of growth is taken as the center of the circular trial area. In this case, the radius of the circular test area increases depending on the height of the central mother tree. Then, annular test sites are marked from the center, arranged concentrically at the same distance from the center with the mother tree along the width of the rings.

After counting all the trees, as well as the trees of the main species and its undergrowth, the distribution densities of tree groups along the annular trial plots are calculated and, according to the results of calculations, statistical modeling reveals the biotechnical patterns of the influence of the mother spruce on the circular trial plot as a whole and on concentrically located annular plots.

For the primary stand, the center of the circular trial plot is taken as the trunk of the mother tree, and for the secondary stand, the center of the territory of the place where the mother forest tree grows is taken as the center of the circular trial plot.

The diameter of the central circle around the parent seed tree of the secondary stand and the width of the ring test sites of the primary or secondary stand are taken based on the height of the mother tree according to the following gradation: when the height of the mother tree is between 5.0-14.9 m, the diameter of the central circle and the width of the ring are 5 m; in the range of 15.0-24.9 m take the diameter of the circle and the width of the ring 10 m; for the interval 25.0-34.9 m - respectively 15 m.

According to the results of calculations by statistical modeling, biotechnological patterns of the influence of mother spruce on the circular trial plot as a whole and on concentrically arranged annular sites are revealed by the distribution density formula for all trees, trees of the main species or its undergrowth:

n = n ₁ + n ₂ + n ₃ ,

where n is the density of trees, units / ar;

n ₁ is the distribution density on the central circle, units / ar;

n ₂ - stressful excitation of individuals adjacent to the mother tree due to the influence of its place of growth, units / ar;

n ₃ - vibrational bioenergetic effect of the mother tree on the development and growth of neighboring trees at distances from it to the middle of the rings, pcs / ar;

L is the distance from the center of the circular test area to the middle of the width of the ring test sites along the radius, m;

A - half the amplitude of the wave effect of the mother tree on the distribution of tree density, units / ar;

p - half the period of the wave influence of the mother tree on the distribution of tree density, m;

a ₁ ... a ₁₂ - parameters of the finished statistical regularity, taking specific values for specific forest conditions.

The method of laying a circular trial plot for measuring the density of forest trees, for example a complex spruce in a specially protected area of the reserve, as follows.

On the forest stand of a complex spruce, a trial area of a circular shape is planned, for example, according to the prototype. Moreover, the distribution density of trees along the radius of the trial plot is studied in several communities - all the trees are spruce, birch, pine, aspen, etc., then the trees were spruce as the main species in this forest area, separately undergrowth was eaten up to 2 m high on the same ring test sites.

Then, the mother tree of the main breed or the circle of its place of growth is taken as the center of the circular trial area. In this case, the radius of the circular test area increases depending on the height of the central mother tree. Then, annular test sites are marked from the center, arranged concentrically at the same distance from the center with the mother tree along the width of the rings.

After counting all the trees, as well as the trees of the main species and its undergrowth, the distribution densities of tree groups along the annular trial plots are calculated and, according to the results of calculations, statistical modeling reveals the biotechnical patterns of the influence of the mother spruce on the circular trial plot as a whole and on concentrically located annular plots.

For the primary stand, the center of the circular trial plot is taken as the trunk of the mother tree, and for the secondary stand, the center of the territory of the place where the mother forest tree grows is taken as the center of the circular trial plot.

The diameter of the central circle around the parent seed tree of the secondary stand and the width of the ring test sites of the primary or secondary stand are taken based on the height of the mother tree according to the following gradation: when the height of the mother tree is between 5.0-14.9 m, the diameter of the central circle and the width of the ring are 5 m; in the range of 15.0-24.9 m take the diameter of the circle and the width of the ring 10 m; for the interval 25.0-34.9 m - respectively 15 m.

