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ADDED VALUE OF NEW REMOTE
SENSING AND UAV FOR RISK
FOREST PROTECTION SURVEY AND
MONITORING
ASP 462 – RockTheAlps
WP1 – Activity A.T2.2
Deliverable D.T2.2.3
Coordinated by: doc. dr. Milan Kobal, Barbara Žabota (UL); prof Marco Piras (POLITO)
Ljubljana, September 2018
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ROCKTHEALPS PARTNERSHIP
IRSTEA – National research institute of science and technology for environment and agriculture
BRGM – French Geological Survey
Alp’Géoriskques
SFS – Slovenian Forest Service
UL – University of Ljubljana, Biotechnial Faculty, Department for Forestry and Renewable Forest Resources
SFI – Slovenian Forestry Institute
UNIPD – University of Padova, Department of Land, Environment, Agriculture and Forestry
DISAFA – Department of Agricultural, Forest and Food Science, University of Turin
ERSAF – Regional Agency for Services in Agricultue and Forest - Lombarida Region
PAT-SFF – Autonomous province of Trento, Forest and Wildlife Department
POLITO – Politecnico di Torino, Department of Territory, Land and Infrastructure Engineering
BFW – Federal Research and Training Centre for Forests, Natural Hazards and Management
BMLFUW – Austrian Federal Ministery of Agriculture, Forestry, Environment and Water Management
LWF – Bavarian State Institute of Forestry
BFH – HAFL – Bern University of Applied Sciences, Department of Forest Sciences
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TABLE OF CONTENT
Nessuna voce di sommario trovata.
1 INTRODUCTION ............................................................................................... 1
2 UAV TECHNOLOGY ........................................................................................ 2
3 THE ADVATAGES OF USING UAV FOR FOREST SURVEY AND
MONITORING .................................................................................................................... 9
4 THE LIMITATION OF THE UAV USE IN FORESTRY ............................ 13
5 CASE STUDIES ................................................................................................ 14
5.1 CEVO (BS) – ITALY .......................................................................................... 14
5.2 COLLE SANTA LUCIA (BL) – ITALY ............................................................ 15
5.3 CESANA (TO) – ITALY ................................................................................... 16
6 DATA ANALYSIS AND RESULTS ................................................................ 16
7 CONCLUSIONS ................................................................................................ 21
8 REFERENCES .................................................................................................. 22
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TABLE OF FIGURES
Figure 1. Different airframes. From the left: polystyrene, plastic, aluminium, carbon fibber ........................... 2
Figure 2. Examples of professional, semi-professional and action cameras for UAVs...................................... 3
Figure 3. U-blox GNSS receivers ....................................................................................................................... 5
Figure 4: two different method for image acquisition: nadir (on the left) and oblique (on the right) ............... 7
Figure 5: Using drones a high spatial resolution of orthophoto images can be achieved ................................... 9
Figure 6: With drones a high spatial resolution of data can be achieved as the observed phenomena can be
monitored more frequently. .............................................................................................................................. 10
Figure 7: 3D model of the rockfall and surrounding forest can offer a better visualisation of the rockfall
impact on forest and forest protection function ................................................................................................ 11
Figure 8: 3D model of rockfall and surrounding forest .................................................................................... 11
Figure 9: An example of NDVI index on the location of rockfall Kekec (Slovenia) where good difference can
be absorbed among the rockfall area and its contact with forest ...................................................................... 12
Figure 10: Comparison of canopy height model (CHM) among raster cell size 1×1 m and 0.25×0.25 m. ...... 13
Figure 11: Location (left) and test site (right) .................................................................................................. 14
Figure 12: flight planning ................................................................................................................................. 15
Figure 13: Location (left) and flight planning (right) ....................................................................................... 15
Figure 14: Location (left) and flight planning (right) ....................................................................................... 16
Figure 15: flowchart of UAV data processing .................................................................................................. 17
Figure 16: example of Alignment step ............................................................................................................. 18
Figure 17: example dense point cloud (on the left) and classification (on the right) ........................................ 18
Figure 18: DSM and orthophoto in Cevo ......................................................................................................... 19
Figure 19: DSM and orthophoto in Colle Santa Lucia ..................................................................................... 20
Figure 20: DSM and orthophoto in Cesana ...................................................................................................... 21
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1 INTRODUCTION
Forest structure is a key parameter in defining the protection function of forest against
natural hazards (Maier et al., 2008). Forests especially in mountainous areas protect people
and their assets against different slope processes e.g. rockfalls, avalanches, landslides,
debris flows etc. Forest cover has a mitigation effect due to standing and lying trees and
their capacity to dissipate energy. Defining forest stand structure is an important task as
based on different parameters, etc. stand density, basal area, DBH, the protective effect of
forest can be evaluated (Belcore et al., 2018).
