Muon Space Partners with Starlink to Equip Halo Satellites with Mini Laser Terminals

Muon Space Partners with Starlink to Equip Halo Satellites with Mini Laser Terminals

Muon Space, a leading end-to-end space systems provider specializing in mission-optimized satellite constellations, announced an agreement with SpaceX's Starlink to integrate its mini laser terminals into Muon's high-performance Halo satellite platform.

Starlink's mini lasers are designed to achieve link speeds of 25 Gbps at distances up to 4,000 km (and are capable of higher link speeds at shorter distances). By connecting to Starlink's global satellite network, Muon will provide customers with persistent, real-time access to their satellite constellations and data on orbit, eliminating the latency associated with traditional ground networks and enabling real-time tasking, payload operations and ultra-high bandwidth data streaming to any location on Earth. This agreement integrates Muon's satellites into Starlink's global digital infrastructure, delivering critical insights and services, and opening new business models where constellations operate with the same Internet speed and responsiveness as cloud providers and telecom networks on the ground.

"This is a sea change in how space systems operate," said Pascal Stang, CTO of Muon Space. "With persistent optical broadband, Muon Halo satellites will move from being isolated vehicles to becoming active, real-time nodes on Starlink's global network. That shift transforms how missions are designed and how fast insights flow to decision-makers on Earth."

"High-speed, low-latency connectivity on orbit is foundational for modern space missions," said Michael Nicolls, VP of Starlink Engineering at SpaceX. "By integrating Starlink mini lasers, Muon's spacecraft can remain persistently connected through our in-space laser mesh, enabling real-time tasking, continuous command-and-control, and immediate data delivery to terrestrial points of presence. We're excited to support Muon Space as they bring these capabilities to commercial missions."

Built from the ground up as fully integrated network-connected platforms, Muon's Halo satellites now extend that design globally, ushering in a new era where spacecraft operate as always-on, high-performance nodes in a worldwide data ecosystem.

From intermittent downlinks to persistent connectivity: Traditional ground station architectures provide brief contact windows; Starlink's mini lasers can be easily installed into Muon Halo spacecraft, creating near-continuous connectivity by routing traffic through SpaceX's in-orbit optical network to terrestrial Points of Presence (PoPs).

High throughput:  Each terminal supports an optical link up to 25 Gbps at link distances of up to 4,000 km, with latency from orbit to the ground measured in milliseconds.

Data center–class pipelines:  With persistent 25 Gbps backhaul, spacecraft can continuously stream to terrestrial Points of Presence and cloud environments while running in-orbit edge processing, enabling near-real-time data fusion, AI inference, product generation, and closed-loop tasking – turning each satellite into an extension of a distributed data center.

Resilience and uptime: A single terminal delivers high availability with brief handover interruptions ("hops") as the link transitions between relay satellites. Multi-terminal configurations enable "make-before-break" handovers, resulting in greater than 99% uptime and availability in typical LEO operations.

Security by design:  User traffic traverses Starlink's satellite network in encrypted, mutually-authenticated tunnels, with hardware-anchored keys and customer-controlled end-to-end encryption layered on top.

Muon-built missions like Earth Fire Alliance's FireSat constellation for wildfire detection and monitoring will be supercharged by the real-time high-bandwidth communications that Starlink provides. Incorporating mini lasers into future FireSats further enhances the global impact of this constellation on the growing wildfire and land management challenges around the world. This high-speed connectivity would cut FireSat data latency from an average of 20 minutes to near real-time. Incident commanders and first responders will receive near instant alerts of new ignitions – enabling rapid mobilization while fires are still small – and continuous updates on evolving perimeters and threatened communities throughout each fire's lifecycle.

"FireSat is already a game-changer for global wildfire response in terms of resolution, precision, and revisit," said Brian Collins, Executive Director of Earth Fire Alliance. "Starlink's optical connectivity offers the potential to further reduce our data delivery timeline, providing end users with the immediate information necessary to act while fires are at their earliest stages, ultimately preventing more large, disaster-scale fires."

"Our customers have been clear – their increasing operational needs require near real-time access to their spacecraft and payloads for tasking, compute, and data transfer," said Greg Smirin, President of Muon Space. "With Starlink's mini lasers integrated natively into Muon's flight-proven Halo platform, we're able to turn real-time connectivity from aspiration into practice across time-critical missions."

