Fact-checked by Grok 2 weeks ago

Swift Engineering

Swift Engineering is an engineering firm specializing in the , , and manufacturing of advanced and systems, including unmanned aerial vehicles (UAVs), high-altitude platforms, composite structures, and mission-critical components for applications. Founded in 1983 in , the company originated in professional , producing championship-winning race cars before expanding into and markets in the early . Today, it serves as a single-source partner for integrated product solutions, from ideation to production, emphasizing speed-driven innovation for defense, commercial, and scientific missions. With over 40 years of experience, Swift Engineering has evolved from building high-performance vehicles like the chassis that debuted with a win in 1997 and the exclusive Formula Atlantic chassis from 1998 to 2009, to pioneering unmanned systems such as the 2002 Killer Bee UAV, which was later acquired by and adapted into the UAS. In , notable achievements include developing a single-engine from concept to first flight in just 200 days in 2007 and contributing to advanced like the SB-1 Defiant and Raider-X programs. The company's portfolio features manufacturing dispensers for in 2015 and supporting Boeing's unmanned submarine. In recent years, Swift has focused on cutting-edge UAV technologies, including the Swift020 UAS for applications like monitoring in since 2018 and the Swift021 platform. It has secured multiple (SBIR) awards, such as Phase II contracts in 2025 for the Swift Ultra Long Endurance (SULE) high-altitude platform system (HAPS), capable of 30-day missions at altitudes exceeding 55,000 feet for and communications. Additionally, the company developed a 72-foot solar-powered high-altitude long-endurance (HALE) UAS in partnership with in 2020, with subsequent flights achieving operations above 65,000 feet, including a record of 67,000 feet in 2025, and continues to innovate in areas like autonomous systems, , and rapid composite fabrication to reduce weight and enhance performance in extreme environments.

History

Founding and Motorsports Focus (1983–1999)

Swift Engineering was founded in 1983 as Swift Racing Cars by David Bruns, Alex Cross, R. K. Smith, and Paul White in San Clemente, California. The company initially concentrated on designing and manufacturing high-performance race cars for open-wheel racing series, with a particular emphasis on the Formula Ford category. Their debut vehicle, the Swift DB-1, was a Formula Ford 1600 chassis designed by David Bruns, featuring innovative aerodynamics such as a lowered front end, needle nose, and wide track that achieved the lowest drag coefficient in its class at the time. The DB-1 debuted in late 1983 and quickly dominated, securing the SCCA National Championship in its first full season and establishing Swift as a leader in affordable yet advanced racing technology. To support its growing motorsports ambitions, Swift invested in cutting-edge infrastructure, including the in 1993 of North America's largest and most advanced rolling , an 8-foot by 9-foot facility designed for precise aerodynamic testing of ground-effect vehicles. This rolling-road allowed for realistic simulation of on-track conditions, enabling rapid iterations in car design and contributing to Swift's reputation for excellence. In 1991, following its acquisition by executive and driver Hiro Matsushita, the company rebranded as Swift , reflecting a broader scope in applications while maintaining its core focus on . Swift's motorsports portfolio expanded with notable chassis designs, including the 1997 Swift 007.i , which achieved an immediate victory in its debut race at the Marlboro Grand Prix of Miami, driven by . This success highlighted the chassis's superior handling and speed, derived from advanced . By 1998, Swift secured an exclusive contract as the sole chassis supplier for the Formula Atlantic series, producing the Swift 008.a for 11 consecutive years and standardizing competition with its carbon-fiber-reinforced design. Throughout the and , Swift pioneered the use of composite materials, such as carbon fiber, aluminum, and hybrids, in race car bodies and components, which provided lightweight strength and enabled quick adaptations to racing regulations. These techniques, honed under the intense demands of motorsports for and iterative development, laid the groundwork for Swift's future engineering innovations.

Expansion into Aerospace (2000–2010)

In 2000, Swift Engineering expanded into and markets, leveraging its established expertise in advanced composites and from motorsports to address demands in unmanned aerial vehicles (UAVs) and aircraft design. This pivot marked the company's transition from high-performance racing chassis to defense and applications, where and lightweight structures proved essential. A key milestone came in 2002 with the design, construction, and delivery of the Killer Bee, a runway-independent blended-wing UAV featuring a mobile launch and retrieval system, developed for U.S. military applications. The platform, with its 4-foot wingspan and catapult-launch/net-recovery capabilities, demonstrated Swift's ability to integrate ground control stations, communication systems, and autonomous flight controls into a compact, tactical system suitable for intelligence, surveillance, and reconnaissance missions. This project highlighted the company's growing role in defense-oriented aerospace innovation. By 2006, Swift showcased its manufacturing scalability—honed through motorsports—by designing, building, and delivering 40 Formula Atlantic open-wheel race cars in just 240 days, a feat that underscored its capacity for high-volume production transferable to components. In 2007, this efficiency was applied directly to with the Eclipse Concept Jet (ECJ), a single-engine, four-passenger where Swift handled design and fabrication, achieving first flight in 200 days from initial concept under a secretive collaboration with at NASA's . The ECJ's configuration and composite emphasized fuel-efficient, high-speed personal transport, though the program was later canceled amid Eclipse's . Swift's aerospace momentum continued through initial collaborations with defense contractors, including a 2005 partnership with to develop UAV structural components for the Killer Bee platform. In 2009, acquired the Killer Bee product line, rebranding it as the Bat UAS family to enhance payload capacity and range for medium-altitude operations, while Swift retained roles in ongoing production and secured an exclusive chassis supply contract for Japan's Formula Nippon series. These developments solidified Swift's reputation for blending racing-derived precision with reliability during this foundational decade.