As already mentioned in D.T1.2.3, since several year, the use of UAV (unmanned aerial
system) aerial surveys by using unmanned aerial vehicles (UAV), especially through
Airborne Laser Scanning (ALS) or photogrammetry, were carried out in the last years to
acquire point clouds to be used in 3D models aimed at achieving an accurate description of
tree crowns and terrain as well as surveying and monitoring natural hazards that occur in
the forests.
The use of drones in forestry has been primarily focused on mapping and monitoring forest
fires, however their use is increasing for applications such as tree crown/gap mapping,
forest stand mapping, volume estimation, wind blow assessment, pest monitoring and
harvest planning (Paneque-Gálvez et al., 2014). Successful implementation of drones in
forestry depends on following features of UAV’s: flexibility of use in flight planning, low
cost, reliability and autonomy, and capacity to produce a high-resolution data (Torresan et
al., 2017). UAVs in forestry can be used for (based on examples in: Vepakomma et al.,
2015; Tang and Shao, 2015; Banu et al., 2016; Torresan et al., 2017; Taddese Berie and
Burud, 2018): tree species classification, quantification of spatial gaps in forests, post-fire
recovery monitoring and forest fire measuring, forest health monitoring and forest diseases
mapping, post-harvest soil displacement estimation and supporting intensive forest
management.
The use of UAV can have many benefits in surveying and monitoring protection forest in
order to maintain protective effect of forest and regenerate it protective effect after the
events that can largely decrease it. Combined with remote sensing techniques UAV offer a
versatile opportunities how to improve forest mapping and monitoring with the regards to
natural hazards like rockfall. The following content is presenting some of the major
advatages of UAV for risk protection survey and monitoring regards to traditional field
methods and also conventional remote sensing techniques.
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This report introduces the UAV in forested sites, analysing the different sensors required
and available results carried out by a data acquisition made by drone. In the second part of
the report focuses on some case studies, stressing advantages and disadvantages of its use
for rockfall monitoring and generally over forested sites.
2 UAV TECHNOLOGY
Aerial vehicles are complex systems made by hardware and software structures. The
improvement of electronics allowed the development of navigation and control systems
more and more available on the market.
The main components required to use the UAV are:
1) the aerial platform, which includes the airframe, the navigation system, the power
system and the payload
2) ground control station (GCS), which allows the human control from a remote
emplacement; and the communication system, which supports the communication
between the other two components.
The UAV could be composed by different components::
airframe: it is the main structure, which has to be designed according to the specific
sensors that have to be installed. Its structure has to consider the weight regarding
in particular the power and the communication and control systems on board.
