Autonomous spaceport drone ship
An autonomous spaceport drone ship (ASDS) is an uncrewed ocean-going barge modified by SpaceX to function as a precision landing platform for the reusable first stage of its Falcon 9 rocket, enabling recoveries at sea when missions require high energy and downrange distances prevent onshore landings.[1] These vessels, derived from standard deck barges, feature a large flat deck marked with a prominent white "X" for guidance, along with GPS-based navigation systems and multiple azimuth thrusters that maintain positional accuracy within approximately 3 meters, even in challenging sea conditions.[2] The ASDS concept supports SpaceX's goal of rocket reusability by allowing boosters to be captured and returned to port for refurbishment and relaunch.[3] SpaceX began developing the ASDS in 2014 as part of its efforts to advance vertical rocket landings, with the first vessel deployed off the Florida coast in late 2014 and initial landing attempts occurring in early 2015 during the CRS-5 mission.[4] After several unsuccessful tries, the program achieved its milestone first successful booster landing on an ASDS on April 8, 2016, during the CRS-8 resupply mission to the International Space Station, when the drone ship Of Course I Still Love You captured the Falcon 9 first stage in the Atlantic Ocean.[5] Over the following years, SpaceX expanded and upgraded its fleet, incorporating enhancements such as reinforced blast walls, additional thrusters for stability, deluge systems for deck cooling, and robotic "Octagrabber" arms to secure landed boosters.[2] As of 2025, SpaceX operates a fleet of three active ASDS vessels, all named after artificial intelligence-controlled ships from Iain M. Banks' Culture science fiction series: Just Read the Instructions (based in Port Canaveral, Florida, for Atlantic operations), Of Course I Still Love You (based in the Port of Long Beach, California, for Pacific missions), and A Shortfall of Gravitas (also based in Port Canaveral).[6] Each measures approximately 90 meters (295 feet) in length and 46 meters (150 feet) in beam, powered by four diesel azimuth thrusters for station-keeping and towed by support tugboats to deployment zones 600–1,200 kilometers downrange from launch sites.[7] The drone ships have facilitated hundreds of recoveries, with SpaceX completing its 400th Falcon booster landing on an ASDS in August 2025, dramatically reducing launch costs through rapid reusability—some boosters have flown over 20 missions.[8]History
Origins and development
The concept of the Autonomous Spaceport Drone Ship (ASDS) emerged as a key component of SpaceX's reusable launch vehicle program, aimed at drastically lowering the cost of space access by enabling the recovery and refurbishment of rocket first stages. In 2009, SpaceX CEO Elon Musk first articulated the vision for sea-based recovery of rocket hardware, describing it as part of a "paradigm shift in the traditional approach for reusing rocket hardware" to achieve rapid turnaround and economic viability for orbital missions.[9] This early idea aligned with Musk's broader reusability goals, initially focused on vertical landings but evolving to include offshore platforms due to range safety and precision requirements for high-velocity returns. Development accelerated in 2014, with SpaceX privately funding the initiative as an extension of its internal research and development efforts into rocket recovery technologies, investing hundreds of millions alongside core Falcon 9 upgrades. The company selected unmodified ocean-going barges from the McDonough Marine Service's Marmac series for their robust construction and availability, leasing the Marmac 300 in late 2014 as the foundation for the first ASDS. Engineering teams addressed significant challenges in ocean stability, including wave-induced motion and wind forces, by integrating dynamic positioning systems with GPS-guided thrusters to maintain the platform within meters of a target location despite rough seas—essential for the narrow landing window of a descending booster.[2][10] The inaugural vessel, designated Just Read the Instructions (JRTI), underwent modifications at a Louisiana shipyard and was completed by December 2014, marking the program's transition from concept to operational hardware. Later that year, SpaceX acquired the Marmac 304 barge for a second ASDS, initiating outfitting that extended into early 2015 to support expanded recovery operations. Naming conventions drew inspiration from Iain M. Banks' Culture series of science fiction novels, with JRTI honoring a ship from the series; Musk publicly revealed these names in February 2015, establishing a tradition for the fleet.[11] The ASDS platforms were designed to integrate seamlessly with the Falcon 9's evolving reusability architecture, culminating in the Block 5 variant's enhanced landing legs and grid fins for reliable offshore recoveries starting in 2018.[12]Early tests and operational evolution