Recent Innovations and Diversification (2011–present)

Since 2011, Swift Engineering has expanded its expertise into advanced autonomous systems, technologies, and international collaborations, leveraging its established capabilities to address emerging challenges in unmanned operations and high-altitude platforms. This period marks a shift toward integrated solutions for defense, commercial, and scientific applications, with a focus on , composites, and global partnerships. In 2012, Swift Engineering received the JEC Americas Innovation Award for its innovative out-of-autoclave composite manufacturing process, which enabled cost-effective production of high-performance structures for applications. The following year, the company provided design and manufacturing support for the nosecone of Northrop Grumman's MQ-8 Fire Scout unmanned aerial system (UAS) and structural components for the RQ-4 Global Hawk, earning recognition through Northrop Grumman's World Class Team Award for exemplary supplier performance. In 2015, Swift contributed to Boeing's Echo Voyager extra-large unmanned undersea vehicle (XLUUV) through design and build support, enhancing its capabilities in maritime autonomy. That same year, the company manufactured dispensers for the Iridium NEXT satellite constellation launched via SpaceX, facilitating the deployment of 66 low-Earth orbit satellites for global communications. Also in 2015, Swift joined the Sikorsky-Boeing team to design and manufacture a major portion of the airframe structure for the SB-1 Defiant demonstrator in the U.S. Army's Joint Multi-Role Technology Demonstrator program. In 2016, Swift developed its proprietary autopilot and ground control software, enabling seamless integration and real-time management for its unmanned systems. The company also introduced the HIRO robot for remote operations in challenging environments. Advancements in vertical takeoff and landing (VTOL) technologies accelerated in 2018, when Swift deployed the Swift020 electric VTOL UAS for forestry monitoring applications in Japan. The following year, Swift designed the Swift021 electric VTOL UAS incorporating patented X-Blade technology for efficient transition between hover and forward flight without additional launch infrastructure. The company also supported Sikorsky's Raider-X demonstrator for the U.S. Army's Future Attack Reconnaissance Aircraft (FARA) program by designing and manufacturing key airframe structures, and contributed to the low-boom flight demonstrator (LBFD) structural design for NASA's X-59 QueSST supersonic aircraft. In 2020, Swift collaborated with on the High-Altitude Long-Endurance (HALE) High-Altitude Pseudo-Satellite (HAPS) solar-powered UAS, aimed at ultra-high altitude operations for persistent and communications, with the prototype achieving its first flight that year. To broaden its international footprint, Swift established an overseas office in 2018 through a with Japan's Institute of Computing, forming Swift Xi to advance , , and autonomous systems development. This diversification has extended into global communication systems, such as HALE platforms for low-latency data relay, and , exemplified by the 2016 HIRO for remote operations in challenging environments. Continuing its focus on high-altitude platforms, in 2024 Swift's Swift Ultra Long Endurance (SULE) HAPS achieved a 24-hour-plus flight reaching 56,000 feet in the . In 2025, the company secured a Phase II (SBIR) award to further develop the SULE platform, capable of 30-day missions at altitudes exceeding 55,000 feet for and communications. That year, Swift showcased its long-endurance Accipiter UAS at an invitation-only industry event in .

Motorsports Engineering

Key Race Car Designs

Swift Engineering's entry into motorsports began with the DB-1, introduced in 1983 as its inaugural Formula Ford chassis. Designed by David Bruns, the DB-1 featured a steel space frame—available in mild steel or chromoly options for enhanced strength—paired with innovative aerodynamic elements including a lowered front end, needle nose profile, wide track, and suspension components positioned out of the airstream to minimize drag. This configuration achieved the lowest drag coefficient recorded for a Formula Ford at the time, providing superior top-speed performance while maintaining affordability at a base price of $16,000 for a rolling chassis. In 1997, Swift expanded into higher-level open-wheel racing with the 007.i chassis for the CART IndyCar series, marking the company's first foray into carbon fiber monocoque construction. The 007.i incorporated a lightweight carbon fiber tub for improved rigidity and weight reduction, alongside aerodynamic refinements such as a low-drag bodywork package developed through and testing. Key innovations included a nested to optimize heat management and airflow, as well as moving plane diffusers for enhanced stability—features that influenced subsequent CART chassis standards. This design emphasized crash energy management through the composite structure's progressive deformation properties, setting a benchmark for safety in high-speed prototypes. From 1998 to 2009, Swift served as the exclusive supplier for Formula Atlantic, producing a series of spec that prioritized and rapid . The lineup included the 008.a (introduced in 1998), evolutions such as the 014.a (from 2002), and the 016.a (from 2006), all utilizing carbon fiber composites for the and components to achieve weight savings of up to 20% over steel predecessors while enabling quick assembly. The earlier DB-4 (1987–1997) laid groundwork for these designs. These designs featured adjustable modular systems—allowing teams to fine-tune without major modifications—and streamlined production processes that allowed Swift to deliver 40 complete 016.a in just 240 days for the 2006 season. The composite elements not only reduced overall vehicle weight to approximately 1,275 pounds but also incorporated energy-absorbing zones in the side impact structures for enhanced driver protection. Swift's involvement in Japan's Formula Nippon (later Super Formula) began in 2009 with the 017.n chassis, known as the FN09, which became the series' sole spec car through 2013. This carbon fiber design advanced with an integrated survival cell featuring multi-layered composite layups for superior crash energy dissipation, meeting stringent FIA-equivalent standards. The 017.n's aerodynamic package, refined via in-house , emphasized underbody generation. Throughout its race car portfolio, Swift consistently leveraged composite materials—primarily —for chassis and bodywork to achieve significant weight reductions, often 15-30% compared to metallic alternatives, while optimizing crash energy management through controlled failure modes in the laminate structures. These motorsports-derived composite techniques, such as out-of-autoclave curing and co-cured assemblies, later informed Swift's applications by enabling lightweight, high-strength structures resilient to dynamic loads.

Achievements in Racing Series

Swift Engineering marked its entry into the IndyCar Series with the Swift 007.i chassis, which secured a victory in its debut race at the 1997 Grand Prix of Miami, driven by . In 1998, Swift Engineering was awarded exclusive rights as the chassis designer and manufacturer for the Formula Atlantic series, a position it held for 11 years until 2009. During this period, the series produced multiple champions using Swift chassis, including notable drivers who progressed to higher tiers of motorsport, underscoring the platform's role in driver development and series stability. A standout logistical achievement came in 2006, when Swift designed, built, and delivered 40 Formula Atlantic cars within 240 days to support the series' transition to the new spec chassis, ensuring uninterrupted competition and demonstrating exceptional manufacturing efficiency. Swift's influence extended internationally in 2009, when it became the exclusive chassis provider for the Formula Nippon series with the , a design that continued in use through the series' rebranding to Super Formula until 2013, shaping the evolution of Japan's premier open-wheel championship. Over its motorsports tenure, Swift Engineering produced more than 500 race vehicles, setting benchmarks for safety and performance in open-wheel racing through rigorous testing and composite material integration. These engineering principles later informed lightweight structures in Swift's aviation projects.

