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Full Paper 273 Using Unmanned Aerial Vehicles (UAV) for Monitoring Biodiversity Measures in Periurban and Agrarian Landscapes Matthias Pietsch 1 , Matthias Henning 2 , David Mader 3 , Patrick Westfeld 3 , Florian Etterer 4 1 Anhalt University of Applied Sciences, Bernburg/Germany · [email protected] 2 Prof. Hellriegel Institute e.V., Bernburg/Germany · [email protected] 3 Institute of Photogrammetry and Remote Sensing, TU Dresden, Dresden/Germany · [email protected] 4 Institute of Landscape Architecture, TU Dresden, Dresden/Germany · [email protected] Abstract: Current farming systems and the land use change are driving forces of biodiversity loss. Based on the Convention on Biological Diversity (CBD) and the Federal Nature Conservation Act in Germany compensation measures are planned and implemented to develop appropriate structures in agrarian landscapes. Therefore a sufficient monitoring is needed. One aim of the project “stadt PARTHE Land” is to use unmanned aerial vehicles (UAV) together with imaging sensors for monitor- ing of compensation measures and the development of indicators. Based on three examples the use of multispectral (true color, near-infrared and thermal infrared) images were tested. Used indicators are vegetation indices for potential habitats, thermal infrared signatures to detect characteristic bird species (e. g. skylark) and the examination of the correct implementation (location, size, restrictions) of com- pensation measures. The results showed that UAV can be used for future applications. Keywords: UAV, biodiversity, monitoring 1 Introduction Land use change and the physical and functional disconnection of ecological networks rep- resent one of the driving forces of biodiversity loss (BUNDESAMT FÜR NATURSCHUTZ 2004, SPANGENBERG 2007). While farming lead to a more varied landscape in the past, intensive agricultural production since the 1950s has contributed to biodiversity decline. Both land- scape structures and plant and animal species that were adapted to extensive farming disap- peared. The Convention on Biological Diversity (CBD) and the National Strategy on Biological Di- versity (NBS) in Germany have the objective to counter this trend by sustainably managing agriculture landscapes. Landscape planning based on the Federal Nature Conservation Act, as one possible instrument in Germany, shapes strategies for sustainable conservation and long-term development of nature and landscapes (BUNDESAMT FÜR NATURSCHUTZ 2002). Mitigation and environmental compensation measures as part of the impact mitigation pro- cedure are required based on nature conservation law at municipal level. The aim is to pre- serve natural potential and functional capacity of ecological services (fauna/flora and their habitats, soils, water, air, climate, scenic quality). In addition the implementation by land owners or land users is very important. Therefore measures are described in detail during the planning procedure and a two-phase monitoring (implementation and functionality) is nec- essary. Journal of Digital Landscape Architecture, 3-2018, pp. 273-282. © Wichmann Verlag, VDE VERLAG GMBH · Berlin · Offenbach. ISBN 978-3-87907-642-0, ISSN 2367-4253, e-ISSN 2511-624X, doi:10.14627/537642029. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by-nd/4.0/).

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Page 1: Using Unmanned Aerial Vehicles (UAV) for Monitoring ... · Full Paper 273 Using Unmanned Aerial Vehicles (UAV) for Monitoring Biodiversity Measures in Periurban and Agrarian Landscapes

Full Paper 273

Using Unmanned Aerial Vehicles (UAV) for Monitoring Biodiversity Measures in Periurban and Agrarian Landscapes

Matthias Pietsch1, Matthias Henning2, David Mader3, Patrick Westfeld3, Florian Etterer4

1Anhalt University of Applied Sciences, Bernburg/Germany · [email protected] 2Prof. Hellriegel Institute e.V., Bernburg/Germany · [email protected] 3Institute of Photogrammetry and Remote Sensing, TU Dresden, Dresden/Germany · [email protected] 4Institute of Landscape Architecture, TU Dresden, Dresden/Germany · [email protected]

Abstract: Current farming systems and the land use change are driving forces of biodiversity loss. Based on the Convention on Biological Diversity (CBD) and the Federal Nature Conservation Act in Germany compensation measures are planned and implemented to develop appropriate structures in agrarian landscapes. Therefore a sufficient monitoring is needed. One aim of the project “stadt PARTHE Land” is to use unmanned aerial vehicles (UAV) together with imaging sensors for monitor-ing of compensation measures and the development of indicators. Based on three examples the use of multispectral (true color, near-infrared and thermal infrared) images were tested. Used indicators are vegetation indices for potential habitats, thermal infrared signatures to detect characteristic bird species (e. g. skylark) and the examination of the correct implementation (location, size, restrictions) of com-pensation measures. The results showed that UAV can be used for future applications.

