AT17219U1 - Method for the detection of structures of a rodent population on a section of land - Google Patents

Abstract

A method for detecting structures of a rodent population on a terrain section by means of a drone, comprising the steps of moving the drone over the terrain section and capturing a ground image (1) of the terrain section with a ground capturing means of the drone; Determining local minima (2) of a terrain level of the terrain section in the captured soil image (1) with an image processing means and / or a point cloud processing means; and rasterizing the ground image (1) into a plurality of cells (3) and assigning the local minima (2) to the cells (3). The method also comprises categorizing cells (3) which contain more than one threshold value of local minima (2) as a construction cell; and assigning the local minima (2) in those cells (3) that are not categorized as building cells, but are at least adjacent to one building cell, to each building cell to the center of which the respective local minimum (2) has the smallest Euclidean distance.

Description

description

METHOD OF DETECTING BUILDINGS OF A RODENT POPULATION ON A SECTION OF SITE

The invention relates to a method for detecting structures of a rodent population on a section of land by means of a drone.

In nature, rodent populations of different species occur in different areas in different densities and abundances. While some rodent species such as rats or mice are usually considered pests, other rodents such as the ground squirrel or the groundhog are species worthy of protection. This results in the need to determine whether a particular section of the site is home to a rodent population, both in the scientific field and in civil engineering, for example in the field of spatial planning or town planning. In the run-up to or the planning phase of new buildings, it is often necessary to determine the rodent population on a section of the site in order to comply with applicable nature conservation regulations.

[0003] Conventionally, rodent populations are determined on sections of the terrain by manual or partially automated methods. These methods include a manual and time-consuming walk around the area of interest and a visual determination of the entrances to rodent burrows. This process can be supported by tracking tubes or by camera traps, which serve as support for mapping in the event of uncertainties in the determination of the species level. The size of the rodent population is determined from this data (full census) or extrapolated from random samples or partial transect inspections. This method known from the prior art has the disadvantage that it requires a large number of trained personnel and a high expenditure of time. In addition, this method is fraught with a relatively high degree of uncertainty, since the recording of the structures of the rodent population depends heavily on the individual skills and the daily constitution of the person carrying out the work. Furthermore, in the case of impassable terrain, it is not always ensured that all areas of the relevant terrain are easily accessible to people. This further increases the inaccuracy of this method according to the prior art.

The present invention is based on the object of providing a method for detecting structures of a rodent population on a section of land which avoids the disadvantages of the methods according to the prior art.

According to the invention, the object is achieved by a method for detecting structures of a rodent population on a section of terrain by means of a drone, which comprises the following steps:

a) moving the drone over the terrain section and capturing a ground image (1) of the terrain section with a ground capturing means of the drone;

b) determining local minima (2) of a terrain level of the terrain section in the captured soil image (1) with an image processing means and / or a point cloud processing means;

marked by

c) rasterizing the ground image (1) into a plurality of cells (3) and assigning the local minima (2) to the cells (3);

d) categorizing cells (3) which contain more than one threshold value of local minima (2) as a construction cell;

e) Assigning the local minima (2) in those cells (3) that are not categorized as building cells, but are at least adjacent to one building cell, to that building cell in each case from the center of which the respective local minimum (2) has the smallest Euclidean distance .

The inventive method provides for the use of a drone with a ground detection means such as an optical camera or a light detection and range

went, or LiDAR device, which is moved over the section of the terrain. In this case, a floor image is recorded with the floor recording means. The soil image can be captured in the form of a pixel graphic or a point cloud, for example. In a further method step, local minima of a terrain level of the terrain section are determined in the captured soil image with an image processing means and / or a point cloud processing means. The soil image is then rasterized into a plurality of cells, and the determined local minima are assigned to the cells. Cells that contain more than one threshold value of local minima are categorized as building cells in a further step. Finally, local minima in those cells that have not been categorized as building cells, but are at least adjacent to one building cell, are assigned to each building cell from whose center the respective local minimum has the smallest Euclidean distance.

The inventive method enables a quick and uncomplicated detection of the terrain section, as well as the local minima of the terrain level in this section. The use of the drone in combination with the ground detection means has the advantage that even difficult-to-access parts of the terrain or local minima that are not directly visible from the ground level can be detected with the method according to the invention. Furthermore, the evaluation method used in the method according to the invention offers the advantage that the detected local minima are automatically assigned to building cells, whereby an estimation error for a population size is reduced.

According to a preferred embodiment of the method according to the invention, the method comprises the steps:

f) applying a DBSCAN algorithm to the local minima not assigned to any building cell and assigning clusters of local minima determined by means of the DBSCAN algorithm to that cell in which a geometric center of the cluster is located;

g) Categorizing the cell in which the geometric center of the cluster is located as a construction cell.

