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References (18)
-
(2019)
HERA Lidar Instrument Development -
S. Brischetto (2018)
Analysis of natural fibre composites for aerospace structuresAircraft Engineering and Aerospace Technology
-
T. Hashimoto, T. Kubota, T. Mizuno (2003)
Light weight sensors for the autonomous asteroid landing of MUSES-C missionActa Astronautica, 52
-
C. Gardner (1992)
Ranging performance of satellite laser altimetersIEEE Trans. Geosci. Remote. Sens., 30
-
N. Thomas, T. Spohn, J. Barriot, W. Benz, G. Beutler, U. Christensen, V. Dehant, C. Fallnich, D. Giardini, O. Groussin, K. Gunderson, E. Hauber, M. Hilchenbach, L. Iess, P. Lamy, L. Lara, P. Lognonné, J. Lopez‐Moreno, H. Michaelis, J. Oberst, D. Resendes, J. Reynaud, R. Rodrigo, S. Sasaki, K. Seiferlin, M. Wieczorek, J. Whitby (2007)
The BepiColombo laser altimeter (BELA): Concept and baseline designPlanetary and Space Science, 55
-
P. Gordo, Nicole Dias, Bruno Couto, B. Arribas, A. Amorim, Belegante Livio, R. Melício, A. Marques, T. Sousa, Vasco Granadeiro, P. Michel (2020)
Planetary Altimeter for HERA Development -
T. Mizuno, T. Kase, T. Shiina, M. Mita, N. Namiki, H. Senshu, R. Yamada, H. Noda, H. Kunimori, N. Hirata, F. Terui, Y. Mimasu (2017)
Development of the Laser Altimeter (LIDAR) for Hayabusa2Space Science Reviews, 208
-
(2019)
HELENA– Hera LIDAR engineering model altimeter design -
(2015)
Scientific measurements of HAYABUSA-2 laser altimeter (LIDAR) -
L. Ramos-Izquierdo, V. Scott, J. Connelly, S. Schmidt, W. Mamakos, Jeffrey Guzek, Carlton Peters, P. Liiva, Mike Rodriguez, J. Cavanaugh, H. Riris (2009)
Optical system design and integration of the Lunar Orbiter Laser Altimeter.Applied optics, 48 16
-
R. Kallenbach, E. Murphy, B. Gramkow, M. Rech, K. Weidlich, Thomas Leikert, R. Henkelmann, B. Trefzger, B. Metz, H. Michaelis, K. Lingenauber, S. DelTogno, T. Behnke, N. Thomas, D. Piazza, K. Seiferlin (2013)
Space-qualified laser system for the BepiColombo Laser Altimeter.Applied optics, 52 36
-
To cite this article: Nicole G. Dias et al 2021 -
Li Shuang, ZhangDalian Liu (2009)
Autonomous navigation and guidance scheme for precise and safe planetary landingAircraft Engineering and Aerospace Technology, 81
-
K. Tsuno, E. Okumura, Yoshihiko Katsuyama, T. Mizuno, Tatsukaki Hashimoto, M. Nakayama, H. Yuasa (2006)
Lidar on board asteroid explorer Hayabusa, 10567
-
Uwe Stilla, B. Jutzi (2008)
Topographic Laser Ranging and Scanning: Principles and Processing -
Ma Mokhtari, M. Shahravy, M. Zabihpoor (2019)
Novel development of dynamic behavior of carbon fiber reinforced polymer sandwich panels with stepwise graded adhesive layerAircraft Engineering and Aerospace Technology, 91
-
Nicole Dias, B. Arribas, P. Gordo, T. Sousa, João Marinho, R. Melício, A. Amorim, P. Michel, Neo-Mapp Team (2021)
HERA Mission LIDAR Altimeter ImplementationIOP Conference Series: Materials Science and Engineering, 1024
-
Luis Ramos-Lzquierdo, V. Scott, S. Schmidt, Jamie Britt, W. Mamakos, R. Trunzo, J. Cavanaugh, Roger Miller (2005)
Optical system design and integration of the mercury laser altimeter.Applied optics, 44 9
- Publisher
- Emerald Publishing
- Copyright
- © Emerald Publishing Limited
- ISSN
- 1748-8842
- eISSN
- 1748-8842
- DOI
- 10.1108/aeat-12-2020-0300
- Publisher site
- See Article on Publisher Site
Abstract
This paper aims to report the first iteration on the Light Detection and Ranging (LIDAR) Engineering Model altimeter named HELENA. HELENA is a Time of Flight (TOF) altimeter that provides time-tagged distances and velocity measurements. The LIDAR can be used for support near asteroid navigation and provides scientific information. The HELENA design comprises two types of technologies: a microchip laser and low noise sensor. The synergies between these two technologies enable developing a compact instrument for range measurements of up to 14 km. Thermal-mechanical and radiometric simulations of the HELENA telescope are reported in this paper. The design is subjected to vibrational, static and thermal conditions, and it was possible to conclude by the results that the telescope is compliant with the random vibration levels, the static load and the operating temperatures.Design/methodology/approachThe Asteroid Impact & Deflection Assessment (AIDA) is a collaboration between the NASA DART mission and ESA Hera mission. The aim scope is to study the asteroid deflection through a kinetic collision. DART spacecraft will collide with Didymos-B, while ground stations monitor the orbit change. HERA spacecraft will study the post-impact scenario. The HERA spacecraft is composed by a main spacecraft and two small CubeSats. HERA will monitor the asteroid through cameras, radar, satellite-to-satellite doppler tracking, LIDAR, seismometry and gravimetry.FindingsThe HELENA design comprises two types of technologies: a microchip laser and low noise sensor. The synergies between these two technologies enable developing a compact instrument for range measurements of up to 14 km.Originality/valueIn this paper is reported the first iteration on the LIDAR Engineering Model altimeter named HELENA. HELENA is a TOF altimeter that provides time-tagged distances and velocity measurements. The LIDAR can be used for support near asteroid navigation and provides scientific information. The HELENA design comprises two types of technologies: a microchip laser and low noise sensor. The synergies between these two technologies enable developing a compact instrument for range measurements of up to 14 km.
Journal
Aircraft Engineering and Aerospace Technology: An International Journal – Emerald Publishing
Published: Aug 12, 2021
Keywords: LIDAR; Aerospace; Dydimos asteroid; HERA mission; Opto-mechanical design