The inaugural deployment of an Autonomous Spaceport Drone Ship (ASDS) occurred on January 10, 2015, during the SpaceX CRS-5 mission launched from Cape Canaveral. The Falcon 9 first stage executed a boost-back burn and reached the deck of Just Read the Instructions (JRTI I) in the Atlantic Ocean, marking a partial success in demonstrating controlled descent to a moving platform; however, it landed hard at a 45-degree angle, tipping over and causing structural damage to the vessel's deck.[13] Following subsequent attempts during the CRS-6 mission in April 2015, where the booster reached the deck but failed due to an off-balance landing, and the CRS-7 mission in June 2015, which failed during ascent before any recovery could be attempted, the original Just Read the Instructions was retired in May 2015 after three deployments without a successful booster capture. To sustain operations, SpaceX introduced Of Course I Still Love You (OCISLY) in June 2015 as the new Atlantic-focused ASDS, converted from the barge Marmac 304. For Pacific operations, a second Just Read the Instructions (JRTI II), based on the barge Marmac 303, debuted in December 2015 during the Orbcomm OG2 Mission-2 from Vandenberg Air Force Base, achieving the first successful Falcon 9 first-stage landing on an ASDS.[2][14] To accommodate SpaceX's growing launch cadence, a third ASDS, A Shortfall of Gravitas (ASOG), converted from the barge Marmac 302, arrived at Port Canaveral on July 15, 2021, and entered service with its first booster recovery during the CRS-23 mission in August 2021. Post-2016, ASDS operations shifted primary emphasis to the Atlantic Ocean to align with the majority of Falcon 9 launches from Florida sites, reducing reliance on Pacific deployments for Vandenberg missions while maintaining dual-ocean capability. Iterative adaptations, including software enhancements for improved GPS-based navigation and thruster control, elevated landing success rates from under 10% in early tests to over 95% by 2018, enabling routine recoveries without vessel repositioning errors exceeding a few meters.[14][15] The surge in Falcon 9 launches—from 26 in 2020 to 134 in 2024 and 146 as of November 2025—intensified ASDS fleet utilization, with vessels often supporting multiple recoveries per week amid Starlink and commercial missions, yet the three-ship configuration proved sufficient without announcements of expansions by November 2025.[16][17]Technical specifications
Platform design and dimensions
Autonomous spaceport drone ships (ASDS) are constructed from modified deck barges of the Marmac 300 series, originally built for offshore oil field support by McDonough Marine Services. These vessels typically measure about 91 meters in length and 30 meters in beam, with structural wing extensions increasing the effective width to approximately 52 meters to accommodate the landing zone. The overall design leverages the inherent stability and load-bearing capacity of these flat-deck barges, which have a deck load capacity exceeding 2,000 long tons in their standard configuration. Key modifications to the base platforms include reinforcement of the deck structure to withstand the dynamic loads from rocket landings, supporting the dry mass of a Falcon 9 first stage booster, which is around 22 metric tons. The deck surface is treated with non-skid coatings to prevent slippage under high-heat conditions and ocean spray, while the central landing area is elevated slightly relative to the edges to better manage wave-induced motion and runoff. This landing pad spans roughly 90 by 50 meters and features a painted layout with concentric circles and converging lines for optical guidance during descent. To enhance stability in open ocean environments, ASDS platforms incorporate ballast tank systems that allow operators to adjust draft and trim, distributing weight for better balance in swells up to 3 meters. These systems also supply water for deck deluge during landings to mitigate heat damage from engine exhaust. Complementing this, the design supports dynamic positioning capabilities that enable station-keeping within 3 meters accuracy, even in moderate storm conditions. The platforms are engineered with corrosion-resistant materials and coatings to endure prolonged salt water exposure and harsh marine weather, permitting operations in sustained winds up to 20 knots. Integration with onboard navigation systems ensures the structural layout aligns with precision control requirements for autonomous operations.Navigation, propulsion, and control systems