Aerospace and Aviation

Unmanned Aerial Vehicles (UAVs)

Swift Engineering has developed a diverse portfolio of unmanned aerial vehicles (UAVs), emphasizing fixed-wing, vertical takeoff and landing (VTOL), and high-endurance platforms tailored for military intelligence, surveillance, and reconnaissance (ISR) missions as well as civilian applications such as environmental monitoring and disaster response. These systems leverage lightweight composite materials derived from the company's motorsports heritage to achieve enhanced structural efficiency and payload capacity. The Killer Bee, introduced in 2002, represents one of Swift Engineering's early contributions to small tactical UAVs, featuring a blended-wing body design with a 12-foot for low-observable flight characteristics. This runway-independent platform supports launch and net recovery, enabling operations from austere environments, and achieves up to 12 hours of at loitering speeds around 55 knots. Fully autonomous, it integrates modular payloads for tasks and was acquired by in 2009, where it evolved into the Bat UAS family with extended capabilities such as 18-hour in later variants. In 2014, Swift Engineering advanced VTOL technology with the Swift Crane, a fully electric UAS incorporating patented X-Blade rotor technology for efficient vertical takeoff, precision hovering, and transition to fixed-wing forward flight. This design provides up to 2 hours of endurance and a 25-kilometer operational range, with assembly requiring only one operator in under five minutes, making it suitable for rapid deployment in mapping and observation roles. The X-Blade system enhances stability and reduces noise, supporting both military and civilian applications like search-and-rescue operations. The Swift020 (developed in 2017) and its successor the Swift021 (developed in 2019), build on this foundation as electric variants optimized for missions with modular payload bays accommodating up to 1 kilogram of sensors. These quad-rotor hybrids enable vertical without runways, transitioning to efficient fixed-wing cruise for up to 2 hours of and a 60-mile communication range, demonstrated in overwater tests and international demonstrations. Swift Engineering's in-house autopilot software governs these platforms, enabling autonomous flight paths, real-time obstacle avoidance, and machine learning-based adjustments for enhanced navigation safety. Swift Engineering's Swift Ultra Long Endurance (SULE) UAS, unveiled in , pushes boundaries in high-altitude, long-duration operations with a solar-powered, ultralight featuring a 72-foot and 15-pound capacity. Designed for stratospheric missions above 65,000 feet, it has achieved altitudes of 67,000 feet in July 2025 and durations exceeding 24 hours in test flights, with goals for 30-day endurance under SBIR funding to support persistent surveillance and . The proprietary integrates with solar augmentation for seamless autonomous operations in environmental and defense contexts.

Manned Aircraft Developments

Swift Engineering's involvement in manned aircraft primarily centers on the development of business jet prototypes, leveraging its expertise in composite materials and rapid design cycles to enhance efficiency and performance. In 2007, the company collaborated with Eclipse Aviation to create the Eclipse 400, a single-engine very light jet designed as a four-passenger business aircraft. This project exemplified Swift's capabilities in full-vehicle architecting, from conceptual CAD modeling and computational fluid dynamics (CFD) analysis to finite element analysis (FEA) and wind-tunnel testing, all executed in-house at its San Clemente, California facility. The 400 featured an all-composite , which contributed to its low-drag and lightweight structure, optimizing for short-haul operations. Swift Engineering handled the complete , including interiors, and manufactured the using advanced composite techniques, achieving first flight on July 2, 2007, at NASA's in —just 200 days from the blank-sheet phase. Unveiled at the on July 23, 2007, the aircraft's configuration and integration of modern positioned it as a competitor to emerging single-engine jets like the SF50. Although the project did not advance to production following Eclipse Aviation's financial challenges, it demonstrated Swift's proficiency in for composite airframes, reducing development timelines while maintaining structural integrity. Beyond the 400, Swift Engineering has contributed to designs through consultancy and component fabrication, emphasizing out-of-autoclave (OOA) composite processing and co-cured structures to achieve high-performance, low-weight solutions. These efforts focus on minimizing aerodynamic drag via optimized shaping and , enabling faster iteration in prototype phases for partners.

Helicopter and Rotorcraft Contributions

Swift Engineering has made significant structural contributions to unmanned systems, notably through its support for the UAS in 2013, where the company designed and manufactured the nosecone structure. This work provided lightweight composite components essential for the 's sensor integration and aerodynamic performance, serving as a foundational bridge to Swift's subsequent involvement in manned and hybrid programs. In 2015, Swift joined the Sikorsky-Boeing team for the Joint Multi-Role Technology Demonstrator program, taking responsibility for a major portion of the structure design and fabrication for the SB-1 Defiant rotor compound . Delivered in 2016, these composite structures enabled the Defiant's innovative , which integrates counter-rotating rigid rotors with a pusher to achieve high-speed forward flight capabilities exceeding 250 knots. The 's advanced materials and integrated design supported the vehicle's agility in both hover and cruise modes, advancing U.S. Army objectives. Building on this expertise, Swift Engineering collaborated with Sikorsky in 2019 on the Raider-X prototype for the U.S. Army's (FARA) program, designing and constructing key elements of the structure at its San Clemente facility. This included contributions to scalable structural components that accommodate the coaxial rotor system and pusher propulsor pylon, facilitating the Raider-X's compact, high-maneuverability profile for reconnaissance missions. Swift's patented X-Blade Technology (US Patent 9,567,088 B2), originally developed for efficient vertical take-off and landing transitions in unmanned systems, has been adapted to enhance rotor efficiency in compound rotorcraft designs. These adaptations optimize blade configurations for reduced drag and improved stability during VTOL-to-forward-flight shifts, drawing from Swift's UAV VTOL innovations to inform manned rotorcraft stability.

