Secure CubeSat-to-CubeSat Communication using Quantum Key Distribution for Information Updates and Risk Alerts

[en] With the growing use of CubeSats for various applications, such as remote sensing, communication, and scientific research, the need for secure communication between them has become crucial. CubeSat to CubeSat communication is becoming increasingly important for maintaining the security and reliability of CubeSat missions in modern day. CubeSats often carry sensitive information that must be protected from unauthorized access or interception and hence vulnerable to physical and cyber-attacks that could compromise their security. In this paper, we propose a system for secure CubeSat-to-CubeSat communication using Quantum Key Distribution (QKD). It consists of a photon source, polarization manipulation device for quantum state preparation and photon detectors with the capability of quantum state measurement. This system could enable CubeSats to update each other in real-time on conditions and status, allowing for rapid response to potential risks. Apart from this, it also allows CubeSats to operate independently in space without relying on ground stations or other infrastructure for communication. In the method, the information to be shared is first encoded into binary signals, and then the sender CubeSat (Alice) generates a stream of single photons with binary codes represented by randomly chosen polarization states of photons and sends them to the receiver CubeSat (Bob). The receiver CubeSat measures the polarization of each photon and communicates its measurements back to Alice. Alice and Bob can then use the measurement results to establish a shared secret key. As the polarization state of a photon is inherently random, any attempt to eavesdrop on the communication will inevitably alter the state of the photons, which can be detected by Alice and Bob. By using this method, CubeSats in a network can exchange information securely and effectively, ensuring the reliability and stability of the CubeSat network.

Disciplines :

Aerospace & aeronautics engineering

Author, co-author :

DUBEY, Priyank ; University of Luxembourg

HEIN, Andreas ; University of Luxembourg > Interdisciplinary Centre for Security, Reliability and Trust (SNT) > SPASYS

External co-authors :

yes

Language :

English

Title :

Secure CubeSat-to-CubeSat Communication using Quantum Key Distribution for Information Updates and Risk Alerts

Publication date :

06 October 2023

Event name :

International Astronautical Congress

Event date :

2-6 October 2023

Main work title :

Proceedings of the International Astronautical Congress

Publisher :

International Astronautical Federation, Paris, France

Available on ORBilu :

since 22 November 2023

Statistics

Number of views

83 (5 by Unilu)