According to the results of calculations by statistical modeling, the biotechnological patterns of the influence of mother spruce on the circular trial plot as a whole and on concentrically arranged annular sites are determined by the distribution density formula for all trees, trees of the main species or its undergrowth:

n = n ₁ + n ₂ + n ₃ ,

where n is the density of trees, units / ar;

n ₁ is the distribution density on the central circle, units / ar;

n ₂ - stressful excitation of individuals adjacent to the mother tree due to the influence of its place of growth, units / ar;

n ₃ - vibrational bioenergetic effect of the mother tree on the development and growth of neighboring trees at distances from it to the middle of the rings, pcs / ar;

L is the distance from the center of the circular test area to the middle of the width of the ring test sites along the radius, m;

A - half the amplitude of the wave effect of the mother tree on the distribution of tree density, units / ar;

p - half the period of the wave influence of the mother tree on

density distribution of trees, m;

a ₁ ... a ₁₂ - parameters of the finished statistical regularity, taking specific values for specific forest conditions.

Example. The measurements were carried out two summers of 2007-2008 in the Mari Chodra National Park on the forest stand of the 8th quarter No. 37. The leader tree in the biogroup of the secondary spruce of natural origin, which is also the mother tree, was taken as the center of the circular trial plot.

In our experiments, the center of the trial circular area was taken to be the mother spruce in the form of a seed tree left after cutting the fir tree. Around the central circle with a diameter of 10 m adopted the layout of the annular test sites with a width of 10 m in one circular test area with a total radius of at least 70 m (figure 2).

During the measurements, the central mother spruce was tied with a rope. The boundaries of the sections along the rings according to the scheme in figure 2 were set using tapes and pegs.

In winter, borders are marked in the snow. Therefore, winter experiments are much more convenient and visibility in the forest is high.

Therefore, it turns out that the selected circular test area with a diameter of at least 80 m is divided into separate ring sites, that is, into test sites that increase in area of the forest site.

The width of the rings and the diameter of the central circle B (Fig. 1) is taken depending on the height of the central spruce tree (Table 1).

Table 1 Parameters of the circular trial plot Central tree height N, m The width of the ring B, m 5.0 ... 14.9 5 15.0 ... 24.9 10 25.0 ... 34.9 fifteen

For example, when the height of the mother spruce is 23 m, we take B = 10 m. Each subsequent circumference of the annular test site will be concentrically located at a distance of 10 m from each other.

Then the value of the area S does not require special measurements and it can be calculated by analytical formulas. They will come from the following series given in Table 2.

table 2 Parameters of circular test plots of circular test plots Site number Primary stand Secondary stand Diameter of the external test site, m The average radius of the annular platform, m The area of the ring test site at B = 10 m, ar (100 m ² ) The increase in circular area at B = 10 m, ar (100 m ² ) Diameter of the external test site, m The average radius of the annular platform, m The area of the ring test site at B = 10 m, ar The increase in circular area at B = 10 m, ar one 1 V - 0.25π 0.25π 2 V - 1π 1π 2 3 v 2 V 2.00π 2.25π 4 V 3 v 3π 4π 3 5 v 4 V 4.00π 6.25π 6 V 5 v 5π 9π four 7 V 6 V 6.00π 12.25π 8 v 7 V 7π 16π 5 9 V 8 B 8.00π 20.25π 10 V 9 V 9π 25π 6 11 V 10 V 10,00π 30.25π 12 v 11 V 11π 36π 7 13 V 12 v 12.00π 42.25π 14 V 13 V 13π 49π 8 15 v 14 V 14,00π 56.25π 16 V 15 v 15π 64π 9 17 V 16 V 16.00π 72.25π 18 v 17 V 17π 81π 10 19 V 18 v 18,00π 90.25π 20 V 19 V 19π 100π

In both schemes, the distance L from the center (the trunk of the mother tree for the primary stand) or from the central circle (the habitat of a large seed tree for the secondary stand) changes equally from zero through the width of the ring, in the example after 10 m.