Keywords: UAV, biodiversity, monitoring

1 Introduction

Land use change and the physical and functional disconnection of ecological networks rep-resent one of the driving forces of biodiversity loss (BUNDESAMT FÜR NATURSCHUTZ 2004, SPANGENBERG 2007). While farming lead to a more varied landscape in the past, intensive agricultural production since the 1950s has contributed to biodiversity decline. Both land-scape structures and plant and animal species that were adapted to extensive farming disap-peared.

The Convention on Biological Diversity (CBD) and the National Strategy on Biological Di-versity (NBS) in Germany have the objective to counter this trend by sustainably managing agriculture landscapes. Landscape planning based on the Federal Nature Conservation Act, as one possible instrument in Germany, shapes strategies for sustainable conservation and long-term development of nature and landscapes (BUNDESAMT FÜR NATURSCHUTZ 2002). Mitigation and environmental compensation measures as part of the impact mitigation pro-cedure are required based on nature conservation law at municipal level. The aim is to pre-serve natural potential and functional capacity of ecological services (fauna/flora and their habitats, soils, water, air, climate, scenic quality). In addition the implementation by land owners or land users is very important. Therefore measures are described in detail during the planning procedure and a two-phase monitoring (implementation and functionality) is nec-essary.

Journal of Digital Landscape Architecture, 3-2018, pp. 273-282. © Wichmann Verlag, VDE VERLAG GMBH · Berlin · Offenbach. ISBN 978-3-87907-642-0, ISSN 2367-4253, e-ISSN 2511-624X, doi:10.14627/537642029. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by-nd/4.0/).

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274 Journal of Digital Landscape Architecture · 3-2018

The purpose of the research project “stadt PARTHE land” is to develop appropriate struc-tures and region-specific action strategies for a sustainable cultural landscape management. One of the goals of the project (2014-2019) is to develop concepts and implement measures to enhance or restore the quality of biodiversity in periurban and agrarian landscapes. Also the evaluation and implementation of mitigation and compensation measures is important. Different measures to promote biodiversity were planned and implemented in the years 2014 to 2017 in cooperation with local farmers. A monitoring concept was designed that included field mapping of different species groups (e. g. birds, butterflies, bees, ground beetles) and vegetation as well as indicators for the ecological services described above. Starting in 2015 the monitoring was performed for all implemented measures.

Unmanned Aerial Vehicles (UAV) have the potential to support nature conservation admin-istrations with periodic reporting commitments (GUO et al. 2017, SCHMIDT et al. 2017). Therefore various types of cost-effective remote sensing data (e. g. true color, multispectral, LiDAR, thermal data) with very high spatial resolution and flexible acquisition periods can be used (MAYR et al. 2017). Hence the potential support of UAV for monitoring purpose was tested in addition to the field mapping activities. Multispectral data, consisting of true color (RGB), near-infrared (NIR) and thermal infrared (TIR) images was captured during flights in 2016 and 2017. An additional compilation of indicators based on the planning procedure, the implementation process with local farmers and the two-phase monitoring has been devel-oped and tested for the implemented measures. This paper will present and discuss first re-sults of UAV-based agriculture and landscape monitoring.

2 Project stadt PARTHE land

2.1 Project Area and Implemented Measures

The project area is a region in the east of the city of Leipzig with about 16.670 ha. It ranges from dense urban to vast rural areas. Core and connecting element of the region is the small river Parthe with its wetlands (Fig. 1).

Fig. 1: Project area “stadt Parthe land” (Openstreetmap, CC-BY-SA 2.0)

A14

A14

A38

Eilenburg

Wurzen

Grimma

Leipzig

Parthe

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Ten potential compensation measures were implemented with three local farmers in 2014 and 2015. For three of them multispectral data was collected (Tab. 1). The expected func-tional capacity of ecological services, especially of habitats for representative fauna and flora in agrarian landscapes, was described for the monitoring.

Table 1: Selected compensation measures for testing UAV

No. Measure Area Aim

01 Fallow land 2.000 m2 Diverse vegetation, habitats for bees, but-terflies and representative bird species

02 Skylark plot 38 (each 50-100 m2) Habitat for skylark and other characteris-tic bird species

03 Flower strips (combina-tion sowing/fallow land)

19.000 m2

(1.500 m × 12-15 m) Diverse vegetation, habitats for bees, but-terflies and characteristic bird species

(a) (b)

Fig. 2: Development of flower strip (measure 03) in (a) July 2015 and (b) September 2015

3 Hardware

The use of UAV as a multi-sensor platform is a powerful tool for time and cost efficient monitoring. In addition to imaging sensors, the UAV were equipped with a navigation system consisting of a GNSS sensor (Global Navigation Satellite System) for determination of the position and an IMU (Inertial Measurement Unit) for orientation. Thereby the images can be geo-referenced.

