1. Introduction
Remote sensing in archaeology includes the application of techniques which allow the detection and documentation of both structures (features) completely buried under the earth surface, and preserved on the ground in the form of ruined monuments (so-called earthworks). Between the 1920s and 1980/90 a visual reconnaissance was practiced using small aircrafts flying at a low altitude by trained specialists: aerial archaeologists. Since at least the beginning of this century, when high (spatial and spectral) resolution space-borne and air-borne imagery became available for applications in non-military research projects, the potential of multispectral (optical) data has been tested in archaeology repeatedly through a variety of techniques, such as vegetation indices, principal component analysis, orthogonal equations, etc. [
1,
2,
3,
4,
5,
6,
7]. In the context of recent technological developments, when UAVs have provided a low-cost and effective way of acquiring data and started to be used for many purposes [
8,
9], new miniature multispectral cameras have been developed offering high spatial resolution data for other analyses [
10,
11]. New possibilities for archaeological survey, mapping and 3D modeling in site-based and small landscape transects scales have appeared [
12,
13]. Such joint applications have recently started to be tested in the practice of Czech archaeology.
This paper presents the first results of a project (first of its kind in Czech archaeology) aimed at the detection, via RGB and Red + NIR data acquired by UAV-based small scanners, of prehistoric funerary features which have not been evidenced by previous aerial observation.
2. Experiments
2.1. Study Area
The archaeological site at Černouček is situated 40 km north of Prague on the large plateau raised above the river Labe basin. This area, situated around the dominant solitary hill of Říp, belongs among the most extensively settled regions of prehistoric Bohemia. In the last two decades the Říp region has become one of the main areas in Bohemia where modern procedures of archaeological prospection have been applied [
14]. The potential of preferably non-invasive methods, and their combination with traditional approaches have been tested here in large scale. Several tens of archaeological sites dated to the Neolithic, Bronze- and Iron Ages, Roman period and early Middle Ages (5.500 BC–1.100 AD) have been evidenced during the last 25 years as a result of systematic aerial reconnaissance over Czech (Bohemian) lowlands.
An increasing number of prehistoric sites discovered through aerial survey over the Říp region are evidenced by a wide variety of archaeological components. Palimpsests created by overlapping features (houses, pits, enclosures), visible seasonally (May–July) from above due to the differences in size and colour of vegetation growing above buried (sunken) archaeological features, indicate the existence of several settlement areas and burial sites spread around the Říp.
Apart from prehistoric rural settlements (villages) a few funerary sites have been discovered in that region through aerial prospection. They usually include 1–5 burials of which each consists of a pit grave surrounded by a circular or rectangular ditched enclosure [
15,
16].
The burial site near Černouček consists of four ditched enclosures—two of rectangular and two of circular ground-plan (
Figure 1), with grave pits placed in their centre—were detected and air-photographically (in panchro) documented not only once but several times between the 1990s and 2010. All of these features were identified due to crop/vegetation marks in late spring, early summer. Principally, higher moisture and presence of some chemical constituents (such as phosphorus) present in the secondary infill of the ditches and pits conform better conditions for plants growing above them. As a consequence, changes in colour and height of such plants towards the end of the vegetation period indicate the presence of buried features [
17].
2.2. UAV Data, Acquisition and Processing
The UAV platform used in this study is a modified quadrocopter DJI Phantom 4 (
Figure 2a). Modifications consist of a mounted multispectral camera (
Figure 2b) and extra landing gears to protect the sensor. The device has been painted by black color that does not reflect sunlight to avoid a sun gleam on the ground.
The data acquisition was performed by two sensors at the same time – the original DJI 4K camera recording a video in RGB and the Survey2 NDVI camera (Red + NIR, MAPIR [
18]) recording images as red and near-infrared bands (660 and 850 nm). The UAV system was controlled by an autopilot system (the Android application Litchi) which provided autonomous navigation based on the track (waypoints) programmed before the mission. The track was set at a height 30 m above the ground, the speed was 3 km/h and the distances between track lines were defined as 18.6 m to achieve a 60% side overlap.
The data acquisition was conducted in June 2017 and the RGB and the Survey2 (Red + NIR) cameras were mounted on the UAV allowing simultaneous data acquiring. The calibration target with white, grey and black patches was placed on the ground in a flight direction to ensure to be a part of the final image mosaics (
Figure 2C). The captured datasets consists of RGB video files (MOV) with 4096 × 2160 px resolution and Red + NIR images taken every second of the flight with 4608 × 3456 px resolution as RAW + JPEG.