Maritime and Naval Technologies

Unmanned Underwater Vehicles (UUVs)

Swift Engineering has contributed to the advancement of unmanned underwater vehicles (UUVs) through its expertise in composite engineering, particularly for extra-large unmanned undersea vehicles (XLUUVs) used in naval defense applications. The company supported Boeing's development of the Echo Voyager, a 51-foot-long XLUUV introduced in 2016, which features hybrid diesel-electric propulsion enabling autonomous missions lasting several months without surface support. Swift provided engineering and manufacturing services for this platform, including the fabrication of large composite structures essential to its structural integrity. Building on this work, Swift Engineering extended its involvement to the U.S. Navy's Orca XLUUV program, a modular submarine platform derived from Echo Voyager technology and developed in collaboration with Boeing and Huntington Ingalls Industries. The Orca incorporates reconfigurable payload bays, approximately 10 meters long with an 8-ton capacity, allowing integration of sensors, weapons, or other mission-specific equipment for extended underwater autonomy. Swift's role focused on composite structures that support stealth characteristics through low acoustic signatures and facilitate payload modularity, leveraging advanced materials to balance strength, weight, and hydrodynamic performance. Swift Engineering's contributions also encompass the testing and fabrication of pressure-resistant composites tailored for deep-sea operations in these XLUUV platforms. Utilizing Nadcap-accredited facilities equipped with large-scale autoclaves capable of processing up to 150 psi, the company produces and validates composite components designed to endure extreme hydrostatic pressures while maintaining structural integrity. These efforts ensure the vehicles' reliability in submerged environments, with Swift's hull design support including features like payload dispensers for deploying underwater assets. Drawing briefly from its heritage, Swift adapted lightweight composite techniques to enhance underwater durability against corrosion and pressure.

Maritime Payload and Communication Systems

Swift Engineering has developed advanced surface maritime technologies focused on payload integration and communication networks to facilitate data collection and environmental monitoring. A key contribution is the Kelp Smart Buoy, created in partnership with HyperKelp, Inc., which serves as a hosted system for real-time aquatic environmental assessment. This modular buoy platform enables of parameters, such as temperature, salinity, and pollutants, while supporting defense applications like and in harbors. The Kelp Smart Buoy emphasizes affordability and ease of use, reducing deployment costs by approximately 50% compared to traditional systems and allowing single-person setup in harsh conditions. Its design incorporates open-source adaptability for custom payloads, ensuring minimal environmental impact through recyclable materials and reusability. Data collected is processed onboard and transmitted via a secure, remote-access , enabling for operations such as monitoring and coastal . This system was developed in partnership with NOAA and Sea Grant, highlighting Swift's role in advancing low-cost, scalable observation tools. As of 2025, the buoys have been deployed in for environmental monitoring and secured a $1.8 million U.S. contract to advance surveillance capabilities. In parallel, Swift Engineering integrates global communication systems for , drawing on technologies from its division to enhance data relay and remote collaboration in domains. These systems support seamless transmission of environmental and surveillance data from surface platforms to command centers, improving operational awareness for naval fleets. capabilities, derived from high-performance actuators and control software in ground , allow operators to interact with assets as if present, facilitating decision-making in dynamic ocean environments.

Robotics and Autonomous Systems

Ground and Telepresence Robots

Swift Engineering has developed ground-based robotics solutions emphasizing telepresence capabilities to facilitate remote human-robot interaction, particularly in educational and collaborative settings. The company's robotics efforts build on its expertise in advanced actuation and control systems, enabling safe and efficient operations in dynamic environments. These systems prioritize modularity and user-friendly interfaces to support applications where physical presence is limited or hazardous. A key example is the HIRO Robot, introduced in 2016, designed specifically for robotic operations. HIRO features arm and hand bands for precision control, allowing operators to manipulate the robot remotely with intuitive gestures. It incorporates 360° stereoscopic augmented virtual overlays with vector gaze tracking and provides tactile feedback to enhance during interactions. The robot's modular arms utilize innovative series elastic actuators, which offer the highest available at the time, along with and a compact, sleek for seamless into various tasks. These actuators enable safe human contact through compliant elements that absorb impacts, making HIRO suitable for collaborative environments such as and remote collaboration. Built on a human-inspired mobile platform, HIRO supports navigation in unstructured spaces, drawing briefly on software principles adapted from Swift's UAV developments for enhanced ground mobility. Complementing HIRO, Swift Engineering's Swift Robotics division focuses on ground vehicle platforms tailored for and logistics in challenging or hazardous environments. These platforms leverage composite materials and advanced from the company's heritage to create durable, lightweight systems capable of navigating rough terrain while carrying payloads for monitoring or transport tasks. The division emphasizes transforming human-machine collaboration through features, enabling operators to oversee operations remotely and intervene as needed. Such designs are deployed in and contexts where reliability and minimal downtime are critical. In 2018, Swift Engineering established a called Swift Xi Inc. with the Kobe Institute of Computing in to expand its portfolio for global markets. Based in , Swift Xi develops AI-enhanced robotic systems as part of broader autonomous technologies, integrating for improved decision-making in operational scenarios. The venture targets applications, including enhanced human-robot interfaces and collaborative tools that build on HIRO's foundation. This partnership has facilitated the adaptation of Swift's technologies for international standards and diverse use cases, such as urban mobility and industrial automation.

Autonomy Software and Control Technologies

Swift Engineering developed its proprietary and ground control software in 2016, designed specifically for cross-platform in unmanned systems. This software enables real-time path planning and , allowing seamless integration of data from multiple sensors such as GPS, inertial measurement units, and environmental detectors to support precise navigation and obstacle avoidance. Applicable to both unmanned aerial vehicles (UAVs) and unmanned underwater vehicles (UUVs), the system facilitates autonomous operations in diverse environments, from aerial to subsea missions, enhancing reliability in mission-critical scenarios. The ground control software complements the by providing operators with intuitive interfaces for mission planning, real-time monitoring, and vehicle health reporting, ensuring secure and layered communication protocols limited to authorized sites. Integrated into platforms like the Swift020 UAS and Killer Bee UAV, it supports extended endurance flights with features for status updates and , minimizing human intervention while maintaining standards. For UUV applications, the software adapts to underwater constraints, fusing acoustic and optical sensor data for path optimization in low-visibility conditions. Swift Engineering's data analytics platforms, particularly through its Swift Global Comm division, process mission data for actionable insights in high-stakes operations, including vehicle health monitoring and for sustained performance. These platforms leverage collected to enable predictive algorithms that anticipate system degradations, reducing downtime in autonomous fleets. In multi-domain contexts, integration enhances the software's capabilities, incorporating techniques such as for adaptive across air, sea, and ground domains. For instance, AI-driven processing improves UAV navigation by analyzing vast datasets in real-time, supporting applications in and . This software ecosystem extends briefly to ground-based platforms like the Hiro robot, where it provides unified control for and collaborative tasks. Overall, Swift's autonomy technologies prioritize modularity and security, fostering interoperability in joint operations while adhering to stringent defense standards.