In order to further reduce the estimation error, according to the preferred embodiment of the method according to the invention, a DBSCAN algorithm, or “Density-Based Spatial Clustering of Applications with Noise” or a density-based spatial cluster analysis with noise is applied to the remaining local minima. This further reduces the estimation error of the method according to the invention. For a detailed description of the method according to the invention using the DBSCAN algorithm, reference is made to the description of the figures.

The ground image is preferably captured by means of the ground capturing means by at least one of a ground radar, an ALS laser scan, or a photographic method. Furthermore, the method according to the invention preferably comprises the acquisition of the ground image by capturing individual images of the terrain section and combining the individual images to form the ground image. To avoid the need for interpolation between the individual images, the individual images are preferably at least partially overlapping.

According to an alternative embodiment variant, the method according to the invention comprises the additional step of checking the local minima determined in the ground image by walking on the terrain section.

Advantageous embodiments of the method according to the invention, as well as alternative design variants are explained in more detail below with reference to the figures.

FIG. 1 shows a floor image captured with the method according to the invention in the form of an ALS laser scan with local minima determined in the floor image.

FIG. 2 shows a floor image rasterized in cells with local minima recorded in the cells.

[0015] FIG. 3 shows a floor image rasterized in cells with a cluster of local minima arranged in different cells.

The inventive method for detecting structures of a rodent population on a terrain section by means of a drone comprises moving the drone over the terrain section and capturing a ground image 1 of the terrain section with a ground detection means of the drone. In a preferred embodiment of the method according to the invention, the drone is provided in the form of a quadrocopter. Alternatively, for example, a drone with a fixed wing configuration or a ground-based drone in the form of a ground vehicle can also be used within the scope of the method according to the invention. The ground detection means of the drone enables the ground image 1 to be captured, the ground image 1 being captured by means of the ground detection means preferably with a ground radar, an ALS laser scan, or a photographic method. The ground radar or the ALS laser scan provides the advantage that vegetation present on the terrain section does not influence the recording of the ground image 1. In a further step of the method according to the invention, local minima 2 of a terrain level of the terrain section in the captured soil image 1 are determined with an image processing means and / or a point cloud processing means. These local minima 2 represent entrances to rodent burrows in the form of holes or depressions in the ground. The image processing means is, for example, an image processing program executed on a computer unit, which uses the structure of brightness gradients in the soil image 1 to determine the local minima 2, which are characteristic of rodent burrows, recognizes. Further methods, which can be used alternatively within the scope of the method according to the invention, for detecting structures in graphic or geometric data are generally known to the person skilled in the art. FIG. 1 shows an example of a ground image 1 of a terrain section captured using the method according to the invention with local minima 2 determined in the ground image 1.

In a further method step of the method according to the invention, the floor image 1, as shown schematically in FIG. 2, is rasterized into a plurality of cells 3, and the local minima 2 are assigned to the cells 3. FIG. 2 shows a diagram of a rasterized floor image 1 with numbered hexagonal cells 3. The choice of hexagonal cells 3 is advantageous since these enable the floor image 1 to be rasterized without gaps. Furthermore, the cells 3 which contain more than one threshold value at local minima 2 are categorized as building cells. If a threshold value of size two is specified, cells number 17 and number 18 in FIG. 2 are categorized as building cells. The threshold value is determined specifically for different rodent species on the basis of biological criteria.

In a further step of the method according to the invention, the local minima 2 in those cells 3 that are not categorized as building cells, but are at least adjacent to one building cell, are assigned to that building cell at the center of which the respective local minimum 2 is the lowest Euclidean distance. In the example shown in FIG. 2, the local minimum 2 in the cell 3 with the number 14, which is adjacent to the building cells 17 and 18, is assigned to the building cell with the number 18. According to an alternative embodiment of the method according to the invention, only local minima 2 in cells 3 that are not categorized as building cells but are at least adjacent to one building cell and which contain a local minimum 2 less than the threshold value are assigned to that building cell in each case. to the center of which the respective local minimum 2 has the smallest Euclidean distance.

According to a preferred embodiment of the method according to the invention, a DBSCAN algorithm is applied to the local minima 2 not assigned to any building cell, and clusters of local minima 2 determined by means of the DBSCAN algorithm are assigned to that cell 3 in which a geometric center of the cluster is located . Furthermore, cell 3, in which the geometric center of the cluster is located, is categorized as a construction cell. This further reduces the estimation error of the method according to the invention.