Deployment Timeline: Muon has begun integrating Starlink's mini laser terminals into current customer constellations and will be launching its first Starlink-enabled Halo satellite in Q1 2027.

Full-Stack Advantage: Muon's vertically integrated Halo technology stack – including the MuSat XL (≈500 kg-class) platform with high-precision pointing and ample payload capacity – streamlines payload integration and leverages Starlink's optical broadband for rapid data movement and in-space compute. Together, the stack delivers adaptable payload hosting, accelerated time-to-orbit, and next-generation networking performance.

Click here to know more about Muon Space's Constellation Stacks

Publisher: SatNow
Tags:-  SatelliteLEOGround

SpaceX

  • Country: United States
More news from SpaceX

GNSS Constellations - A list of all GNSS satellites by constellations

beidou

Satellite NameOrbit Date
BeiDou-3 G4Geostationary Orbit (GEO)17 May, 2023
BeiDou-3 G2Geostationary Orbit (GEO)09 Mar, 2020
Compass-IGSO7Inclined Geosynchronous Orbit (IGSO)09 Feb, 2020
BeiDou-3 M19Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M20Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M21Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 M22Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 I3Inclined Geosynchronous Orbit (IGSO)04 Nov, 2019
BeiDou-3 M23Medium Earth Orbit (MEO)22 Sep, 2019
BeiDou-3 M24Medium Earth Orbit (MEO)22 Sep, 2019

galileo

Satellite NameOrbit Date
GSAT0223MEO - Near-Circular05 Dec, 2021
GSAT0224MEO - Near-Circular05 Dec, 2021
GSAT0219MEO - Near-Circular25 Jul, 2018
GSAT0220MEO - Near-Circular25 Jul, 2018
GSAT0221MEO - Near-Circular25 Jul, 2018
GSAT0222MEO - Near-Circular25 Jul, 2018
GSAT0215MEO - Near-Circular12 Dec, 2017
GSAT0216MEO - Near-Circular12 Dec, 2017
GSAT0217MEO - Near-Circular12 Dec, 2017
GSAT0218MEO - Near-Circular12 Dec, 2017

glonass

Satellite NameOrbit Date
Kosmos 2569--07 Aug, 2023
Kosmos 2564--28 Nov, 2022
Kosmos 2559--10 Oct, 2022
Kosmos 2557--07 Jul, 2022
Kosmos 2547--25 Oct, 2020
Kosmos 2545--16 Mar, 2020
Kosmos 2544--11 Dec, 2019
Kosmos 2534--27 May, 2019
Kosmos 2529--03 Nov, 2018
Kosmos 2527--16 Jun, 2018

gps

Satellite NameOrbit Date
Navstar 82Medium Earth Orbit19 Jan, 2023
Navstar 81Medium Earth Orbit17 Jun, 2021
Navstar 78Medium Earth Orbit22 Aug, 2019
Navstar 77Medium Earth Orbit23 Dec, 2018
Navstar 76Medium Earth Orbit05 Feb, 2016
Navstar 75Medium Earth Orbit31 Oct, 2015
Navstar 74Medium Earth Orbit15 Jul, 2015
Navstar 73Medium Earth Orbit25 Mar, 2015
Navstar 72Medium Earth Orbit29 Oct, 2014
Navstar 71Medium Earth Orbit02 Aug, 2014

irnss

Satellite NameOrbit Date
NVS-01Geostationary Orbit (GEO)29 May, 2023
IRNSS-1IInclined Geosynchronous Orbit (IGSO)12 Apr, 2018
IRNSS-1HSub Geosynchronous Transfer Orbit (Sub-GTO)31 Aug, 2017
IRNSS-1GGeostationary Orbit (GEO)28 Apr, 2016
IRNSS-1FGeostationary Orbit (GEO)10 Mar, 2016
IRNSS-1EGeosynchronous Orbit (IGSO)20 Jan, 2016
IRNSS-1DInclined Geosynchronous Orbit (IGSO)28 Mar, 2015
IRNSS-1CGeostationary Orbit (GEO)16 Oct, 2014
IRNSS-1BInclined Geosynchronous Orbit (IGSO)04 Apr, 2014
IRNSS-1AInclined Geosynchronous Orbit (IGSO)01 Jul, 2013
Advertisement