Moreover, the airframe needs to be properly designed to withstand the forces that
can occur during the flight and not cause deformation and vibration. Fixed wings
on UAVs are mainly made on polystyrene or plastic, while common multi-rotors
airframes are made on aluminium or carbon fibber (in such a way as to be
lightweight and resistant) (Figure 1), and the number of arms is a function of the
expected payload and the number of engines;
Figure 1. Different airframes. From the left: polystyrene, plastic, aluminium, carbon fibber
Navigation system (board): this board allows autonomous or semi-autonomous
flights through hardware and software components. The specification of the
autopilot for a UAV can be summarized as reported in Table 1. The autopilot
includes positioning (Global Navigation Satellite System – GNSS receiver) and
attitude (inertial platform) systems and the data registered from these sensors are
managed by a microcontroller that, after the process of the input signals, can send
updated information to the autopilot to control the stability and the trajectory;
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Physical specifications
Sensor specifications
Autopilot functions
Size Operative temperature
Waypoints navigation
Weight Max angular rate
Auto take-off and landing
Power consumption
Max acceleration
Altitude hold
Required voltage Max angular velocity
Servo control rate
Required CPU Max altitude Telemetry rate
Memory Operative airspeed
Fail safe
Table 1. Autopilot main specifications
Focusing more the attention on the payload, various gimbals and acquisition systems can be mounted on-board. These sensors can mainly include the following:
• digital cameras: the most common use for UAVs is image and video acquisition for monitoring, photogrammetry [0]. Different kind of cameras are now available as professional, semi-professional and action cams, but the lens calibration is always required to ensure a final good result;
Figure 2. Examples of professional, semi-professional and action cameras for UAVs
• thermal detector: these systems can be used in situations with an important gradient of temperature in order to add the thermal information to the visible one [0],
• multispectral cameras: these sensors can be very helpful in environmental applications to classify different kinds of vegetation or to monitoring the growth and variation of some areas [0]. Table 2 summarizes some characteristics of the most used multispectral sensors;
PARROT SEQUOIA
MICASENSE REDEDGE
Tetracam ADC Micro
N° spectral channel
4 5 3
Spectral range 550-790 nm 400-900 nm 520-920 nm
Weight 0.072 Kg 0.15 Kg 0.09 Kg Table 2. Comparison between the most used multispectral sensors
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• LiDAR (Light Detection And Ranging): these devices are very helpful during the night, with clouds or shadows and especially in presence of many trees (Table 3). This is possible because they are active sensors that transmit a signal to the object then they measure the intensity of the returned signal [0];
YELLOWSCAN RIEGL VUX-1UAV LeddarVu 8
Wavelength 905 nm 905 nm 905 nm
Maximum range 50m typ. 100m abs.
from 85 m to 920 m
from 6 m to 61 m
Accuracy 5 cm 1 cm 5 cm
Scanner field of view
360° 330° 100°
Weight 1.5 Kg 3.5 Kg 0.128 Kg Table 3. Comparison between the most used LiDAR sensors
• IMU-MEMS (Inertial Measurement Unit - Micro Electro-Mechanical Systems): useful for real time navigation and post-processing attitude estimation;
• GNSS receivers: these sensors are able to obtain the position of the UAV along the flight. In particular, navigation systems play a fundamental role and these systems use not only one or
more GNSS receivers, but also an inertial navigation system that is necessary to provide the
vehicle set-up information for each epoch, and to assist the GNSS system in estimating the
position of the vehicle.
The use of these sensors, however, requires the resolution of a series of problems, both
theoretical and practical, linked for example to their synchronization and calibration. Typically,
these problems can be solved by developing appropriate hardware and software tools, where
systematic errors (bias) and sensor drift (s) are analyzed and compensated, with the ultimate goal
of obtaining a navigational solution sufficiently accurate, also in relation to the type of application
in which the sensors are used.
Different solutions can be available, mainly based on these possibilities:
• Single/multi frequency receivers: possibility to improve the solution with the usage of the
L2 frequency;
• Single/multi constellation antennas and receivers: the availability of more than one
constellation can improve, also in this case, the final positioning solution;
• RTK (Real Time Kinematic) approach: it is the possibility to improve the position estimated
in real time with correction from a master or a permanent station;
• GNSS/IMU integration: it is also possible to improve the GNSS position with data from the
inertial platform.
