Litcius/Paper detail

Challenges and Opportunities in Free Space Optical Satellite Communication

M.C. Cardakli

2025Journal of Lightwave Technology6 citationsDOI

Abstract

This paper presents a comprehensive analysis of the challenges and emerging opportunities in free-space optical (FSO) satellite communications, with a focus on low Earth orbit (LEO) constellations. A scalable architecture is proposed, leveraging coherent optical inter-satellite links (OISLs), high-photon efficiency (HPE) modulation formats, and digital beam combining (DBC), all enabled by purpose-built, space-optimized digital signal processors (DSPs). These DSPs address key system bottlenecks— including LEO-to-ground and OISL feeder links—by supporting rapid link acquisition, Doppler resilience, seamless rate adaptation, and real-time coherent combining across distributed receivers. Coherent DBC significantly reduces latency by mitigating physical-layer disruptions without relying on traditional recovery mechanisms such as automatic repeat request (ARQ) or deep interleaving. In parallel, space-optimized DSPs improve system scalability by minimizing size, weight, power, cost, and cooling (SWaP-C<sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup>), enabling each satellite to support more traffic and denser mesh deployments. The paper also examines the viability of 25G ZR+ coherent links as a pragmatic intermediate standard for inter-orbital communication and examines the role of high altitude platform systems (HAPS) in enabling reliable, high throughput optical relay paths above adverse atmospheric conditions. Furthermore, the integration of alternative positioning, navigation, and timing (ALT-PNT) capabilities is explored to support synchronization, autonomy, and distributed sensing. The feasibility of commercial off-the-shelf (COTS) hardware is also evaluated in the context of space qualification and thermal constraints. Collectively, these innovations establish a roadmap for resilient, low-latency, and interoperable optical satellite networks supporting next-generation broadband, Earth observation, and deep-space applications.

Topics & Concepts

Computer scienceScalabilityInteroperabilityCommunications satelliteContext (archaeology)Free-space optical communicationSatelliteDigital signal processingKey (lock)Electronic engineeringOptical communicationRelayLow latency (capital markets)PhotonicsOptical Transport NetworkOptical linkGeostationary orbitSpace technologyThroughputAsynchronous Transfer ModeSignal processingComputer architectureOptical performance monitoringPassive optical networkModulation (music)Earth observationOptical engineeringCloud computingAsynchronous communicationTelecommunicationsFrequency-division multiplexingDeep space explorationOrthogonal frequency-division multiplexingNASA Deep Space NetworkLink budgetOptical networkingUpgradeSatellite Communication SystemsOptical Wireless Communication TechnologiesSpacecraft Design and Technology