Calculation of the area of the rings. We accept the following conventions:

N is the number of trees of various species and ages at each annular test site, pcs .;

i is the number of the ring with a width of 5, starting from the central circle with a diameter of 5 (for natural stands) or a radius of 5 (for secondary forests prone to logging in the past) with the central spruce mother tree;

B is the width of the ring, based on half the average height of the leader trees in the forest area or relative to half the height of the mother spruce, m;

S is the area of the annular area, ar (100 m ² );

R is the radius of the middle circle of the annular test site, m

For the most commonly encountered in anthropogenicly modified forests, which is characteristic even of recently organized specially protected areas, the ring contour of the trial plot will receive the following equations for changing the area parameter:

- the area of the first circle according to the scheme in figure 2, showing the placement of the mother spruce of the secondary forest

- for all rings of the trial plot, starting from the first

The width of the ring of the test site B = 10 m was successful. It shows a multiple of the irrational number π, the change in the area of concentric rings as the outer circle moves away from the mother spruce.

Here, the difference between the rings increases through the integer “two”, starting from the central circle with an area of 1π (Table 2), that is, the increase in the area of the circular trial area occurs according to the law of arithmetic progression.

The location of the concentric rings of the forest area on the territory of the circular trial area becomes perfectly ordered. This uniform scale allows you to identify biotechnological patterns of wave changes in stand indicators from the adopted center.

Density of stand. Specific indicators of forest land plots are obtained per unit area of forest stand, and according to our methodology, on a circular test plot for ring test plots.

They will allow you to compare the results of studies on circular and standard rectangular test areas. In addition, the specific parameters of the forest stand are necessary when comparing the productivity of woody plants of various types of forest soils.

Data processing of the measurements of the density of the trees on the ring test sites was carried out according to the following specific indicators:

n is the density of all trees in the forest area, pcs / ar;

n _E - density of placement on trial plots of spruce, units / ar;

- плотность размещения подроста ели, шт./ар.

- the density of the undergrowth of spruce, units / ar.

The elementary density of trees was determined by test sites of a circular shape relative to the central mother spruce, placed on a central circle with a diameter of 10 m.

The density of all trees in the trial plot is sq. 37. The tabular model is given in the data of table.3.

Moreover, we note that the proportion of spruce in the allocation of 8 square meters. 37 is equal to 50% compared with the allocation of 9 per square. thirty.

Table 3 The density of all types of trees, n, pcs./ap Distance from the center Geodesic directions Total FROM AT YU 3 0 0.75 0.75 0.75 0.75 0.95 10 5.5 4.5 7.5 13.5 9.02 twenty 6 6.5 7.5 eighteen 8.72 thirty 7 8 10 18.5 8.91 40 4.5 8 13 eleven 7.11 fifty 6 8 8 fifteen 7.12 60 8 8 eleven eleven 7.44 70 5.5 7 11.5 6.5 5.35 80 3 6 8- 6 3.76 Average 4.7 5.75 7.8 10.1 6.39

Therefore, territorial structuring, i.e. territorial ecological balance (balance), the trees ate here are richer. Therefore, we will immediately search for wave patterns.

Wave disturbance is an obligatory attribute in the behavior of the population of forest trees both in general and for individual species of woody plants in this complex community.

In total, on the rings (Fig. 3), forest trees are distributed from the circle with the mother spruce according to a three-term formula of the form

The density of spruce on the trial plot sq. 37. The initial data are given in table.4.

Table 4 The density of spruce trees n _E , pcs / ar Distance from the center Geodesic directions Total FROM AT YU 3 0 0.75 0.75 0.75 0.75 0.95 10 3 3.5 5 9.5 5.41 twenty 3 4.5 2 11.5 4.77 thirty 2.5 6 6.5 11.5 5.41 40 one 6 5.5 7 4.00 fifty four 7.5 6 11.5 5.47 60 5.5 6.5 9 9 5.53 70 4.5 5.5 8 5.5 4.12 80 1.5 four 5 4.5 2.53 Average 2.65 4.5 4.85 7.15 4.34

The density of spruce trees in the center of the circular area is very low and is only 0.95 pcs / ar, although it has a diameter of 20 m.