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The market offers many low-cost GPS or GNSS receivers, often available as an OEM card. In other
cases, some Devolopper Kit are available, as in the u-blox receivers: this makes them immediately
usable since the card is already combined with a USB serial port, a power supply device and a LAN
network port.
In particular, the u-blox receiver (Figure 3, now available in v.8) is a GNSS receiver, capable of
receiving also 4 single-frequency GNSS constellations. At a cost of about € 300, it is an interesting
solution with minimum overall dimensions and an easy interface. The presence of the
communication port requires only to prepare a data storage on micro PC and SD card (or similar)
and the transfer of raw data to a processing center.
Figure 3. U-blox GNSS receivers
https://www.u-
blox.com/en/product/ma
x-m8-series
On the other hand, some OEM card solutions with a variable cost between € 100 and €1000 are
also available (examples in Erreur ! Source du renvoi introuvable.). Among the "medium-high"
receivers, some multi-frequency and multi-constellation OEM records should be highlighted, not
included in any management and display device. These cards should therefore be engineered and
could constitute a low cost solution but with centimeter precision suitable also for real time.
These receivers are already set up for RTK acquisitions and they may have options that are not
always included in normal receivers.
SkyTra NS-HP TERSUS BX316 TOPCON B125
Dimension 25 x 25 mm 108 x 54 mm 40 x 55 mm
Weight 3 g 50 g 20 g
Frequency Single Dual Dual
Constellation GPS, Beidou GPS, GLONASS, Beidou GPS, GLONASS, Galileo, Beidou, SBAS
Max acquisition rate
20 Hz 20 Hz 100 Hz
Possibility of RTK Yes Yes Yes
Communication protocol
RTCM 3.x RTCM 2.x/3.x/CMR/CMR+ TPS, RTCM SC104 2.x and 3.x, CMR, CMR+
Classification Low-cost ($ 100) Medium-cost ($1,799.00) Medium/high-cost ($3,500.00)
Table 4. Comparison between different rate OEM GNSS receivers
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About the IMU sensors, an inertial measurement unit consists of a set of sensors, generally
accelerometers and gyroscopes, necessary to allow the estimation of all the navigation states at a
high frequency. Since these are sensors of an electro-mechanical nature, the measurements
carried out are affected by systematic errors (measurement bias, scaling factors or non-
orthogonality of the sensor triplets) and accidental errors (noise).
Usually the height of flight is fixed not considering a real elevation model. In same case, flight
planners are able to consider some global digital elevation models, and define a flight plan with a
constant distance from the ground (figure 3). This is important in particular in steep areas, where
the value of GSD can be very different is the flight height is constant and the surveyed area has a
strong difference of altitude.
Figure 3: example of flight planner that is able to consider also a global terrain. In the image is also possible to see that flight planner have always the possibility to setup a geofence, which represents the limit of the area of operation of the UAV.
Recently, there is a new approach adopted for photogrammetry application which is based on the
acquisition of oblique images. In this case, the planning has to be completely different and the
traditional tools are not more available. The same problem rises when the image acquisition is
made along a vertical façade (e.g. rock façade), where the flight is manually made, using the
experience of the pilot. Moreover in this condition, working along a vertical plane, the height is
not perfectly guarantee and stable due by the position quality estimated by the GNSS receiver.
The oblique acquisition is the typically based on the use of multirotors.
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Figure 4: two different method for image acquisition: nadir (on the left) and oblique (on the right)
Ground Control Points The use of Ground Control Points is an important element that could have a strong impact on the
accuracy of the SfM-based DSM (James et al., 2012; Turner et al., 2015). GCPs are points of known
coordinated that can be clearly recognized in the photo-sequence acquired by UAV. These points
can be elements present in the field or artificial targets placed in the surveyed area before the
UAV flight. The position of GCPs is acquired using high accuracy topographic methods like GNSS or
total stations and then identified in the photo sequence during the SfM procedure (Harwin and
Lucieer, 2012). The use and the number of GCPs depends on the required final accuracy of the
positioning of the DSM and the quality of the UAV positioning system.