Company Operations

Facilities and Organizational Structure

Swift Engineering's headquarters is located in , where the company operates a state-of-the-art 60,000 square foot facility dedicated to design, prototyping, and production activities. This facility supports the full spectrum of engineering and manufacturing processes, enabling rapid development cycles, as demonstrated by the design, construction, and delivery of 40 Formula Atlantic race cars in just 240 days in 2006. The facility is equipped for advanced manufacturing techniques, including composite fabrication with three autoclaves capable of processing materials up to 450°F and 150 , alongside rooms and controlled contamination areas to ensure high-quality production. prototyping is facilitated through CNC machining and technologies, such as those from , which allow for the creation of complex composite tooling and prototypes without compromising performance. Testing capabilities encompass static and dynamic structural evaluations, supported by on-site laser tracker inspections and specialized analysis for and applications. Additionally, the facility houses North America's largest and most advanced rolling , built in 1993, for aerodynamic testing and validation. Organizationally, Swift Engineering is structured around specialized teams in motorsports, , , and , each drawing on cross-functional expertise in engineering, design, and manufacturing to address mission-critical projects. These teams collaborate to leverage the company's integrated capabilities, with dedicated divisions such as Swift Robotics focusing on autonomous systems and human-machine interaction, and HyperKelp addressing technologies like buoys. In 2018, Swift expanded internationally through a with the Kobe Institute of Computing, establishing Swift Xi Inc. in , , to advance in , , and autonomous systems. This initiative marked the company's first overseas office, enhancing its global innovation efforts in urban mobility and related technologies.

Leadership and Strategic Partnerships

Swift Engineering was founded in 1983 by David Bruns, Alex Cross, R. K. Smith, and Paul White as a designer and manufacturer of high-performance race cars, with the founders establishing a foundation in advanced composites and aerodynamics that influenced the company's later pivot to aerospace applications. In 1991, the company was acquired by Hiro Matsushita, a former professional racecar driver and grandson of Panasonic founder Konosuke Matsushita, who steered its expansion into aviation and unmanned systems during the post-1990s era. Matsushita serves as Chairman and CEO, bringing a legacy of motorsport innovation to oversee strategic growth in defense and commercial sectors. Current leadership includes President Hamed Khalkhali, who leads operations with a focus on transformative aerospace solutions, alongside executives such as Chief Financial Officer Rick Schnell and Head of Operations Natarajan T, emphasizing engineering expertise from aerospace backgrounds. Key partnerships have been central to Swift's innovation, including long-term collaboration with on unmanned aerial vehicles (UAVs), where Swift developed the KillerBee ISR platform, later acquired by Northrop for military applications. Swift has partnered with on unmanned underwater vehicles (UUVs) such as the extra-large UUV and autonomous undersea vehicle, providing engineering and manufacturing support for naval autonomy. In helicopter programs, Swift contributed design and composites to the Sikorsky-Boeing SB>1 Defiant compound helicopter for the U.S. Army's competition, and to the for the program, enhancing vertical lift capabilities. Additionally, Swift has worked with Bell on aerospace projects and on high-altitude long-endurance (HALE) platforms, including SBIR-funded developments like the SULE solar-powered UAS for missions. Strategic alliances underscore Swift's role in defense and commercial ecosystems, with contracts for ISR platforms such as the KillerBee UAV supporting , , and operations for U.S. partners. Commercially, Swift manufactured dispensers for the , facilitating deployment of communication satellites via launches to enable global connectivity services. In 2018, Swift formed the joint venture Swift Xi Inc. with Japan's Institute of Computing, establishing its first international office in to advance R&D in UAVs, , and logistics solutions tailored to Japanese markets.

Awards and Recognitions

Major Industry Awards

Swift Engineering has received several prestigious awards recognizing its contributions to engineering excellence in composites, unmanned systems, and supplier performance. In 2012, the company was awarded the JEC Americas Innovation Award for its advancements in out-of- composite processing, which enabled efficient production of high-performance airframes without traditional methods. This recognition highlighted Swift's innovative approach to reducing costs and improving scalability in composites. That same year, Swift Engineering earned the Small Business Supplier of the Year award, selected from over 1,500 suppliers for exceptional performance in delivering critical components for unmanned aerial systems.

Notable Contracts and Milestones

In 2009, acquired the design and marketing rights to Swift Engineering's Killer Bee unmanned aerial system (UAS), evolving it into the UAS family with enhanced payload capacity and range capabilities. This transaction marked a significant milestone in Swift's transition from motorsports to defense-oriented autonomous systems, enabling the variants to achieve wingspans up to 33 feet while maintaining modular, hand-launchable designs. Swift Engineering supported Boeing's development of the Echo Voyager extra-large unmanned undersea vehicle (XLUUV) around 2015, facilitating the company's entry into naval autonomy technologies through contributions to its structural and composite elements. The , a fully autonomous, pier-launched UUV capable of months-long missions with propulsion, represented a pivotal advancement in long-endurance underwater operations, drawing on Swift's expertise in lightweight composites for enhanced buoyancy and durability. A landmark achievement in rapid prototyping occurred in 2007 when Swift Engineering designed and built the Concept Jet (ECJ)—a single-engine, four-seat —from concept to first flight in under 200 days, setting a record for the category. Commissioned by , the ECJ demonstrated Swift's proficiency in accelerated composite fabrication, incorporating advanced and a compact to achieve efficient performance during its July 2 debut flight. In 2020, Swift Engineering collaborated with NASA's on the High-Altitude Long-Endurance (HALE) UAS, achieving the first solar-powered stratospheric flight of a U.S.-made platform designed for persistent missions above 65,000 feet. The 72-foot-wingspan HALE vehicle, weighing under 180 pounds empty, supports 15-pound payloads for up to 100 days of continuous operation, providing a cost-effective alternative to satellites for and communications relay. In 2025, Swift Engineering received a Phase II (SBIR) contract from for the Swift Ultra Long Endurance (SULE) high-altitude platform system (HAPS), supporting design, fabrication, and for missions lasting up to 30 days at altitudes exceeding 55,000 feet for and communications. Over its history, Swift Engineering has produced more than 500 vehicles across , automotive, and autonomous domains, while serving as a key composites supplier to major primes including for programs like the (FARA) airframe. These contracts have not only driven technological innovations but also earned Swift several industry recognitions for engineering excellence.

