Your search keyword '"Melograna, Catrina"' showing total 6 results

1. The need to improve registration practices in the context of space traffic management

Author

Masson-Zwaan, Tanja, Martinez, Peter, Letizia, Francesca, Melograna, Catrina, Reynders, Martin, Rovetto, Robert, Skinner, Mark A., Stanciu-Manolescu, Marius, Strah, Maruska, Volynskaya, Olga, and Wang, Guoyu

Published

2024

2. Applications And Potentials Of Intelligent Swarms For Magnetospheric Studies

Author

Rajan, Raj Thilak, Ben-Maor, Shoshana, Kaderali, Shaziana, Turner, Calum, Milhim, Mohammed, Melograna, Catrina, Haken, Dawn, Paul, Gary, Vedant, V, Sreekumar, Weppler, Johannes, Gumulya, Yosephine, Bunt, Riccardo, Bulgarini, Asia, Marnat, Maurice, Bussov, Kadri, Pringle, Frederick, Ma, Jusha, Amrutkar, Rushanka, Coto, Miguel, He, Jiang, Shi, Zijian, Hayder, Shahd, Jaber, Dina Saad Fayez, Zuo, Junchao, Alsukour, Mohammad, Renaud, Cecile, Christie, Matthew, Engad, Neta, Lian, Yu, Wen, Jie, McAvinia, Ruth, Simon-Butler, Andrew, Nguyen, Anh, and Cohen, Jacob

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Electrical Engineering and Systems Science - Systems and Control

Abstract

Earth's magnetosphere is vital for today's technologically dependent society. To date, numerous design studies have been conducted and over a dozen science missions have own to study the magnetosphere. However, a majority of these solutions relied on large monolithic satellites, which limited the spatial resolution of these investigations, as did the technological limitations of the past. To counter these limitations, we propose the use of a satellite swarm carrying numerous and distributed payloads for magnetospheric measurements. Our mission is named APIS (Applications and Potentials of Intelligent Swarms), which aims to characterize fundamental plasma processes in the Earth's magnetosphere and measure the effect of the solar wind on our magnetosphere. We propose a swarm of 40 CubeSats in two highly-elliptical orbits around the Earth, which perform radio tomography in the magnetotail at 8-12 Earth Radii (RE) downstream, and the subsolar magnetosphere at 8-12RE upstream. In addition, in-situ measurements of the magnetic and electric fields, plasma density will be performed by on-board instruments. In this article, we present an outline of previous missions and designs for magnetospheric studies, along with the science drivers and motivation for the APIS mission. Furthermore, preliminary design results are included to show the feasibility of such a mission. The science requirements drive the APIS mission design, the mission operation and the system requirements. In addition to the various science payloads, critical subsystems of the satellites are investigated e.g., navigation, communication, processing and power systems. We summarize our findings, along with the potential next steps to strengthen our design study., Comment: Accepted in Acta Astronautica

Published

2021

3. Applications and Potentials of Intelligent Swarms for magnetospheric studies

Author

Rajan, Raj Thilak, Ben-Maor, Shoshana, Kaderali, Shaziana, Turner, Calum, Milhim, Mohammed, Melograna, Catrina, Haken, Dawn, Paul, Gary, Vedant, Sreekumar, V., Weppler, Johannes, Gumulya, Yosephine, Bunt, Riccardo, Bulgarini, Asia, Marnat, Maurice, Bussov, Kadri, Pringle, Frederick, Ma, Jusha, Amrutkar, Rushanka, Coto, Miguel, He, Jiang, Shi, Zijian, Hayder, Shahd, Jaber, Dina Saad Fayez, Zuo, Junchao, Alsukour, Mohammad, Renaud, Cécile, Christie, Matthew, Engad, Neta, Lian, Yu, Wen, Jie, McAvinia, Ruth, Simon-Butler, Andrew, Nguyen, Anh, and Cohen, Jacob

Published

2022

4. Space for Challenges: NASA’s Protest Process Makes Procurement Fairer and More Transparent

Author

A. Melograna, Catrina, primary

Published

2022

5. APIS: Applications and Potentials of Intelligent Swarms for magnetospheric studies

Author

Rajan, R.T., Ben-Maor, Shoshana, Kaderali, Shaziana, Turner, Calum, Haken, Dawn, Vedant, Gary Paul, Melograna, Catrina, Salmeri, Antonino, and Cohen, Jacob