As said before, it is possible to have on the UAV GPS only or multi-constellation receiver, but it is
important to evaluate the combination between receiver and antenna, in order to define the final
performances. In some cases, an external GNSS receiver is installed, which is used to collect the
raw data only. This solution is adopted for direct photogrammetry applications (Turner et al.,
2014; Eling et al., 2015; Mian et al., 2015; Gabrlik et al., 2018), where is required a high resolution
GNNS on board that reduce the importance and the impact of GCPs on the final accuracy of the
DSM.
The number of GCPs and their position is hard to define a priori, but some simple operative
suggestions can be useful for a good distribution of these points: i) follow the limit of the area of
interest ii) insert other GCPs inside the area of interest considering also the elevation differences
of the area. Other critical consideration that have to be evaluated during the deployment of GCPs
are, according to James et al. (2017): i) the importance of datum alignment to gravity ( the
distribution of targets can be carefully considered in particular if the final model can be used for
modelling gradient-sensitive processes like, for example, rainfall runoff), ii) the presence of
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vegetation at the scale of the physical control targets (that could hamper the identification of
targets on images) iii) the absolute 3-D positioning.
Another important element that should be carefully considered during the definition of number
and position of GCPs is the real effort that the deployment and survey of these points required.
Nex and Remondino (2014) propose an evaluation of the time effort in a typical UAV-based
photogrammetric workflow. The time effort evaluation proposed by Nex and Remondino (2014)
is: Flight planning 5%; Image acquisition 20%; GCPs field measurement 15%; image triangulation
15%; DSM generation 25%; Ortho mosaicking 10%; Feature extraction 10%.
In our experience, usually the time required for the survey of GCPs is twice or more the time
necessary for the UAV survey. This element should be carefully considered because the
deployment of targets has to be done before the flight, and this activity can constrain the UAV
flight activity that often should be done in the central part of the day to limit the influence of
shadows.
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3 THE ADVATAGES OF USING UAV FOR FOREST SURVEY AND
MONITORING
The operational altitude of small drones usually ranges from 50 to 300 m and consequently
permits the acquisition of high spatial-resolution imagery (with pixels of few centimetres)
which enhances the visual analysis (Figure 1). High-resolution imagery enables the
identification and monitoring of specific trees, canopy gaps, forest loss, damaged and
fallen trees, degradation and regrowth processes (Paneque-Gálvez et al., 2014; Inoue et al.,
2014; Banu et al., 2016).
Figure 5: Using drones a high spatial resolution of orthophoto images can be achieved
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The identification of single tree species it’s an important factor in evaluation of the
protection forest against rockfalls and other natural hazards. Assessing the forest health
condition can be used for evaluating the state of protection forest.
Small drones can be used for detailed mapping over larger areas than ground surveys
(Banu et al., 2016). With their use we save time for obtaining the imagery and on the small
to medium size areas the monitoring can be repeated in shorter time period which can be
practical for monitoring a particular protection forest at for example one rockfall site.
Imagery can also be acquired more frequently compared with conventional remote sensing
techniques (e.g. satellite and aircraft imagery), meaning that assessment of local protection
forest at shorter intervals (Figure 2) and immediately after the rockfall event, which can
offer an insight on which silvicultural or other technical measures need to be taken in order
to restore protection function of the forest stand. Also, small UAVs can fly bellow the
cloud level which gives them an important advantage over conventional remote sensing
platforms as they can offer images without clouds (Paneque-Gálvez et al., 2014). The
smallest UAVs can also fly near the forest canopy or under the forest canopy, while
medium and larger ones can also fly on higher alltitudes (Tang and Shao, 2015).
Figure 6: With drones a high spatial resolution of data can be achieved as the observed phenomena can be
monitored more frequently.