The DBSCAN algorithm, short for "Density-Based Spatial Clustering of Applications with

Noise ", in German" Density-based spatial cluster analysis with noise "is an algorithm for cluster analysis. The DBSCAN algorithm works on a density basis and is able to recognize several clusters. Noise points are ignored. The basic idea of the algorithm is the notion of density connectedness. Two objects are considered to be densely connected if there is a chain of dense objects, which are core objects with more than a minimum of neighbors, connecting these points together. The objects linked by the same core objects form a cluster. Objects that are not part of a close-knit cluster are known as noise. The DBSCAN algorithm is one of the most cited algorithms in the field of cluster analysis. Details of the DBSCAN algorithm can be found, for example, in the publication “Martin Ester, Hans-Peter Kriegel, Jörg Sander, Xiaowei Xu: A density-based algorithm for discovering clusters in large spatial databases with noise. In: Evangelos Simoudis, Jiawei Han, Usama M. Fayyad (Eds.): Proceedings of the Second International Conference on Knowledge Discovery and Data Mining (KDD-96). AAAI Press, 1996, ISBN 1-577350049, pp. 226-23 “.

The DBSCAN algorithm can be described by the following exemplary pseudocode:

DBSCAN (D, eps, MinPts) C = 0 for each unvisited point P in dataset D mark P as visited N = D.regionQuery (P, eps) if sizeof (N) <MinPts mark P as NOISE else C = next cluster expandCluster (P, N, C, eps, MinPts)

expandCluster (P, N, C, eps, MinPts) add P to cluster C for each point P 'in N if P' is not visited mark P 'as visited N' = D.regionQuery (P ", eps) if siZzeof ( N ')> = MinPts N = N joined with N' if P 'is not yet member of any cluster add P' to cluster C unmark P 'as NOISE if necessary

regionQuery (P, eps) return all points within P's eps-neighborhood (including P)

As is well known to those skilled in the art, the DBSCAN algorithm can alternatively also be implemented recursively:

DBSCAN (D, eps, MinPts) C = 0 for each unvisited point P in dataset D mark P as visited N = getNeighbors (P, eps) if sizeof (N) <MinPts mark P as NOISE else C = next cluster add P to cluster C forP'inN

if P 'is not yet member of any cluster recursivekxpandCluster (P', C, eps, MinPts)

recursivekxpandCluster (P, C, eps, MinPts) add P to cluster C if P is not visited mark P as visited N = getNeighbors (P, eps) if siZzeof (N)> = MinPts for P'inN if P 'is not yet member of any cluster recursivekxpandCluster (P ', C, eps, MinPts)

The use of the DBSCAN algorithm is explained below with reference to FIG. Due to the rasterization, for example with hexagonal cells 3, situations can arise in which local minima 2, as shown in FIG the threshold value at local minima 2 in the individual cells 3 is not exceeded. According to the preferred embodiment of the method according to the invention, the DBSCAN algorithm is used to handle such situations. The cluster of local minima 2 determined by means of the DBSCAN algorithm is then assigned to that cell 3 in which the geometric center of the cluster is located.

The ground image 1 is preferably captured by capturing individual images of the terrain section and combining the individual images to form the ground image 1. To avoid the need for interpolation between the individual images, the individual images are preferably at least partially overlapping.

According to an alternative embodiment, the method according to the invention comprises the additional step of checking the local minima 2 determined in the ground image 1 by walking on the terrain section.

Claims (5)

Expectations 1. A method for detecting structures of a rodent population on a site section by means of a drone, comprising the steps: a) moving the drone over the terrain section and capturing a ground image (1) of the terrain section with a ground capturing means of the drone; b) determining local minima (2) of a terrain level of the terrain section in the captured soil image (1) with an image processing means and / or a point cloud processing means; marked by c) rasterizing the ground image (1) into a plurality of cells (3) and assigning the local minima (2) to the cells (3); d) categorizing cells (3) which contain more than one threshold value of local minima (2) as a construction cell; e) Assigning the local minima (2) in those cells (3) that are not categorized as building cells, but are at least adjacent to one building cell, to that building cell in each case from the center of which the respective local minimum (2) has the smallest Euclidean distance . 2, method according to claim 1, characterized by the steps: f) applying a DBSCAN algorithm to the local minima (2) not assigned to any building cell and assigning clusters of local minima (2) determined by means of the DBSCAN algorithm to that cell (3) in which a geometric center of the cluster is located; g) Categorizing the cell (3) in which the geometric center of the cluster is located as a construction cell. 3. The method according to any one of claims 1 or 2, characterized in that the ground image (1) is captured by means of the ground capturing means by at least one of a ground radar, an ALS laser scan, or a photographic method. 4. The method according to any one of claims 1 to 3, characterized in that the recording of the floor image (1) takes place by recording individual images of the terrain section and combining the individual images to form the floor image (1). 5. The method according to claim 4, characterized in that the individual images are at least partially overlapping. For this purpose 2 sheets of drawings