At four circular test sites, the maximum density of spruce trees is observed. The weighted average density on a circular trial plot is 4.34 pcs / ar.

Together (Fig. 5), the constant term, excitation, and wave change form a formula of the form

The density distribution of spruce is such that already from the edge of the above-ground crown of the mother spruce there is a maximum of its energetic effect on relatives. Then, along the trend, the impact energy decreases, at first slowly, and then accelerating to the edge of the circular test area.

In the central circle with a radius of 0.5 H, the mother tree itself is located, that is, its trunk and ground crown. Underground crowns of forest trees live in a special way, differing from the behavior of aboveground crowns.

The density of undergrowth ate on the trial plot sq. 37. As can be seen from the data in Table 5, there is a difference in the density of undergrowth of spruce.

Table 5

, шт./арDensity of spruce spruce

, pcs / ar Distance from the center Geodesic directions Total FROM AT YU 3 0 0.5 0.5 0.5 0.5 0.64 10 0 0 3.5 5.5 2.12 twenty one 0 2 11.5 3.25 thirty 0 3.5 6 10 3.55 40 0 3.5 four one 1.27 fifty 0 1.5 2.5 7.5 2.17 60 0 2.5 7.5 6.5 3.04 70 2.5 3.5 5 3.5 2.36 80 one 3 3.5 2.5 1.55 Average 0.55 1.85 3.5 4.9 2.28

Due to the difference in the area of the territory, the density of undergrowth of spruce in the central circle is 100 (0.64-0.50) / 0.50 = 28.0% higher than the central square.

On average, in the radial directions of rectangular test sites in decreasing density of spruce spruce, all cardinal points are ranked according to the following order of preference: west (4.9 pcs / ar), south (3.5 pcs / ar), east (1.85 pcs ./ar) and the north (0.55 pcs / ar).

Together (figure 5) formed biotechnological regularity of the form

,

,

,

,

,

,

,

,

.

.

Asymmetric wavelet signals are remarkable in that they allow you to create a forest inspection method for discrepancies in the actual density distributions, and when calculating by tape tax methods and the number of trees.

The effectiveness of the new method is manifested in the fact that it allows you to apply both the well-known methods of taxation of the stand, and the proposed method for the distribution of trees relative to the central mother tree in the ring test sites. These measurements will be suitable for studying the radial distributions of the number of trees, as well as their density, depending on the distances between the central mother tree and the middle of the ring test sites.

Claims (3)

1. The method of laying a circular trial plot for measuring the density of forest trees, characterized in that they outline a circular trial plot, which counts trees whose trunks are in a circular trial plot, characterized in that the mother tree of the main species is taken as the center of the circular trial plot or the circle of its place of growth, while the radius of the circular test area is increased depending on the height of the central mother tree, then ring test sites are marked from the center, which arranged concentrically at the same distance from the center with the mother tree along the width of the rings. 2. The method of laying a circular test plot for measuring the density of forest trees according to claim 1, characterized in that for the primary stand stand for the center of the circular test plot is the trunk of the mother tree, and for the secondary stand for the center of the circular test plot take the central circle of the territory of the mother tree. 3. The method of laying a circular test area for measuring the density of forest trees according to claim 1, characterized in that the diameter of the central circle around the mother seed tree of the secondary stand and the width of the ring test sites of the primary or secondary stand are taken based on the height of the mother tree according to the following gradation: the height of the mother tree in the range of 5.0-14.9 m take the diameter of the central circle and the ring width of 5 m; in the range of 15.0-24.9 m take the diameter of the circle and the width of the ring 10 m; for the interval 25.0-34.9 m - respectively 15 m.

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