Based on the images that UAV capture, 3D surface models, digital surface models, digital
elevation models and canopy height models can be generated (Figure 3 and 4). Using those
models, we can improve forest monitoring strategies (e.g. detection of the damaged trees
due to rockfall, the regrowth stage of protection forest etc.) and use them for retrieving
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forest structural parameters (e.g. height, basal area, DBH, tree density, tree species
composition etc.) (Banu et al., 2016; Mohan et al., 2017).
Figure 7: 3D model of the rockfall and surrounding forest can offer a better visualisation of the rockfall
impact on forest and forest protection function
Figure 8: 3D model of rockfall and surrounding forest
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Small drones are easy to operate with and can be used fully or semi-autonomously by the
users that have little training and no geomatic knowledge. Also, the cost of small drones
are relatively low compared with classically obtained aircraft imagery or satellites
(Paneque-Gálvez et al., 2014). We can monitor areas that are hard to access or remote, e.g.
steep slopes, rocky terrain, as rockfalls usually are. With drones we can consequently
improve the working conditions for field workers as they become safer.
With the use of multispectral cameras forest health can be monitored using different
vegetation indices. One of the most common is normalized difference vegetation index
(NDVI) that employs the multi-spectral remote sensing data techniques to find vegetation
index, land cover classification, vegetation, water bodies, open area, scrub area, hilly areas,
agricultural areas, thick forest, thin forest with few band combinations of the remote
sensed data (Gandhi et al., 2015). NDVI is a simple metric that indicates the health of
green vegetation. Chlorophyll stongly reflects near infrared light (NIR, around 750 nm)
while red and blue are absorbed. As it reflects strongly the plant appear green to us,
however reflection in NIR is even greater which helps us in rendering precise data for
analysis. NDVI is based on a principle that the leaves, due to spongly layers on their
backsides, reflect a lot of light in the near infrared to the constrast with most non-plant
object. When a plant is dehydrated or stressed, the spongly layer collapses leading to the
reduced reflection of NIR light when the same amount stays in the visible range. Using the
combination of this signals can help differenciate plant from non-plant and healthy tree
from a damaged tree (Mahajan and Bundel, 2017) (Figure 5).
Figure 9: An example of NDVI index on the location of rockfall Kekec (Slovenia) where good difference can
be absorbed among the rockfall area and its contact with forest
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Therefore, using multispectral cameras in combination with UAV can enable the
calculation of NDVI index (and other vegetation indices) for individual investigated trees
as the pixles (Figure 6) for vegetation layer can be relatively small. This way the trees that
have been affected by a rock and are therefore severly damaged, can be recognized.
Figure 10: Comparison of canopy height model (CHM) among raster cell size 1×1 m and 0.25×0.25 m.
4 THE LIMITATION OF THE UAV USE IN FORESTRY
Nevertheless that UAVs have great advatages for the use in forestry, there still some
limitations that hinder their operation. As UAVs are usually small they have a limit of the
equipment that they can carry onboard. Consequently the amount of additional sensors and
GNSS devices in the monitoring process are quite limited. They are also more susceptible
to pitch, roll and yaw distortions that can affect the georeferencing (Paneque-Gálvez et al.,
2014).
The placing of ground control point can be challenging as the point under the canopy
won’t be visible on imagery and will hinder the georeferencing. Even more, because
rockfalls usually occur on steep terrains that are hardly accessible there might be problem
by finding appropriate places for ground control points. In the remote areas we might also
face a bad signal receipt which will disable us to accurately measure the position of ground
control point or it will hinder the GNSS connection on UAV itself and won’t enable us a
direct georeferencing. The duration of the flight itself is usually short and limited and
depends on the carrying capacity of the UAV and the size of batteries (NEWFOR…,
2014).
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During the flight there is always a possibility of collisions with objects on their way – for
example trees or steep slopes. Similar situations may occur in the lost signal among UAV
and its operator and when we lose the sight of its movement. Weather and atmospheric
conditions can also impact the UAV flights, especially heavy rain, strong winds and fog.