The dynamic positioning system of the Autonomous Spaceport Drone Ship (ASDS) relies on GPS guidance to maintain precise station-keeping, achieving accuracy within 3 meters even under storm conditions through the use of redundant satellite signals for enhanced reliability.[18] This system, based on Thrustmaster’s Portable Dynamic Positioning System, enables the vessel to hold position autonomously at designated coordinates hundreds of miles offshore, compensating for ocean currents and winds.[19] Lateral positioning accuracy during booster landings has been reported at approximately 10 meters in early tests.[18] Propulsion is provided by four azimuth thrusters, each rated at 300 horsepower (220 kW) with 1-meter nozzles, arranged for omnidirectional maneuverability and powered by modular diesel-hydraulic power units.[2] These hydraulic outdrive units, manufactured by Thrustmaster, allow the ASDS to perform station-keeping and repositioning at low speeds suitable for offshore operations.[18] The setup includes modular diesel-hydraulic power units and six onboard generators to ensure continuous operation.[19] The control architecture features SpaceX-developed autonomous software integrated with the Falcon 9's guidance system, enabling real-time position adjustments via shared GPS coordinates for synchronized targeting during descent.[20] A dedicated DP Control Van oversees automated heading and position maintenance using hydraulic propulsion controls, with failover to telerobotic manual override available for redundancy.[19][18] The sensor suite includes radar and commercial off-the-shelf optical cameras, such as GoPro units, for obstacle detection, landing recording, and environmental monitoring to support swell compensation.[19][18] Post-2016 upgrades have included enhancements to propulsion and control for improved repositioning efficiency, alongside structural additions like blast shielding.[2]Fleet
Just Read the Instructions (I)
The original Autonomous Spaceport Drone Ship (ASDS), named Just Read the Instructions (I), served as the prototype for SpaceX's offshore rocket recovery program. Built upon the Marmac 300 barge, a 300-foot-long platform originally constructed in 1998 by Gulf Coast Fabrication for McDonough Marine Service, the vessel was acquired by SpaceX in November 2014 and modified with steel wing extensions to widen its deck to 170 feet.[2][21] Homeported at SpaceX's facility in Alameda, California, in the Pacific, it was towed eastward through the Panama Canal for initial Atlantic operations, marking the company's first dedicated effort to enable precision landings at sea for Falcon 9 first stages.[2][22] Its brief service history spanned early 2015, focusing on experimental booster recoveries rather than operational successes. During the SpaceX CRS-5 mission on January 10, 2015, the Falcon 9 first stage achieved a partial success by softly touching down on the deck approximately 200 miles east of the Carolina coast, though it subsequently tipped over due to uneven leg deployment, causing minor structural damage.[23][2] The second attempt came during the SpaceX CRS-6 mission on April 14, 2015, where the booster executed a hard landing with excessive lateral velocity, leading to it tipping over and breaking apart on impact; this failure, combined with subsequent exposure to rough seas including 3-story waves, inflicted significant damage to on-deck equipment and thrusters.[23][2] With no full recoveries achieved, the ship was retired in May 2015 after less than six months of active use, its duties transferred to a successor vessel.[2] Equipped with basic autonomous capabilities for its era, Just Read the Instructions (I) featured four diesel-powered, hydraulically driven azimuth thrusters repurposed from deep-sea oil rigs, enabling it to hold position within about 3 meters using pre-programmed GPS coordinates for guidance.[2] These systems, along with onboard cameras and sensors for recording landings, supported testing of booster descent profiles but lacked the advanced reinforcements seen in later designs.[2] Post-retirement, the damaged Marmac 300 barge was deemed unsuitable for further modification and was ultimately scrapped, having fulfilled its role primarily as a proof-of-concept platform.[2] The prototype's experiences directly informed enhancements in subsequent ASDS vessels, particularly in deck reinforcement to withstand booster impacts and wave-induced stresses, as well as improved thruster configurations and GPS accuracy for better station-keeping in adverse conditions.[2] For instance, its replacement incorporated vertical steel blast walls and additional bow thrusters to mitigate vulnerabilities exposed during the rough-sea incidents.[2] This legacy underscored the iterative engineering approach that enabled SpaceX's eventual routine offshore recoveries.Of Course I Still Love You
