HERA Mission LIDAR Altimeter Implementation

Dias, Nicole G.; Arribas, Beltran N.; Gordo, Paulo; Sousa, Tiago; Marinho, João; Melício, Rui; Amorim, A.; Michel, Patrick; Team, Neo-Mapp

doi:10.1088/1757-899x/1024/1/012112

Cited by 6 publications

(12 citation statements)

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“…The emitter has a microchip laser that emits pulses of light at 1535 nm, with a pulse energy of 100 μJ and a pulse width of 2 ns. The radiometric model of this instrument was discussed in [8,9], where the link equation is used to calculate the received pulse energy, which depends on the transmitted laser pulse energy, the emitter and receiver transmittance, the asteroid reflectance, the geometry of the receiver telescope, the distance between LIDAR and the target and the overlap between the emitter and receiver. This equation is important to calculate the critical parameters required for the LIDAR receiver aperture.…”

Section: Figure 1 Lidar Receiver Telescope Optical Design (Zemax)mentioning

confidence: 99%

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HERA Mission LIDAR Mechanical and Optical Design

Dias

Arribas

Gordo

et al. 2022

IOP Conf. Ser.: Mater. Sci. Eng.

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Near-Earth Objects (NEO) are the topic of several research studies, with objects smaller than 1km in size posing the most threats and being the less understood of this scientific domain. The Asteroid Impact and Deflection Assessment (AIDA) mission involves NASA and ESA with the main mission goal to perform and analyze the asteroid deflection using the Kinetic Impactor technique. The mission target is Didymos-B, a moon of a binary asteroid called Didymos. NASA oversees the Double Asteroid Redirection Test (DART probe), and ESA is responsible for HERA probe, that will measure the Dydimos-B deflection caused by the impact. The Light Detection and Ranging (LIDAR), the Radar, the Satellite-to-Satellite Doppler tracking, the Seismometer, and the Gravimeter are instruments integrated into HERA spacecraft. Information synergy between the instruments allows the detailed characterization of the asteroid including internal structure. This experiment allows further understanding and will provide important information to improve the current NEO understanding and modelling. In this paper, scientific advances related to the LIDAR instrument are reported, including the innovative optomechanical design resulting from thermal and mechanical optimizations. The LIDAR has a compact design and needs to withstand extreme conditions, such as radiative and thermal conditions, without compromise its high accuracy measurements. The LIDAR is a time-of-flight altimeter instrument that will measure the distances from the HERA spacecraft to the target. It provides information for a 3D topographic mapping and calculates the asteroid reflectivity. The measurements are to be performed at a distance from 500 m to 14 km while operations such as fly byes or landings remain a possibility.

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Section: Figure 1 Lidar Receiver Telescope Optical Design (Zemax)mentioning

confidence: 99%

“…The HERA LIDAR is a compact instrument with an overall mass of less than 2 kg. The engineering model of the LIDAR, called HELENA, was addressed in [8,9]. The lessons learned from HELENA demonstrated that it is helpful to optimize the thermal and mechanical design of the LIDAR flight model (PALT).…”

Section: Thermo-mechanical Designmentioning

confidence: 99%

HERA Mission LIDAR Mechanical and Optical Design

Dias

Arribas

Gordo

et al. 2022

IOP Conf. Ser.: Mater. Sci. Eng.

Self Cite

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“…The Planetary ALTimeter (PALT) mechanical design has been optimized on different aspects to meet the requirements established for the HERA mission. In [6][7][8], the HELENA LIDAR's performance was evaluated regarding weaker requirement of shock, static simulation of 5G in two different directions, and thermal conductive simulations between −40 C. The main objective was to study the secondary mirror deformation towards the base of the telescope, and maximum stresses. Two different materials (aluminum and titanium) were assessed for the upper part of the LIDAR telescope.…”

Section: Previous Researchmentioning

confidence: 99%

“…The design was iterated several times, with the focus being on the initial design and a final design. The first design of the isostatic bipod mounts was presented in HELENA [6,7], which was the starting point of the isostatic bipod mount for PALT. This first design is depicted in Figure 2.…”

Section: Designmentioning

confidence: 99%

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Analysis on the Isostatic Bipod Mounts for the HERA Mission LIDAR

Dias

Gordo

Onderwater³

et al. 2022

Applied Sciences

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The Light Detection and Ranging (LIDAR) is a time-of-flight altimeter instrument being developed for the HERA mission, designated as Planetary ALTimeter (PALT). PALT is positioned in the center of the top face of the HERA probe, and therefore, it cannot use radiators to stabilize its internal temperature. The contribution of this paper is the design of isostatic bipod mounts for the LIDAR primary mirror. The performance of PALT must be maintained over a wide operational range, from −60 °C to 80 °C. These temperature requirements imply that a careful isostatic mount structure design is critical to maintaining performance in all operational scenarios. The purpose of the instrument is to perform range measurements from 500 m to 14 km. The instrument will contribute to the detailed characterization of the asteroid’s topography, assist the probe navigation in operations such as fly-bys (including on the dark side of the asteroid) or landing. PALT has an emitter system that generates 2 ns, 100 µJ, 1535 nm laser pulses and a receiver system that collects the backscattered signal from the asteroid. The receiver system is composed of a 70 mm diameter Cassegrain telescope and a refractive system that focuses the signal on the sensor.

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