Loading…

Optimized Design and Implementation of Digital Lock-In for Planetary Exploration Sensors

Exploring life conditions on the near-Earth planets and satellites before carrying out human missions is an important task for Space Agencies. For that purpose, scientific space missions usually include instruments to measure climatological variables. Within this space instrumentation and measuremen...

Full description

Saved in:
Bibliographic Details
Published in:IEEE sensors journal 2022-12, Vol.22 (23), p.1-1
Main Authors: Ramirez Barcenas, A., Paz Herrera, R., Miranda Calero, J.A., Canabal Benito, M.F., Garcia Ares, E., Russu, A., Cortes, F.C., De Castro, A.J., Lopez, F., Portela-Garcia, M., Lopez Ongil, C.
Format: Article
Language:English
Subjects:
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Exploring life conditions on the near-Earth planets and satellites before carrying out human missions is an important task for Space Agencies. For that purpose, scientific space missions usually include instruments to measure climatological variables. Within this space instrumentation and measurement context, dust sensors aim to measure dust particles in suspension, and provide valuable information for persons and equipment life conditions while they must deal with low signal-noise ratios (SNR). For example, Exomars mission is focused to characterize the weather on Mars surface and include up to four dust sensors, based on different technologies: infrared (IR), laser, interferometry, impact sensors and electric fields activity sensors. Due to the tight budget in terms of area, weight, power consumption and data budget in aerospace instruments, as well as ionizing radiation and extreme temperatures, current solutions present low scalability and configurability. In this paper, a novel system proposal that extracts valuable information from noisy signals obtained from InfraRed sensors aimed to measure airborne dust is presented. The solution provides competitive capabilities in terms of power consumption, data budget, SNR, and reconfigurability. It has been implemented in a rad-hard Microsemi® FPGA (RT54SX32S). Therefore, robustness and scalability are guaranteed. The results reported a maximum power consumption of up to 141 mA (@12Vdc), a sensitivity of 19.5 mV (input signal) and a data budget of 32B/s. This research possesses great potential to further instruments not only in planetary exploration but also at Earth applications.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2022.3213423