Number of downloads

111 (5 by Unilu)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

Bibliography

Wayne A Shiroma, Larry K Martin, Justin M Akagi, Jason T Akagi, Byron L Wolfe, Bryan A Fewell, and Aaron T Ohta. Cubesats: A bright future for nanosatellites. Central European Journal of Engineering, 1:9-15, 2011.
Ram Sarup Jakhu and Joseph N Pelton. Small satellites and their regulation. Springer, 2014.
Chantal Cappelletti and Daniel Robson. Cubesat missions and applications. In Cubesat Handbook, pages 53-65. Elsevier, 2021.
Thyrso Villela, Cesar A Costa, Alessandra M Brandão, Fernando T Bueno, Rodrigo Leonardi, et al. Towards the thousandth cubesat: A statistical overview. International Journal of Aerospace Engineering, 2019, 2019.
Zaid J Towfic, David Heckman, David Morabito, Ryan Rogalin, Clayton Okino, and Douglas S Abraham. Simulation and analysis of opportunistic mspa for multiple cubesat deployments. In 2018 SpaceOps Conference, page 2396, 2018.
Youngbum Song, Sang-Young Park, Geuk-Nam Kim, and Dong-Gu Kim. Design of orbit controls for a multiple cubesat mission using drift rate modulation. Aerospace, 8(11):323, 2021.
Giancarlo Santilli, Cristian Vendittozzi, Chantal Cappelletti, Simone Battistini, and Paolo Gessini. Cubesat constellations for disaster management in remote areas. Acta Astronautica, 145:11-17, 2018.
Pau Garcia Buzzi, Daniel Selva, Nozomi Hitomi, and William J Blackwell. Assessment of constellation designs for earth observation: Application to the tropics mission. Acta Astronautica, 161:166-182, 2019.
Shufan Wu, Wen Chen, Caixia Cao, Chuanxin Zhang, and Zhongcheng Mu. A multiple-cubesat constellation for integrated earth observation and marine/air traffic monitoring. Advances in Space Research, 67(11):3712-3724, 2021.
Sijing Ji, Min Sheng, Di Zhou, Weigang Bai, Qixuan Cao, and Jiandong Li. Flexible and distributed mobility management for integrated terrestrial-satellite networks: challenges, architectures, and approaches. IEEE Network, 35(4):73-81, 2021.
Mauro De Sanctis, Ernestina Cianca, Giuseppe Araniti, Igor Bisio, and Ramjee Prasad. Satellite communications supporting internet of remote things. IEEE Internet of Things Journal, 3(1):113-123, 2015.
Gregory Falco. Job one for space force: Space asset cybersecurity. Belfer Center, Harvard Kennedy School, Belfer Center for Science and International Affairs, Harvard Kennedy School, 79, 2018.
KW Ingols, RW Skowyra, and MIT Lincoln Laboratory Lexington United States. Guidelines for secure small satellite design and implementation: Fy18 cyber security line-supported program. AD1099003, 2019.
Chronis Kapalidis, Carsten Maple, Matthew Bradbury, Marie Farrell, and Michael Fisher. Cyber risk management in satellite systems. 2019.
Jasminder S Sidhu, Siddarth K Joshi, Mustafa Gündoğan, Thomas Brougham, David Lowndes, Luca Mazzarella, Markus Krutzik, Sonali Mohapatra, Daniele Dequal, Giuseppe Vallone, et al. Advances in space quantum communications. IET Quantum Communication, 2(4):182-217, 2021.
Ryszard Horodecki, Paweł Horodecki, Michał Horodecki, and Karol Horodecki. Quantum entanglement. Reviews of modern physics, 81(2):865, 2009.
Valerio Scarani, Helle Bechmann-Pasquinucci, Nicolas J Cerf, Miloslav Dušek, Norbert Lütkenhaus, and Momtchil Peev. The security of practical quantum key distribution. Reviews of modern physics, 81(3):1301, 2009.
Robert Bedington, Juan Miguel Arrazola, and Alexander Ling. Progress in satellite quantum key distribution. npj Quantum Information, 3(1):30, 2017.
Robert Bedington, Xueliang Bai, Edward Truong-Cao, Yue Chuan Tan, Kadir Durak, Aitor Villar Zafra, James A Grieve, Daniel KL Oi, and Alexander Ling. Nanosatellite experiments to enable future space-based qkd missions. EPJ Quantum Technology, 3(1):1-10, 2016.
Yu-Ao Chen, Qiang Zhang, Teng-Yun Chen, Wen-Qi Cai, Sheng-Kai Liao, Jun Zhang, Kai Chen, Juan Yin, Ji-Gang Ren, Zhu Chen, et al. An integrated space-to-ground quantum communication network over 4, 600 kilometres. Nature, 589(7841):214-219, 2021.
Giuseppe Vallone, Vincenzo D'Ambrosio, Anna Sponselli, Sergei Slussarenko, Lorenzo Marrucci, Fabio Sciarrino, and Paolo Villoresi. Free-space quantum key distribution by rotation-invariant twisted photons. Physical review letters, 113(6):060503, 2014.
Mateusz Polnik, Luca Mazzarella, Marilena Di Carlo, Daniel KL Oi, Annalisa Riccardi, and Ashwin Arulselvan. Scheduling of space to ground quantum key distribution. EPJ Quantum Technology, 7(1):3, 2020.
Roland Haber, Daniel Garbe, Klaus Schilling, and Wenjamin Rosenfeld. Qube-a cubesat for quantum key distribution experiments. 2018.
James A Grieve, Robert Bedington, Zhongkan Tang, Rakhitha CMRB Chandrasekara, and Alexander Ling. Spooqysats: Cubesats to demonstrate quantum key distribution technologies. Acta Astronautica, 151:103-106, 2018.
Luca Mazzarella, Christopher Lowe, David Lowndes, Siddarth Koduru Joshi, Steve Greenland, Doug McNeil, Cassandra Mercury, Malcolm Macdonald, John Rarity, and Daniel Kuan Li Oi. Quarc: Quantum research cubesat-a constellation for quantum communication. Cryptography, 4(1):7, 2020.