References

  1. [1]
    The Company We Keep - Swift Engineering
    Swift Engineering is a speed-driven, innovation company providing products, technologies, and fully integrated product development solutions from ideation to ...
  2. [2]
    History - Swift Engineering
    For over 40 years, Swift Engineering's design and manufacturing innovations have produced championship-winning racecars and next-generation aviation and ...Missing: projects achievements
  3. [3]
    Swift Engineering - Innovating the next generation of advanced ...
    Swift Engineering is a speed-driven, innovation company providing products, technologies, and fully integrated product development solutions from ideation to ...Company · People & Culture · Contact · Swift020 VTOL UAS
  4. [4]
    Swift Engineering Wins Phase II NASA SBIR Award for SULE High ...
    Jul 15, 2025 · The award provides financial support for the company's Swift Ultra Long Endurance (SULE) high-altitude platform systems (HAPS) capability demonstration.Missing: sources | Show results with:sources
  5. [5]
    Swift Engineering History: Founding, Timeline, and Milestones - Zippia
    Swift Engineering company history timeline. 1983. Swift Engineering was founded as SWIFT CARS in 1983 by David Bruns, Alex Cross, R. K. Smith, and Paul White.
  6. [6]
    Swift DB1 Racecar
    Alex Cross, RK Smith, Paul White and Dave Burns created Swift Cars to bring burns vision to life. The DB1's aerodynamic design produced the lowest drag ever ...
  7. [7]
    David Bruns' influence on the AAR Eagle - Paul Haney
    Apr 22, 1999 · The David Bruns-designed Swift DB-1 (DB for David Bruns' initials) Formula Ford began racing late in 1983 and quickly eclipsed all the other FF ...
  8. [8]
    Recent Upgrades to the Swift 8ft × 9ft Rolling-Road Wind Tunnel
    Dec 2, 2002 · This paper describes upgrades to the Swift 8' by 9' rolling-road wind tunnel that will be available for use in 2003. The Swift tunnel was ...Missing: 1993 North largest<|control11|><|separator|>
  9. [9]
    HIRO AT LARGE - Los Angeles Times
    Sep 24, 1997 · His team of engineers at Swift developed the Swift chassis that Michael Andretti won with in its debut race, CART's season opener in Homestead, ...
  10. [10]
    The Race May Go to the Swift but Profits Come More Slowly
    Aug 16, 1988 · Some Swift cars have Fiberglas bodies, while others are made of a composite material of carbon fibers, aluminum and Fiberglas. ... The company ...
  11. [11]
    Composite Manufacturing - Swift Engineering
    Bring your ideas from prototype to production. Swift Engineering is an industry leader in composite manufacturing, parts, and tools.Missing: rapid motorsports
  12. [12]
    Swift Engineering Information - RocketReach
    In 2000, Swift Engineering diversified in to aerospace vehicles and has worked on space, aerospace, aeronautical, terrestrial and underwater, manned and ...
  13. [13]
    Swift Engineering on the fast track | News | Flight Global
    Aug 15, 2007 · Swift has previously been known in aerospace circles for a concept for a swarming, flying-wing family of tactical unmanned air vehicles called ...
  14. [14]
    Killer Bee UAV - Swift Engineering
    The Killer Bee is a catapult launch and net recovery UAS, that included the development of the ground control station (GCS), communication systems, system ...Missing: 2002 | Show results with:2002
  15. [15]
    Eclipse Concept Jet - Swift Engineering
    The Eclipse 400 was first publicly unveiled on 23 July 2007 at AirVenture as the Eclipse Concept Jet (ECJ). The Eclipse 400 is a small, four-passenger ...
  16. [16]
    Bat Unmanned Aerial Vehicle (UAV) - Airforce Technology
    May 13, 2010 · Bat UAV development. Northrop Grumman partnered with Swift Engineering in 2005 to design and develop KillerBee UAV (now known as Bat) for the ...
  17. [17]
    Northrop buys Swift's KillerBee UAS family | News | Flight Global
    Apr 28, 2009 · Northrop Grumman has acquired a line of small unmanned air systems (UAS) invented by Swift Engineering and formerly known as KillerBee.Missing: 2002 | Show results with:2002
  18. [18]
    Northrop Grumman Acquires KillerBee UAV Line - Aviation Week
    Share. Graham Warwick April 29, 2009 ... Two years after they failed to reach a business agreement and parted company, Northrop Grumman has acquired the KillerBee line of unmanned aerial vehicles (UAVs) from Swift Engineering.
  19. [19]
    Legacy of Airframe Design - Swift Engineering
    Swift Engineering, Inc. has a long legacy of innovation in the aerospace industry from the ideation of a novel UAV in 2000 to the current 2021 Sikorsky ...Missing: expansion 2000-2010
  20. [20]
    Thread: Swift DB-1 frame material - ApexSpeed
    Nov 24, 2018 · The early Swift DB-1 FF frames were both mild steel and chromoloy. The all chromoly frame was an option in the early years, but was dropped sometime in 1984 as ...Thread: Swift DB1- how many were made?Thread: 1989 Swift DB-1More results from www.apexspeed.comMissing: Engineering | Show results with:Engineering
  21. [21]
    [PDF] FORMULA FORD - 25 Years On - ApexSpeed
    But Cross was more of a salesman than a driver. So, with. Bruns and racer RK Smith, they pooled their money, created Swift. Cars and got to work.
  22. [22]
    Swift 007.i
    Designer David Burns Notable Drivers Michael Andretti, Christian Fittipaldi, and Roberto Moreno Competition History Races: 17 Wins: 1 Podiums: 5 Technical ...Missing: IndyCar | Show results with:IndyCar
  23. [23]
    1997 Swift-Ford 007.i | Haas Collection - RM Sotheby's
    The 1997 Swift-Ford 007.i was the first IndyCar chassis from Swift, with novel features like moving plane diffusers, and won its debut race. It was one of six ...
  24. [24]
    Swift DB4
    The Swift DB4 is an open-wheel formula racing car chassis, designed, developed, and built by American Company Swift Cars.Missing: 1998 | Show results with:1998
  25. [25]
    Swift 017.n - Wikipedia
    The Swift 017.n was the sole racing car for the Super Formula (formerly: Formula Nippon) between 2009 and 2013. The initial FN09 version was upgraded for ...
  26. [26]
    The Indycars that never were - Page 4 of 7 - Racecar Engineering
    Jul 21, 2017 · Swift had good form with supplying interesting looking spec racers with the Formula Nippon chassis it had developed a couple of years earlier.
