Internet of Things in Space: A Review of Opportunities and Challenges from Satellite-Aided Computing to Digitally-Enhanced Space Living (2109.05971v1)

Abstract: Recent scientific and technological advancements driven by the Internet of Things (IoT), Machine Learning (ML) and AI, distributed computing and data communication technologies have opened up a vast range of opportunities in many scientific fields - spanning from fast, reliable and efficient data communication to large-scale cloud/edge computing and intelligent big data analytics. Technological innovations and developments in these areas have also enabled many opportunities in the space industry. The successful Mars landing of NASA's Perseverance rover on February 18, 2021 represents another giant leap for mankind in space exploration. Emerging research and developments of connectivity and computing technologies in IoT for space/non-terrestrial environments is expected to yield significant benefits in the near future. This survey paper presents a broad overview of the area and provides a look-ahead of the opportunities made possible by IoT and space-based technologies. We first survey the current developments of IoT and space industry, and identify key challenges and opportunities in these areas. We then review the state-of-the-art and discuss future opportunities for IoT developments, deployment and integration to support future endeavours in space exploration.

Internet of Things in Space: Integrating Terrestrial and Non-Terrestrial Networks

The paper explores the intersection of the Internet of Things (IoT) with satellite communications in the context of space exploration, offering a comprehensive overview of current technological advancements and potential future developments. It examines the integration of IoT technologies with satellite networks, recognizing the unique challenges and opportunities presented by space environments.

The authors begin by surveying the current landscape, focusing on IoT's application areas across terrestrial and non-terrestrial networks, including inter-planetary communications. IoT's integration into satellite communications, although promising, presents technical challenges related to latency, data transmission protocols, and efficient resource management. The challenges are amplified when IoT protocols originally designed for terrestrial applications are applied to satellite communications, necessitating modifications for efficient operations.

Current implementations of IoT in space include satellite-aided backhaul connectivity, particularly in remote environments where terrestrial infrastructure is limited. While satellite communications traditionally support delay-tolerant applications, future developments aim to support delay-sensitive applications that rely on ultra-reliable, low-latency communications, such as autonomous vehicles and industrial automation.

The paper details the emerging role of 5G (and 6G) networks in supporting satellite-based IoT services. These technologies promise substantial improvements in bandwidth, latency, and reliability, fostering advancements in integrating ground-based, aerial, and satellite networks. Such integration is anticipated to support diverse, emerging applications, including smart cities and environmental monitoring, enabled by the expansive reach of non-geosynchronous satellites like LEO and CubeSats.

Several architectural frameworks are discussed, including the Heterogeneous Space and Terrestrial Integrated Networks (H-STIN) framework, which leverages SDN and NFV for dynamic network management. The integration of CubeSats with SDN technologies is also highlighted as a cost-effective initiative for expanding IoT's reach into remote and underserved areas.

In terms of future developments, the paper speculates on the implications of smart architecture, space data centers, robotic automation in space construction, and automated space vehicles. These applications denote an increasing trend towards the complete automation of space operations to support human endeavors in extraterrestrial environments. The potential for interconnected automated systems and smart infrastructures presents an opportunity to extend and redefine human presence in space.

The implications of these technologies are expansive. They pave the way for fundamental advancements in satellite communications, with anticipated reductions in size, power consumption, and costs. The paper suggests ongoing research and innovation as critical to overcoming current limitations and realizing the potential of a fully integrated IoT in space. Future space systems will likely be characterized by decentralized and distributed processing and storage capabilities, interplanetary communications, and seamless integration across heterogeneous networks.

The research opens future avenues in the domain of space exploration supported by IoT, indicating a shift towards smarter, more resilient networks capable of supporting a wide array of applications beyond terrestrial confines. This integration is poised to transform sectors such as telecommunications, space tourism, scientific experimentation, and inter-planetary habitation, underpinned by robust IoT frameworks adapted for space environments.