Chithrabhanu Perumangatt, Tom Vergoossen, Alexander Lohrmann, Srihari Sivasankaran, Ayesha Reezwana, Ali Anwar, Subash Sachidananda, Tanvirul Islam, and Alexander Ling. Realizing quantum nodes in space for cost-effective, global quantum communication: in-orbit results and next steps. In Quantum Computing, Communication, and Simulation, volume 11699, page 1169904. SPIE, 2021.
Srihari Sivasankaran, Clarence Liu, Moritz Mihm, and Alexander Ling. A cubesat platform for space based quantum key distribution. In 2022 IEEE international conference on space optical systems and applications (ICSOS), pages 51-56. IEEE, 2022.
Alexander Lohrmann, Chithrabhanu Perumangatt, Aitor Villar, and Alexander Ling. Broadband pumped polarization entangled photon-pair source in a linear beam displacement interferometer. Applied Physics Letters, 116(2), 2020.
Yuan Lee, Eric Bersin, Axel Dahlberg, Stephanie Wehner, and Dirk Englund. A quantum router architecture for high-fidelity entanglement flows in quantum networks. npj Quantum Information, 8(1):75, 2022.
Thomas Schildknecht. Optical surveys for space debris. The Astronomy and Astrophysics Review, 14:41-111, 2007.
Gerard Vives Vallduriola, Diego Andrés Suárez Trujillo, Tim Helfers, Damien Daens, Jens Utzmann, Jean-Noel Pittet, and Nicolas Lièvre. The use of streak observations to detect space debris. International journal of remote sensing, 39(7):2066-2077, 2018.
Leonard Felicetti and M Reza Emami. A multi-spacecraft formation approach to space debris surveillance. Acta Astronautica, 127:491-504, 2016.
Abhilash Singh and Kumar Gaurav. Deep learning and data fusion to estimate surface soil moisture from multisensor satellite images. Scientific Reports, 13(1):2251, 2023.
Vanessa Brum-Bastos, Jed Long, Katharyn Church, Greg Robson, Rogério de Paula, and Urška Demšar. Multisource data fusion of optical satellite imagery to characterize habitat selection from wildlife tracking data. Ecological Informatics, 60:101149, 2020.
Sunita Jahirabadkar, Punam Pande, and R Aditya. A survey on image processing based techniques for space debris detection. In 2022 IEEE Bombay Section Signature Conference (IBSSC), pages 1-6. IEEE, 2022.
Leonard Felicetti and M. Reza Emami. Image-based attitude maneuvers for space debris tracking. Aerospace Science and Technology, 76:58-71, 2018.
Jorge Núñez, Anna Núñez, Francisco Javier Montojo, and Marta Condominas. Improving space debris detection in geo ring using image deconvolution. Advances in Space Research, 56(2):218-228, 2015.
P Hickson. A fast algorithm for the detection of faint orbital debris tracks in optical images. Advances in Space Research, 62(11):3078-3085, 2018.
Vincenzo Pesce, Roberto Opromolla, Salvatore Sarno, Michèle Lavagna, and Michele Grassi. Autonomous relative navigation around uncooperative spacecraft based on a single camera. Aerospace Science and Technology, 84:1070-1080, 2019.
Arunkumar Molayath and V Sanal Kumar. Studies on space debris tracking and elimination. In 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit, page 7008, 2010.
CR Phipps, G Albrecht, H Friedman, D Gavel, EV George, J Murray, Chunching Ho, W Priedhorsky, MM Michaelis, and JP Reilly. Orion: Clearing near-earth space debris using a 20-kw, 530-nm, earth-based, repetitively pulsed laser. Laser and particle beams, 14(1):1-44, 1996.
Oscar Rodriguez Fernandez, Jens Utzmann, and Urs Hugentobler. Spook-a comprehensive space surveillance and tracking analysis tool. Acta Astronautica, 158:178-184, 2019.
Mohamed Khalil Ben-Larbi, Kattia Flores Pozo, Tom Haylok, Mirue Choi, Benjamin Grzesik, Andreas Haas, Dominik Krupke, Harald Konstanski, Volker Schaus, Sándor P Fekete, et al. Towards the automated operations of large distributed satellite systems. part 1: Review and paradigm shifts. Advances in Space Research, 67(11):3598-3619, 2021.
Jukka Korpela. A tutorial on character code issues. Retrieved March, 14:2009, 2001.
Kuang Tsan Lin. Digital information encrypted in an image using binary encoding. Optics Communications, 281(13):3447-3453, 2008.
T Hwang, CC Hwang, and CW Tsai. Quantum key distribution protocol using dense coding of three-qubit w state. The European Physical Journal D, 61:785-790, 2011.
Ci-Hong Liao, Chun-Wei Yang, and Tzonelish Hwang. Dynamic quantum secret sharing protocol based on ghz state. Quantum information processing, 13:1907-1916, 2014.
Anindita Banerjee and Anirban Pathak. Maximally efficient protocols for direct secure quantum communication. Physics Letters A, 376(45):2944-2950, 2012.
Chitra Shukla, Anindita Banerjee, and Anirban Pathak. Improved protocols of secure quantum communication using w states. International Journal of theoretical physics, 52:1914-1924, 2013.
Chitra Shukla, Anirban Pathak, and R Srikanth. Beyond the goldenberg-vaidman protocol: secure and efficient quantum communication using arbitrary, orthogonal, multi-particle quantum states. International Journal of Quantum Information, 10(08):1241009, 2012.