  27. [27]
    Swift Engineering excels in rapid composite fabrication and high ...
    Jun 4, 2025 · Swift Engineering (Swift) began as Swift Race Cars in 1983. It was in 1991 that the business rebranded to Swift Engineering, and by the ...Missing: headquarters | Show results with:headquarters
  28. [28]
    Swift 007.i - Wikipedia
    Complete CART results ; United States · Michael Andretti, 6, 1*, 3 ; Brazil · Christian Fittipaldi, 11, 26, 28 ; Brazil · Roberto Moreno, 24 ...
  29. [29]
    Swift
    The first car, the DB-1, was a Formula Ford 1600 which won the SCCANational Championship in its debut race. The company later built cars for Sports 2000 ...
  30. [30]
    2006 Champ Car Formula Atlantic Series - Road & Track
    Feb 14, 2006 · The American-made Swift Engineering 016.a chassis features all-composite construction, revamped aerodynamics (including heavily sculpted ...
  31. [31]
    Eclipse Aviation partners with Swift Engineering to develop Eclipse ...
    Jul 27, 2007 · Swift Engineering assisted with design and build of the Eclipse Concept Jet, while Eclipse provided design vision and specifications. Swift ...Missing: 400 | Show results with:400<|separator|>
  32. [32]
    Swift, raytheon Promote Killer Bee UAV for Tier II - Defense Update
    Apr 28, 2009 · Swift Engineering teamed with the Raytheon Company, pursuing the STUAS/Teir II competition with its Killer Bee UAS platform.Missing: 2002 | Show results with:2002
  33. [33]
    Swift Crane VTOL UAS
    The Swift Crane is fully electric, provides a flight endurance of up to 2 hours and an operational range of 25 kilometers. Back to Research & Development ...Missing: 2019 | Show results with:2019
  34. [34]
    Swift020 VTOL UAS​ - Swift Engineering
    Swift developed this entire system in-house including its autopilot, hardware/software package to report vehicle health and status, and a ground control system.Missing: proprietary 2016
  35. [35]
    Long-Range Drone Takes Off, Lands like a Bird - ASME
    Sep 20, 2019 · The Swift020 electric drone turns off front and aft fuselage propellers when cruising to extend battery life for up to 2 hours. · Swift ...Missing: X- Blade
  36. [36]
    VTOL UAS-Swift Engineering Inc. has overwater test flight with ...
    The Swift020 Unmanned Air System (UAS) takes off and lands anywhere like a quad-rotor and transitions to efficient fixed-wing forward flight without additional ...
  37. [37]
    Swift Engineering SULE High-Altitude, Long-Endurance Platform ...
    Nov 13, 2024 · SULE delivers an even longer range/endurance platform with a 72-foot wingspan and 15-pound payload capacity that can provide seamless ...
  38. [38]
    Swift Ultra Long Endurance (SULE) Unmanned Air Vehicle (UAV)
    Swift proposes to design, fabricate, and fly a Swift Ultra Long Endurance (SULE) 30-day mission HALE UAS with flight tests including: 24-hrs, 48-hrs, ...
  39. [39]
    https://www.suasnews.com/2017/05/vtol-uas-swift-engineering-inc-overwater-test-flight-swift020/
  40. [40]
    The Little Eclipse Concept Jet That Almost Was - FLYING Magazine
    Nov 15, 2022 · The Eclipse 400 (originally ECJ) was a sleek, single-engine, V-tail personal jet that predated and bore a strong resemblance to the later Cirrus ...
  41. [41]
    [PDF] NASA SBIR-2024-Phase 1 Solicitation
    Proposal Title: SAF-compatible Hybrid-Electric propulsion for a fixed-wind aircraft ... Firm: Swift Engineering, Inc. Address: 1141-A Via Callejon , San ...
  42. [42]
    Engineering the Future of Flight: Inside Aerospace Systems ...
    Aug 13, 2025 · A successful prototype is the starting point for production. Swift approaches every airframe with scalability in mind. Designs are built to ...
  43. [43]
    SB-1 Defiant completes testing program - AeroTime
    Jan 19, 2022 · Such a design will, according to Sikorsky and Boeing, allow the helicopter to reach speeds in excess of 250 knots (460 km/h). For a comparison, ...
  44. [44]
    Swift Engineering Selected for the Design and Construction of FARA ...
    Swift Engineering Selected for the Design and Construction of FARA Airframe for Sikorsky, a Lockheed Martin Company. December 23, 2019 ...Missing: L- BFD<|separator|>
  45. [45]
    Raider X (FARA) - Swift Engineering
    Weapon System Built for Multi-Domain Operations ; Customer: Sikorsky/Lockheed Martin ; Industry: Aerospace & Defense ; Services: Design & Manufacturing.Missing: L- BFD 2019
  46. [46]
    US9567088B2 - Vertical take-off and landing aircraft - Google Patents
    A VTOL aircraft includes at least one puller rotor and at least one pusher rotor. The VTOL aircraft, for example, may include three puller rotors and one pusher ...<|separator|>
  47. [47]
    Echo Voyager - Swift Engineering
    Fully autonomous extra large unmanned undersea vehicle (XLUUV). Swift Performance Level: Supported the project.(Details are confidential)Missing: 2015 | Show results with:2015
  48. [48]
    [PDF] Echo Voyager | Boeing
    Echo Voyager is a game-changing platform, capable of performing as a multi-mission system and playing a pivotal role in future force structure. The vehicle's ...Missing: Swift 2015
  49. [49]
    None
    ### Summary of Swift Engineering's Work on Unmanned Underwater Vehicles, XLUUV, Composites, Hull Design, Testing, and Naval Technologies
  50. [50]
    Orca XLUUV - Swift Engineering
    The Orca is an autonomous underwater vehicle (AUV) that is under development by Boeing and Huntington Ingalls Industries for the United States Navy.Missing: 2015 | Show results with:2015
  51. [51]
    Orca XLUUV, USA - Naval Technology
    Apr 19, 2024 · Contractors involved. Swift Engineering, a product development company, supported Boeing in the development of the Orca XLUUV. Share.
  52. [52]
    First Look at the US Navy's Orca XLUUV with Massive Payload Module
    Jun 12, 2024 · The UUV features a modular payload bay that is about 400 inches (10 meters) in length and has a capacity of 8 tons. This payload bay has defined ...
  53. [53]
    Swift Engineering Profile - HigherGov
    Date Founded. Jan. 7, 2003. Initial Registration. Sept. 25, 2002. Last Registration. Jan. 16, 2025. Registration Activation. Jan. 15, 2025. Registration ...
  54. [54]
    Kelp Smart Buoy - Swift Engineering