In the stadt PARTHE land project, two UAV-systems were used for data acquisition, a DJI Inspire 1 quadrocopter (Fig. 3a) with the DJI ZENMUSE X5 camera (Fig. 3b) and a Cadmic Goliath octocopter (Fig. 3c) with a multi camera system (Fig. 3d). The camera specifications are shown in Table 2.

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276 Journal of Digital Landscape Architecture · 3-2018

(a) (b) (c) (d)

Fig. 3: (a) DJI Inspire 1 (DJI 2017), (b) ZENMUSE X5 camera (DJI 2017), (c) Cadmic Goliath octocopter, (d) camera bar including a RGB-, NIR-, thermal camera

Table 2: Imaging sensors

UAV DJI Inspire 1 Goliath Octokopter

Imaging sensor DJI ZENMUSE X5

Mako G-419C (RGB)

Mako G-223B (NIR)

FLIR A65 (TIR)

Focal length 15 mm 12.5 mm 25 mm

12.5 mm 25 mm

13 mm 25 mm

Ground sample distance at 15 m

3.54 mm 6.6 mm 3.3 mm

6.6 mm 3.3 mm

19.6 mm 10.2 mm

Sensortype CMOS CMOS CMOS Uncooled microbolometer

Resolution 4608 × 3456 px 2048 × 2048 px 2048 × 1088 px 640 × 512 px

Frame rate 7 Hz 26,3 Hz 49,5 Hz 30 Hz

Radiometric characteristic

no information

300 to 750 nm 830 to 1.000 nm 7.5 to 13 µm

4 Methods

4.1 Multi-Image Processing

A visual impression of compensation measures can be obtained by geo-referenced and high-resolution images. However, those images are showing only a small section of a large area. For this reason image-based data sources like 3D point clouds and orthophotos are more usable for monitoring tasks. 3D point clouds represent the captured area in discrete 3D points with cartesian coordinates (X, Y, Z) and other given attributes (e. g. RGB, NIR, temperature, indices, …). Orthophotos are a 2D projection of an area without perspective distortion effects. Instead of using a single image, an orthophotomosaic, consisting of single orthophotos, in-crease the coverage of an area. By using geo-referenced images, the 3D point clouds and orthophotos or orthophotomosaics were also geo-referenced and became true in scale, which allows the measurement of distances and areas.

With knowledge of the interior orientation of the image (focal length c, principial point x0’), the camera’s position (X0) and orientation (ω, φ, κ) in space, the reconstruction of a single 3D point P or a 3D point cloud is possible (Fig. 4). It is required that corresponding points are mapped in two or more images. Therefore, the reconstruction of a 3D object requires the positions and orientations of the overlapping images resulting from a bundle block adjust-ment. By using the resulting point cloud and the oriented images, an orthophoto can be gener-ated. Further information can be found in literature like LUHMANN et al. 2013.

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Fig. 4: Photogrammetric measurement principle (WESTFELD 2011)

4.2 Indicators for Monitoring

The implementation (step 1) and expected functional capacity (step 2) of compensation measures must be evaluated by field mapping and defined indicators. The acquired orthopho-tos were used to check the implementation. Additional indicators for the functional capacity according to Tab. 1 are the following.

Habitats

Skylark plots are used for foraging and landing by characteristic birds of agrarian landscapes. Skylarks are breeding in their surroundings and are sensitive towards disturbance. Based on the thermal infrared images and field mapping the breeding success was analyzed.

Potential habitats

Vegetation indices or band ratio parameters identify plant biomass versus soil and residue backgrounds and are used in precision crop management and weed control (MEYER & NETO 2008). There exist different vegetation indices which are calculated from RGB or NIR-image data. They are used to identify potential habitats for representative bees and birds as well as the diversity of vegetation. Four vegetation indices were tested (Tab. 3).

Implementation of compensation measures

Compensation measures must be implemented with care. Especially for skylark plots re-strictions exist (e. g. minimum distance to trees is 50m, in between machine tracks, minimum distance to field’s edge is 25m). Location and size are important. For this reason, the mainte-nance must be monitored. Hence, aerial orthophotos were used for visual interpretation and measurement.

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Table 3: Tested vegetation indices

Index Formula Reference

Normalized Difference Vegetation Index (NDI) NDI

Green Red

Green Red

PEREZ et al. 2000

Excess-Green-Index (ExG) 2ExG Green Red Blue

WOEBBECKE et al. 1995

Red-Green-Index (RGI) RGI

Red

Green

COOPS et al. 2006

Green-Leaf-Index (GLI) 2

2GLI

Green Red Blue

Green Red Blue

HUNT et al. 2011

5 Results

5.1 Data Acquisition

Table 4 shows an overview of the measures and the used UAV-system with their captured image data, the mean flight height and the resulting ground sample distance (pixel size on ground). For generation of 3D point clouds and orthophotos the images need to overlap 80% in flight direction and 60% between flight strips. Due to limitations regarding the image-capturing mode of the ZENMUSE X5 camera, 4K image sequences up to 30 images per second were recorded and single images extracted for further processing.