Subjects

Low earth orbit, Cubesats, Satellite swarms, Physics::Space Physics, Autonomous agents, Space technology, Astrophysics::Earth and Planetary Astrophysics, Heliophysics

Abstract

Earth's magnetosphere is vital for today's technologically dependent society. The energy transferred from the solar wind to the magnetosphere triggers electromagnetic storms on Earth, knocking out power grids and infrastructure - e.g., communication and navigation systems. Despite occurring on our astrophysical doorstep, numerous physical processes connecting the solar wind and our magnetosphere remain poorly understood. To date, over a dozen science missions have flown to study the magnetosphere, and many more design studies have been conducted. However, the majority of these solutions relied on large monolithic satellites, which limited the spatial resolution of these investigations, in addition to the technological limitations of the past. To counter these limitations, we propose the use of a satellite swarm, carrying numerous payloads for magnetospheric measurements. Our mission is named APIS - Applications and Potentials of Intelligent Swarms. The APIS mission aims to characterize fundamental plasma processes in the magnetosphere and measure the effect of the solar wind on our magnetosphere. We propose a swarm of 40 CubeSats in two highly-elliptical orbits around the Earth, which perform radio tomography in the magnetotail at 8-12 Earth Radii (R E) downstream, and the subsolar magnetosphere at 8-12 R E upstream. These maps will be made at both low-resolutions (at 0.5 R E, 5 seconds cadence) and high-resolutions (at 0.025 R E, 2 seconds cadence). In addition, in-situ measurements of the magnetic and electric fields, and plasma density will be performed by on-board instruments. In this publication, we present a design study of the APIS mission, which includes the mission design, navigation, communication, processing, power systems, propulsion and other critical satellite subsystems. The science requirements of the APIS mission levy stringent system requirements, which are addressed using Commercial Off-the-Shelf (COTS) technologies. We show the feasibility of the APIS mission using COTS technologies using preliminary link, power, and mass budgets. In addition to the technological study, we also investigated the legal considerations of the APIS mission. The APIS mission design study was part of the International Space University Space Studies Program in 2019 (ISU-SSP19) Next Generation Space Systems: Swarms Team Project. The authors of this publication are the participants of this 9-week project, in addition to the Chairs and Support staff.

Published

2020

6. APIS: Applications and Potentials of Intelligent Swarms for magnetospheric studies

Author

Rajan, R.T. (author), Ben-Maor, Shoshana (author), Kaderali, Shaziana (author), Turner, Calum (author), Haken, Dawn (author), Vedant, Gary Paul (author), Melograna, Catrina (author), Salmeri, Antonino (author), Cohen, Jacob (author), Rajan, R.T. (author), Ben-Maor, Shoshana (author), Kaderali, Shaziana (author), Turner, Calum (author), Haken, Dawn (author), Vedant, Gary Paul (author), Melograna, Catrina (author), Salmeri, Antonino (author), and Cohen, Jacob (author)

Abstract

Earth's magnetosphere is vital for today's technologically dependent society. The energy transferred from the solar wind to the magnetosphere triggers electromagnetic storms on Earth, knocking out power grids and infrastructure - e.g., communication and navigation systems. Despite occurring on our astrophysical doorstep, numerous physical processes connecting the solar wind and our magnetosphere remain poorly understood. To date, over a dozen science missions have flown to study the magnetosphere, and many more design studies have been conducted. However, the majority of these solutions relied on large monolithic satellites, which limited the spatial resolution of these investigations, in addition to the technological limitations of the past. To counter these limitations, we propose the use of a satellite swarm, carrying numerous payloads for magnetospheric measurements. Our mission is named APIS - Applications and Potentials of Intelligent Swarms. The APIS mission aims to characterize fundamental plasma processes in the magnetosphere and measure the effect of the solar wind on our magnetosphere. We propose a swarm of 40 CubeSats in two highly-elliptical orbits around the Earth, which perform radio tomography in the magnetotail at 8-12 Earth Radii (R E) downstream, and the subsolar magnetosphere at 8-12 R E upstream. These maps will be made at both low-resolutions (at 0.5 R E, 5 seconds cadence) and high-resolutions (at 0.025 R E, 2 seconds cadence). In addition, in-situ measurements of the magnetic and electric fields, and plasma density will be performed by on-board instruments. In this publication, we present a design study of the APIS mission, which includes the mission design, navigation, communication, processing, power systems, propulsion and other critical satellite subsystems. The science requirements of the APIS mission levy stringent system requirements, which are addressed using Commercial Off-the-Shelf (COT, Electronics

Published

2020