Of Course I Still Love You (OCISLY) is the first operational autonomous spaceport drone ship (ASDS) deployed by SpaceX for Falcon 9 first-stage booster recoveries. Built as a refit of the barge Marmac 304 in a Louisiana shipyard starting in early 2015, the vessel was commissioned in June 2015 and initially homeported at Port Canaveral, Florida, to support East Coast launch operations.[24][7] Following the introduction of A Shortfall of Gravitas in 2021, OCISLY was relocated to the West Coast and is now homeported at the Port of Long Beach, California, for Pacific missions.[7] The ship measures approximately 90 meters in length and 46 meters in width, providing a stable platform for precision landings approximately 600-700 kilometers downrange from launch sites.[7] Equipped with four azimuth thrusters for station-keeping and enhanced stability during recovery operations, OCISLY features a blackened landing deck marked with a central "X" symbol enclosed in concentric circles to aid visual guidance for descending boosters.[7][4] These navigation aids complement the ship's shared GPS and optical systems used across the ASDS fleet for autonomous positioning. The vessel supported Atlantic deployments until 2021 and now focuses on Pacific recoveries, primarily for launches from Vandenberg Space Force Base.[25] OCISLY achieved its first successful booster landing on April 8, 2016, during the Commercial Resupply Services-8 (CRS-8) mission, marking a milestone in offshore reusability efforts.[26] In 2018, the ship underwent upgrades to better accommodate the heavier Falcon 9 Block 5 boosters, including modifications to the deck and propulsion for improved handling of increased mass and thrust during landings.[27] By November 2025, OCISLY had facilitated 163 successful landings, primarily for West Coast launches deploying Starlink satellites and other payloads.[28] As of November 2025, OCISLY remains active in SpaceX's recovery fleet, continuing to enable routine booster recoveries for high-cadence operations.[28]Just Read the Instructions (II)
Just Read the Instructions (II), often abbreviated as JRTI II, serves as the second iteration of SpaceX's autonomous spaceport drone ship bearing that name, evolving from the original experimental vessel used for early Atlantic Ocean tests in 2015. Built on the modified ocean-going barge Marmac 303, it entered service in December 2015 and was initially stationed in the Pacific Ocean off the coast of Vandenberg Space Force Base in California to support launches from that site. In 2019, the vessel was relocated via the Panama Canal to the East Coast, arriving at Port Canaveral, Florida, by December to expand recovery operations for missions from Kennedy Space Center and Cape Canaveral Space Force Station.[29] The design of JRTI II closely mirrors that of its sister ship, Of Course I Still Love You (OCISLY), featuring a length of approximately 90 meters and reinforcements capable of handling payloads exceeding 30 tons, such as Falcon 9 first-stage boosters. It incorporates four azimuth thrusters for precise station-keeping, along with enhanced ballast systems optimized for stability during high-latitude recoveries associated with polar orbit missions from Vandenberg. These adaptations proved essential for operations in the Pacific, where launch trajectories often require downrange landings farther from shore.[30] JRTI II achieved its first booster landing on January 17, 2016, during the Jason-3 mission launched from Vandenberg, marking SpaceX's inaugural successful touchdown on a Pacific-based drone ship despite the booster later tipping over on the deck. By November 2025, the vessel had recorded 137 successful landings, playing a pivotal role in recoveries for National Reconnaissance Office (NRO) payloads and Starlink constellation deployments from the East Coast. Its unique contributions include facilitating high-latitude recoveries for polar missions, which demand greater positional accuracy due to orbital inclinations. In 2022, JRTI II underwent upgrades to improve autonomous operations, including enhanced capabilities for docking with support vessels to streamline logistics and reduce towing dependency.[32][33] As of November 2025, JRTI II remains active in SpaceX's recovery fleet, having indirectly supported over 300 missions through positioning and standby roles, even when not serving as the primary landing platform. This mid-fleet workhorse primarily enables reusable rocket operations on the East Coast, contributing to the overall efficiency of Falcon 9 and Falcon Heavy launches.[8]A Shortfall of Gravitas