    Modular and affordable aquatic environmental monitoring system. Customer: Hyper Kelp. Industry: Commercial and Defense.
  55. [55]
    HyperKelp Update: February 1, 2023
    Feb 24, 2023 · We will demonstrate our systems' real-time remote sensing, rapid data transmission, and integration into existing command and control systems ...
  56. [56]
    HIRO Robot - Swift Engineering
    A new high-performance series elastic actuator that was energy efficient, had the highest power-to-weight ratio on the market, and had a sleek, compact design.
  57. [57]
    Swift Xi | Accelerating Social Innovation
    Cultivating innovation and developing disruptive technologies for systems of autonomous systems, robotics & AI, urban mobility, and power management.Missing: spacecraft | Show results with:spacecraft
  58. [58]
    VTOL Swift020 flies over Kobe Japan - Swift Engineering
    Aug 1, 2018 · Swift-Xi is a Japanese joint venture by Swift Engineering, Inc. headquartered in San Clemente, California, USA and the Kobe Institute of ...
  59. [59]
    Swift Autonomy - Unmatched Tactical Advantage
    ### Summary of Swift Tactical Systems Content
  60. [60]
    Machine Learning Techniques Can Help Enable Intelligent Autopilot
    Jan 28, 2025 · info@swiftengineering.com · Home · Company · Technology · Culture · Press ... | Swift Engineering is a speed-driven, innovation company providing ...Missing: sources | Show results with:sources
  61. [61]
    the Future of Unmanned Aerial Vehicles (UAVs) - Swift Engineering
    Apr 29, 2025 · Swift Engineering is building next-gen UAVs that learn, adapt, and operate independently, using AI and deep reinforcement learning for self- ...Missing: global telepresence
  62. [62]
    Swift Engineering wins NASA SBIR award for SULE UAS - LinkedIn
    Oct 27, 2025 · This collaboration marks a major step forward in Multi-Domain Adaptive Autonomy (MDA2)—bringing precision, resilience, and trusted autonomy to ...
  63. [63]
    Manufacturing - Swift Engineering
    Facilities & Equipment. Swift Engineering's state-of-the-art 60,000sqft facility is located in San Clemente, California. Our facilities have 3 autoclaves ...
  64. [64]
    Swift Engineering Utilizes Composite Tooling with Technology from ...
    Mar 7, 2022 · Swift Engineering uses 3D printed composite tooling to create complex designs that are effective without compromising performance.Missing: early | Show results with:early
  65. [65]
    Non-Linear Dynamic Crash Simulation - Swift Engineering
    Non-Linear Dynamic Crash Simulation. Swift Engineering focused on structural integrity and manufacturing issues within the aerospace, marine, UAV, and ...Missing: facilities static testing
  66. [66]
    US developer and manufacturer of drones. SWIFT Engineering ...
    Dec 18, 2018 · In 2000, the company diversified its business and began work in the aerospace field. It has been involved in the design of vehicles that are ...Missing: history 2000-2010
  67. [67]
    Swift Engineering - Crunchbase Company Profile & Funding
    Swift Engineering is an aviation & aerospace firm providing products, technologies, and fully integrated product development solutions.
  68. [68]
    The Way It Is/ Swift's 2012 Indy car concept - Gordon Kirby
    ... Swift Indy car. Remarkably, Michael Andretti won in the car's debut at Homestead in the spring of 1997 but the early success flattered only to deceive.
  69. [69]
    Swift Engineering CEO and executives - Zippia
    Based on our data team's research, Hiro Matsushita is the Swift Engineering's CEO. Swift Engineering has 500 employees, of which 3 are in a leadership position.
  70. [70]
    Swift Engineering Management Team | Org Chart - RocketReach
    The Swift Engineering management team includes Hamed Khalkhali (President), Rick Schnell (Chief Financial Officer), and Natarajan T (Head of Operations).
  71. [71]
    Swift Engineering Dubbed “Innovator in Aerospace” with IMPACT ...
    Jan 30, 2025 · Most recently, the company achieved a major milestone for its SULE (Swift Ultra Long Endurance, a HAPS platform) aircraft in a flight that ...Missing: projects achievements
  72. [72]
    Customers - Swift Engineering
    Swift Engineering is proud to partner with some of the most prestigious companies in the world. Northrop Grumman. Bell. Boeing. DARPA. Elbit Systems.Missing: partnerships | Show results with:partnerships
  73. [73]
    Swift Joins Sikorsky-Boeing Defiant Team to deliver Next Generation ...
    Mar 30, 2015 · The DEFIANT™ technology demonstrator will feature counter-rotating rigid main rotor blades for vertical and forward flight, a pusher propeller ...
  74. [74]
    SB>1 DEFIANT (JMR) - Swift Engineering
    Weapon System Built for Multi-Domain Operations​​ A major portion of the airframe structure was designed and manufactured at Swift's facility in San Clemente, ...Missing: contributions | Show results with:contributions
  75. [75]
    SpaceX - Swift Engineering
    Manufacture of iridium satellite constellation dispensers. Back to Build to Print Projects · Back to History. Ready to reach new heights?<|control11|><|separator|>
  76. [76]
    Swift Xi - Crunchbase Company Profile & Funding
    is a Japanese joint venture by Swift Engineering, Inc., headquartered in San Clemente, California, USA, and the Kobe Institute of Computing in Kobe, Japan.
  77. [77]
    [PDF] AltaSim Technologies
    Swift Engineering won the prestigious Northrop Grumman Small Business Supplier of the Year award for 2012. Swift was selected from over 1500 suppliers for ...
  78. [78]
    Bat UAS - Swift Engineering
    Northrop Grumman received design and marketing rights from Swift Engineering to the Killer Bee, renamed the Bat in April 2009. The Bat family product line ...Missing: 2002 | Show results with:2002
  79. [79]
    Swift HALE Drone Reaches New Heights with NASA - DRONELIFE
    Sep 9, 2020 · Swift Engineering is banking on the success of the high altitude long endurance (HALE) drone system.Missing: HAPS | Show results with:HAPS
  80. [80]
    Swift HAPS UAS - Swift Engineering
    Developed In Partnership With NASA. The Swift HALE was developed under an SBIR Phase I and II plus internal funds. The aircraft is designed to fly for 100+ ...Missing: spacecraft | Show results with:spacecraft