The pre-processing workflow differs for RGB and Red + NIR data (
Figure 3). The video files in RGB were splitted to JPEG images in interval of 1 s. We have developed a python script that was used to add the actual data acquisition time to EXIF files of extracted JPEG images. The UAV records a flight track by GPS sensor which was necessary for an assignment of flight coordinates to the JPEG images. This step was performed by the GeoSetter software. The JPEG files of Red + NIR data were located in the same way. The RAW images obtaining all spectral data were united with the located JPEG images to TIFF format by the QGIS plugin provided by the MAPIR (the Survey2 camera producer).The prepared images from the both cameras were processed in the Agisoft PhotoScan Pro software (
Figure 3). We have followed the software workflow to get a 3D model and orthomozaic which means—aligning photos, building dense cloud, building DEM and building orthomozaic. The whole process was controlled and manually modified to achieve the best results.
2.3. Red + NIR Data Analyses
The Red + NIR data were transformed to the reflectance employing the empirical line method [
19] using the laboratory-measured reflectance of the light and dark patches of the calibration target (
Figure 2C). After that it was possible to build linear calibration equations to convert at-sensor radiance to estimated surface reflectance. Red + NIR reflectance was used to:
Derive Vegetation Indexes (VI): Normalized Differential Vegetation Index (NDVI) and Simple Ratio Index.
To employ Decorrelation Stretch (DS) technique to enhance the color differences in Red + NIR data.
The spatial filtering was employed to both the VI and the DS data sets. To enhance image texture Lee filter [
20] was used, this filter smooths noise using the multiplicative speckle model, on the other side it also uses local statistics to effectively preserve edge features.
3. Results and Discussion
Two Černouček burial ditched enclosures -one rectangular (12.5 × 12.5 m, marked II on
Figure 4), and one circular (11 m in diameter,
Figure 1, marked I on
Figure 4) enclosures near Černouček were scanned by DJI and Survey2 cameras placed at UAV in order to find out whether some other objects of prehistoric origin hidden under the ground—and not evidenced yet during annually repeated visual observations from low flying aircraft—can be detected through Red + NIR data.
The data taken over the Černouček site were processed to one digital elevation model (RGB) with spatial resolution 2.41 cm/px and to two orthomozaics (RGB and Red + NIR) with resolution 1.2 cm/px, respectively 0.99 cm/px. Remote sensing analyses such as NDVI, Simple Ratio Index and DS were employed to the Red + NIR data.
The results displayed the two ditched enclosures (I and II in
Figure 4) discovered in the past and several new objects including two small enclosures (circles with solid lines,
Figure 4), possible ditches, with centrally placed points inside them. Some other features (circles with dotted line,
Figure 4) may represent single pits of variable function (burial/storage/refuse), but their non-archaeological origin (of at least some of them) is possible as well: without ground truthing by means of geophysical survey or test/sample excavation it is difficult to definitely interpret their age and origin. Anyway, the linear arrangement of the dots indicates their man-made origin.
4. Conclusions
In this study, we examined the usage of remote sensing techniques (such as UAV) in archaeology. The processed data acquired by the UAV-based RGB and Red + NIR cameras over the Černouček burial objects achieved high spatial resolution (0.99–2.41 cm/px) and allowed to apply remote sensing analyses that discovered already known prehistoric features, as well as a few objects which have not been recorded by conventional aerial reconnaissance.
Future studies should repeat these methods in different seasons to see how different conditions and vegetation affect results. We are also planning to use and compare these data with data recorded by multispectral sensor—Parrot Sequoia. As the project is at the beginning we are going to apply more field work techniques and analyses to discover the origin of new detected features.
Author Contributions
Lucie Koucka recorded the data by UAV, figured out the processing method and prepared a draft version of the manuscript. Veronika Kopackova designed the study, made remote sensing analyses and added her contribution to the manuscript. Katerina Farova processed the data, and Martin Gojda provided an archaeological background, wrote a part of the manuscript and interpreted discovered objects.
Acknowledgments
This study is a part of the project of Czech Geological Survey that is focused on testing of the UAV DJI Phantom 4 for scientific purposes. Project number: 322600.
Conflicts of Interest
The authors declare no conflict of interest.
Abbreviations
The following abbreviations are used in this manuscript:
DEM | Digital Elevation Model |
DS | Decorrelation Stretch |
NDVI | Normalized Differential Vegetation Index |
NIR | Near-Infrared |
UAV | Unmanned Aerial Vehicle |
VI | Vegetation Index |
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