A Shortfall of Gravitas is the fourth autonomous spaceport drone ship in SpaceX's fleet, converted from the cargo barge Marmac 302 and commissioned in July 2021 to enhance East Coast recovery capabilities. Homeported at Port Canaveral, Florida, it provides redundancy alongside existing vessels, enabling more flexible positioning for Falcon 9 booster landings in the Atlantic Ocean. The conversion was completed at Bollinger Shipyards' Port Fourchon facility, transforming the 2012-built barge into an equipped platform optimized for repeated offshore operations.[34][35][15] Measuring 90 meters in length and 46 meters in width, the vessel features a reinforced deck designed for rapid turnaround and secure booster placement, supporting SpaceX's push toward higher launch frequencies. It is equipped with four advanced azimuth thrusters driven by diesel engines housed in a dedicated superstructure, allowing for precise autonomous station-keeping in recovery zones after being towed into position by support vessels. These enhancements, including higher-power propulsion systems, position the ship to handle the demands of a 2020s launch cadence exceeding 100 missions annually, as evidenced by regulatory approvals for increased flight rates.[35][14][36] The drone ship achieved its inaugural booster landing on August 29, 2021, successfully capturing the first stage of Falcon 9 Block 5 booster B1061 during the CRS-23 resupply mission to the International Space Station. By November 2025, it has recorded 131 landing attempts, with 130 successes and one failure, including multiple consecutive recoveries for Starlink satellite deployments that underscore its role in scaling operations. This performance has been critical during high-volume periods, such as the 2024-2025 waves of Starlink missions, where the ship fills operational gaps to maintain launch momentum. The vessel remains fully active, contributing to SpaceX's overall fleet expansion for sustained reusability.[37][38][39]Operations
Preparation and deployment procedures
The preparation for deploying an Autonomous Spaceport Drone Ship (ASDS) begins 24 to 48 hours prior to a scheduled Falcon 9 launch, involving comprehensive inspections of the vessel's structural integrity, propulsion systems, and landing deck to ensure operational readiness. Thruster calibration is performed to verify precise station-keeping capabilities, while software updates are uploaded to the onboard navigation and control systems for mission-specific parameters. Securing gear, such as clamps and netting for post-landing booster stabilization, is loaded onto the deck during this phase.[40][2] Transit to the downrange landing zone typically occurs via towing by a support vessel from ports like Port Canaveral, Florida, covering distances of approximately 600 km in the Atlantic Ocean for many missions. The journey takes 1 to 2 days at towing speeds of around 5 to 10 knots, allowing the ASDS to arrive in position well in advance of the booster's expected descent approximately 8 minutes after liftoff. Once on site, the vessel transitions to self-propelled mode using its thrusters.[41][42][43] Positioning involves autonomous station-keeping to maintain the deck within meters of the targeted impact zone, with thrusters dynamically adjusting for ocean currents, winds, and forecasted weather variations to ensure stability. The ASDS is oriented to align with prevailing wave directions for optimal balance during the wait. Primary operations are conducted remotely from SpaceX's mission control center in Hawthorne, California, via satellite communication links; the ASDS remains uncrewed during landing and recovery, with support from nearby vessels for oversight.[7][44][45] Deployment proceeds only under favorable weather conditions, generally limited to waves below 2 meters and winds under 15 knots to minimize risks to the incoming booster. If forecasts indicate exceeding these thresholds, contingency plans shift the recovery to a Return to Launch Site (RTLS) landing on solid ground, avoiding ocean hazards. Support ships remain nearby for towing assistance post-mission.[46][47]Booster recovery process