Table 4: Information about the data acquisition

Measure No.

Altitude Ground Sample Distance System Data

01 35 m 8.26 mm DJI RGB

02 13 m 5.72 mm Goliath RGB, NIR, TIR

03 21 m 4.96 mm DJI RGB, 4K image sequence

03 11 m 4.84 mm Goliath RGB, NIR, TIR

5.2 Detection and Localisation of Ground Breeders (e. g. Skylark)

Thermal infrared images were tested for the monitoring of breeding success in selected sky-lark plots in 2016 and 2017. The early morning hours are the right moment to detect skylark breedings based on difference in temperature. Therefore a heating pad was prepared for calibration. In Fig. 5, the heating pad and a potential skylark breeding are visible. While in practice the breeding success is evaluated by singing male skylarks, thermal infrared images may help to detect nests. For this, the difference in temperature between the background and the skylark has to be known.

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(a) (b)

Fig. 5: (a) Thermal data with potential skylark (lower red part) and prepared heating pad (upper red part). (b) The same section in RGB data.

5.3 Detection of Bare Soil and Biomass as a Quality Indicator

To detect potential habitats of bees and measure the scale of diversity inside compensation measures, vegetation indices were tested to identify the proportion between vegetation cover and bare soil (Fig. 6). To classify the results, 100 control points were used. The Excess-Green-Index has the highest accuracy with 88 %, Red-Green-Index 84 %, Green-Leaf-Index 81 % and the Normalized Difference Vegetation Index 74 % (Fig. 6).

Excess-Green-Index Green-Leaf-Index Red-Green_Index

Normalized Difference Vegetation Index Aerial Image

Fig. 6: Comparison of different vegetation indices to analyze vegetation cover and bare soil in skylark plots (HENNING 2017)

Tests in fallow land or flower strips lead to different results due to dry vegetation. In the examined sites, the accuracy differs in comparison to skylark plots. But if there is bare soil as a quality indicator, it is possible to detect.

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280 Journal of Digital Landscape Architecture · 3-2018

Fig. 7: Excess-Green_index for flower stripes (HENNING 2017)

Unmanned Aerial Systems (UAV) are a helpful tool in verifying the implementation and restrictions for compensation measures especially during the whole growing season (Fig. 7).

In summary, the potential of UAV was identified in periodic monitoring of compensation measures. It is suitable especially for the monitoring of species that are sensitive towards disturbance (e. g. skylark). Another advantage is the documentation of compensation meas-ures by the acquired data, which can be reprocessed later.

Fig. 8: Skylark plot: measuring distance in a point cloud (left), digital elevation model (right)

6 Discussion

The two tested platforms produce different aerial images. Extracting images from image sequences lead to deterioration of quality, because of compression techniques by DJI ZENMUSE X5 camera. Wind and missing sights influence the quality of the produced or-thophotos, too. Therefore, mission planning to plan, control and manage the flights is essen-

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tial for the described monitoring. The implementation and consideration of restrictions of compensation measures can be checked during the whole growing season. UAV can support the monitoring of functional capacity. Nevertheless if field work is needed (e. g. vegetation mapping) in addition to UAV-based data recordings, cost-benefit analysis have to be dis-cussed. The examples demonstrate that the detection of some indicators (e. g. potential hab-itats, breeding success) is possible. The combination of field work and automated or semi-automated detection of indicators should be discussed and improved in the future.

7 Conclusion and Outlook

UAV have the potential to support monitoring biodiversity measures in agrarian landscapes. Especially for species that are sensitive towards disturbance and hard to find by field mapping (e. g. skylark). Thermal infrared recordings may help to detect such species with higher ac-curacy in the future and improve the evaluation of specific measures (HOFFMANN et al. 2012). Therefore, research especially in temperature differences is needed to develop species de-pendent signatures. User manuals for an efficient use of UAV in monitoring is needed and should be prepared for practical use. Cost-benefit analysis for field mapping and UAV-based data recordings for monitoring purpose is needed. A discussion between experts (field map-ping, monitoring, UAV, remote sensing) and practitioner (administration, management, na-ture conservation) is necessary to develop and evaluate indicators and support the use of UAV and the development of software application for the future.

This work has been funded by the Federal Ministry of Education and Research (BMBF), grant identifier 033L119D.

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