TY - GEN
T1 - Investigations Into the Accuracy of the Uav System Dji Matrice 300 Rtk with the Sensors Zenmuse p1 and l1 in the Hamburg Test Field
AU - Kersten, Thomas
AU - Wolf, Joseph
AU - Lindstaedt, Maren
N1 - Publisher Copyright:
© 2022 T. Kersten et al.
PY - 2022/5/30
Y1 - 2022/5/30
N2 - The development of increasingly powerful Unmanned Aerial Vehicles (UAV) is progressing continuously, so that these systems equipped with high-resolution sensors can be used for a variety of different applications. With the Matrice 300 RTK, Da-Jiang Innovations Science and Technology Co. Ltd (DJI) has launched a system that can use the high-resolution camera Zenmuse P1 or the laser scanner Zenmuse L1 as a recording sensor, among other sensors. In order to investigate the geometric quality of these two sensors, HafenCity University Hamburg, in cooperation with LGV Hamburg, NLWKN in Norden and the German Archaeological Institute in Bonn, flew over the 3D test field in the Inselpark in Hamburg-Wilhelmsburg on 5 August 2021 with the P1 camera and the L1 laser scanner. Using the Matrice 300 RTK as carrier platform, the test field was recorded in various configurations at altitudes between 50 m and 90 m above ground. Prior to the UAV flight campaign, 44 marked ground control points (GCP) were signalised in the test field, which had already been surveyed by LGV in 2020 using geodetic measurement methods to achieve a coordinate accuracy of ±5 mm for each GCP. The results of aerial triangulations as well as 3D point clouds generated from image data and laser scanning are compared with reference data in order to demonstrate the accuracy potential of these measurement systems in this paper.
AB - The development of increasingly powerful Unmanned Aerial Vehicles (UAV) is progressing continuously, so that these systems equipped with high-resolution sensors can be used for a variety of different applications. With the Matrice 300 RTK, Da-Jiang Innovations Science and Technology Co. Ltd (DJI) has launched a system that can use the high-resolution camera Zenmuse P1 or the laser scanner Zenmuse L1 as a recording sensor, among other sensors. In order to investigate the geometric quality of these two sensors, HafenCity University Hamburg, in cooperation with LGV Hamburg, NLWKN in Norden and the German Archaeological Institute in Bonn, flew over the 3D test field in the Inselpark in Hamburg-Wilhelmsburg on 5 August 2021 with the P1 camera and the L1 laser scanner. Using the Matrice 300 RTK as carrier platform, the test field was recorded in various configurations at altitudes between 50 m and 90 m above ground. Prior to the UAV flight campaign, 44 marked ground control points (GCP) were signalised in the test field, which had already been surveyed by LGV in 2020 using geodetic measurement methods to achieve a coordinate accuracy of ±5 mm for each GCP. The results of aerial triangulations as well as 3D point clouds generated from image data and laser scanning are compared with reference data in order to demonstrate the accuracy potential of these measurement systems in this paper.
KW - accuracy
KW - bundle block adjustment
KW - ground control points
KW - reference data
KW - RTK-GNSS
KW - test field
KW - UAV/UAS
UR - https://www.scopus.com/pages/publications/85131946392
U2 - 10.5194/isprs-archives-XLIII-B1-2022-339-2022
DO - 10.5194/isprs-archives-XLIII-B1-2022-339-2022
M3 - Conference Paper
AN - SCOPUS:85131946392
VL - 43
T3 - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences - ISPRS Archives
SP - 339
EP - 346
BT - XXIV ISPRS Congress on Imaging Today, Foreseeing Tomorrow, Commission I
A2 - Hinz , S.
A2 - Feitosa, R.Q.
A2 - Weinmann, M.
A2 - Jutzi, B.
T2 - 2022 24th ISPRS Congress on Imaging Today, Foreseeing Tomorrow, Commission I
Y2 - 6 June 2022 through 11 June 2022
ER -