The booster recovery process on an Autonomous Spaceport Drone Ship (ASDS) begins with the approach phase, where the Falcon 9 first stage, after separation and reentry, performs a final powered descent using its Merlin engine in a hoverslam maneuver. During this phase, the booster's landing legs deploy and align with illuminated circular markers on the ASDS deck, which feature a central "X" for precision targeting. The ASDS, positioned via differential GPS and dynamic positioning thrusters, fine-tunes its location in real-time to achieve sub-meter accuracy relative to the incoming booster, compensating for ocean currents and minor drifts.[48] In the landing execution, the booster uses grid fins for aerodynamic control during descent. The vertical touchdown speed is controlled to under 5 m/s to minimize impact stress, while the ASDS actively stabilizes against swells of 1-2 meters using its thruster array. This propulsive landing relies on the booster's onboard guidance to nullify horizontal and vertical velocities just above the deck.[49] Following touchdown, the booster uses its cold gas thrusters to maintain stability during initial hold-down. Within about 5 minutes, automated robotic arms, such as the Octagrabber, deploy to secure the landing legs in place, preventing tipping from residual motion or waves. The booster then undergoes automated safing procedures, including propellant venting and system shutdowns, before support crews board for inspection.[49][7] Post-landing, the booster is powered down completely, with telemetry data transmitted for immediate reuse assessment, evaluating structural integrity and propulsion health. The ASDS then transits back to port, typically taking 1-3 days depending on weather and distance, accompanied by support vessels for monitoring. This phase ensures safe transport of the recovered hardware for refurbishment.[50] By 2025, the ASDS recovery process has achieved a success rate of approximately 97%, reflecting iterative improvements in software, hardware, and weather prediction. Early failures in 2015-2016, such as mispositioned barges or grid fin malfunctions due to high winds and software glitches, informed these advancements, reducing error rates significantly.[51]Mission record
Usage and landing statistics
As of November 16, 2025, SpaceX has conducted approximately 444 landing attempts on autonomous spaceport drone ships (ASDS) for Falcon 9 first stages, achieving 432 full successes, 9 failures, and 3 partial successes.[52] Approximately 75% of Falcon 9 missions have utilized ASDS for recovery rather than landing at ground pads, reflecting the preference for offshore landings in missions requiring extended downrange trajectories, such as polar orbits from Vandenberg or high-inclination launches from Cape Canaveral.[53] Breakdowns by vessel highlight the operational distribution across the fleet: Of Course I Still Love You (OCISLY) has recorded 165 successful landings, Just Read the Instructions II (JRTI II) 140 successes, and A Shortfall of Gravitas (ASOG) 132 successes, while the original Just Read the Instructions (JRTI I) achieved no full successes before its retirement following early attempts.[54] Success rates for ASDS landings have evolved dramatically, starting at around 20% in 2015–2016 during initial tests and reaching 98% by 2025, driven by iterative improvements in guidance software, grid fin control, and cold gas thruster reliability.[8] Usage peaked in 2024–2025, with over 150 ASDS landings amid the rapid expansion of Starlink constellation deployments, enabling high-cadence orbital insertions.[51] Key operational metrics include an average booster turnaround time of 7–10 days from ASDS recovery to relaunch, facilitated by streamlined refurbishment processes at SpaceX facilities.[55] Reusability via ASDS has yielded estimated cost savings of $20–30 million per flight compared to expendable boosters, primarily through amortizing manufacturing expenses across multiple missions.[56] Geographically, approximately 75% of ASDS landings occur on the East Coast (using OCISLY and ASOG out of Port Canaveral), with 25% on the West Coast (JRTI II from Vandenberg), aligning with launch site demands.[53] ASDS are not used for Falcon Heavy side boosters, which are recovered on land pads due to their closer return profiles.[57]| Vessel | Successful Landings | Notes |
|---|---|---|
| Of Course I Still Love You (OCISLY) | 165 | Primary East Coast vessel; highest utilization. |
| Just Read the Instructions II (JRTI II) | 140 | West Coast operations from Vandenberg. |
| A Shortfall of Gravitas (ASOG) | 132 | East Coast support for high-volume missions. |
| Just Read the Instructions I (JRTI I) | 0 | Retired after early unsuccessful attempts. |