5 CASE STUDIES
UAV systems are involnving in several test sites, with purpose to verify the performance
and accuracy available, considering different platform, software, sensors and apprpoaches.
In the following section, three case studies are described, where UAV has been used in
order to generate a DSM and orthophotos for forestry application and adopted in the RTA
project.
5.1 CEVO (BS) – ITALY
In this fisrt case, a fixed wings UAV has been used to collect RBG image, with purpose to
generate a DSM and a DTM, extracting the terrain only and realizing a classification.
The site is Cevo (BS) (see figure), where a LiDAR data collecteion has been realized many
years ago. Now, the data collection has been focused in a specific area, defined in the
figure.
Figure 11: Location (left) and test site (right)
One flight has been carried out, collecting 188 image and covering an area equal to 15,4
ha. The relative flight height was 127,5m. The average GSD (groud sampling distance) has
been 3 cm/px and a duration of data acquisition equal to 14 minutes.
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Figure 12: flight planning
5.2 COLLE SANTA LUCIA (BL) – ITALY
In this case, the data acquisition was similar to the previous one, where one flight has been
carried out, collecting 302 image but covering a largest are, which was equal to 57.61 ha.
The relative flight height was 100m. The average GSD (groud sampling distance) has been
5.47 cm/px and a duration of data acquisition equal to 22 minutes. Location and flight
planning are reported in the following figures.
Figure 13: Location (left) and flight planning (right)
In this case, a terrestrial data acquisition with Lidar has been carried out.
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5.3 CESANA (TO) – ITALY
In this site, three different flights have been carried out: 2 usign RGB camera and 1 with a
NIR camera. In the following table, the main properties of each flight are summarized.
RGB 1 RGB 2 NIR 1
Average H [m] 100 100 100
GSD [m] 5.47 5.47 6.29
Duration (min) 18 12 19
Area [ha] 60 40 76.4
# images 221 137 176
Table 5. Comparison between different rate OEM GNSS receivers
The flight planning is shown hereafter.
Figure 14: Location (left) and flight planning (right)
6 DATA ANALYSIS AND RESULTS
After data acquisition, each dataset has been processd by two different sofwares: Agisoft
photoscan and Pix4D. The approach used to realize the data processing is quite similar in
both cases, and it could be schematize as:
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Figure 15: flowchart of UAV data processing
where the “alignment” is the step where a preliminary “combination and join” between the
images and sparse point cloud is generated.
Mesh generation
DTM/DSM and orthophoto
generation
Import images (and
geoinformation)Alignment of images
Import GCPs coordinates and
markers identification in the
imagesCamera parameters optimization
Dense point cloud generation
Dense point cloud classification
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Figure 16: example of Alignment step
After this step, imposing the GCPs, it is possible to extract the dense point cloud and the
related classification, as shown in the following figures.
Figure 17: example dense point cloud (on the left) and classification (on the right)
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Last step is the generation of the DSM, DTM and the orthophotos, removing the vegetation
using the classification. Some examples are shown in the following, considering the case
studies.
Figure 18: DSM and orthophoto in Cevo
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Figure 19: DSM and orthophoto in Colle Santa Lucia
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ù
Figure 20: DSM and orthophoto in Cesana
7 CONCLUSIONS
UAS system is surely a very interesting and powerful tool for many different application
fields in particular in forestry, where the use of RGB and NIR camera can be help the
expert and professional to generate DSM, DTM, classification and orthophoto.
Moreover, the new technologies allow to solving all kind of survey and evinronment, but it
is fundamental to have some knownledge on data acquisition and data processing, with
purpose to be able to evaluate the results and to select the correct approach.
In particular in forestry application, background is fundamental and mandatory, to be able
to planning correctly the flight trajectory, the sensor and to platform (fixed wings or multi-
rotors).
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