EGU2020-22374, updated on 12 Jun 2020
https://doi.org/10.5194/egusphere-egu2020-22374
EGU General Assembly 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Progress on the development of innovative, floating, biodegradable radio- probes for atmospheric monitoring inside warm clouds

Miryam Paredes2,3, Shahbozbek Abdunabiev1, Marco Allegretti2,3, Giovanni Perona3, Daniela Tordella1, Eros Pasero2, Flavio Canavero2, Andrea Merlone4, and Chiara Musacchio4
Miryam Paredes et al.
  • 1Department of Applied Science and Technology, Politecnico di Torino
  • 2Department of Electronics and Telecommunications, Politecnico di Torino
  • 3Envisens Technologies s.r.l.
  • 4Istituto Nazionale di Ricerca Metrologica di Torino

Characterization of clouds is still a challenging task for weather forecasting and climate modeling. This is because clouds depend on interdisciplinary natural processes, ranging from the micrometer scale, where particles and droplets collide, to the thousand-of-meters scale of airflow dynamics. Turbulence has an important role in cloud formation and rain initiation since it helps rain droplets to evolve through coalescence and collision processes. Unfortunately, the effects of turbulence mechanisms are not yet well understood and there remains a need for further clarification.

In an attempt to address these knowledge gaps, this work presents the advances of an experimental method for measuring in-situ the influence of turbulence in cloud formation and producing an infield cloud Lagrangian dataset by means of the development of ultra-light bio- compatible radio-probes. With a target weight of less than 20 grams, these innovative devices are carefully designed to float and passively track small-scale turbulence fluctuations in warm clouds and neighboring air. Each mini radio-probe embeds a set of compact size microprocessors, controllers and sensors for the measurement of atmospheric parameters inside clouds (e.g. velocity, acceleration, vorticity, pressure, temperature, humidity) after been released into the atmosphere. To reach a buoyancy force equal to the weight of the system, the bio balloons containing the electronics are appropriately filled with a mixture of helium gas and air. During the flight, the smart radio-probes acquire, pre-process, store, arrange and transmit the obtained data to different receiving and ground stations located on earth through a dedicated radio transmission link. Due to the radio-probes’ physical constrains and the environmental conditions that can be found inside warm clouds, a power-saving and long-range wireless communication technology has been selected and tested.

The development of the first operational prototypes for both, the radio-probes and the receiving stations, are presented together with results of the first measurement experiments both, in laboratory and field campaign.

How to cite: Paredes, M., Abdunabiev, S., Allegretti, M., Perona, G., Tordella, D., Pasero, E., Canavero, F., Merlone, A., and Musacchio, C.: Progress on the development of innovative, floating, biodegradable radio- probes for atmospheric monitoring inside warm clouds, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-22374, https://doi.org/10.5194/egusphere-egu2020-22374, 2020

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Presentation version 1 – uploaded on 04 May 2020
  • CC1: Similar solution 'Swarmsonde', Anders Petersson, 04 May 2020

    My company has developed a similar system, used for insitu analyzing of tornadic supercells:

    We are now developing the next version, shrinking the size from 12 to 8 grams. I will get in contact with you for possible cooperation.