Technology & Innovation
Joby Aviation and Metropolis Develop 25 US Vertiports for eVTOL Launch
Joby Aviation partners with Metropolis Technologies to retrofit parking garages into 25 vertiports across US cities, supporting a 2026 eVTOL commercial launch.
This article is based on an official press release from Joby Aviation.
Joby Aviation has announced a significant infrastructure partnership with Metropolis Technologies to develop a network of 25 vertiports across the United States. The collaboration aims to repurpose existing parking infrastructure into “mobility hubs” to support the commercial launch of electric vertical takeoff and landing (eVTOL) aircraft.
According to the company’s announcement, the partnership will leverage Metropolis’s extensive portfolio of parking facilities to create takeoff and landing sites in key metropolitan areas. By retrofitting existing structures rather than building new terminals from the ground up, Joby intends to accelerate the deployment of its air taxi service, which is currently targeting a commercial launch in 2026.
The initiative addresses one of the most critical challenges in the Urban Air Mobility (UAM) sector: the “last mile” connection. The integration of ground and air travel is designed to offer passengers a seamless transition from their vehicles to Joby’s aircraft, utilizing advanced artificial intelligence to streamline the process.
The core strategy of this partnership involves identifying and upgrading sites within Metropolis’s network, which expanded significantly following its recent acquisition of SP+. With access to over 4,200 parking facilities, the companies plan to select prime locations in high-density urban centers such as Los Angeles, San Francisco, and New York City.
Joby Aviation stated that this retrofit approach offers a distinct advantage over constructing standalone vertiports. By utilizing the top decks of existing parking garages, the partners can reduce upfront construction costs and navigate zoning requirements more efficiently. These sites will be designed to meet the Federal Aviation Administration’s (FAA) Engineering Brief 105A, which outlines the specific design standards for vertiport geometry, marking, and load-bearing capacity.
“For air taxis to deliver on their promise of seamless urban travel, they must connect directly with the existing ground transportation ecosystem. By leveraging existing parking infrastructure… we can maximize the value of those sites without needing to build infrastructure from scratch.”
, JoeBen Bevirt, Founder and CEO of Joby Aviation
Beyond physical infrastructure, the partnership emphasizes the integration of Metropolis’s proprietary technology. The company utilizes AI-powered computer vision to manage facility access and payments. In the context of air travel, this technology aims to facilitate a “drive-in, fly-out” experience. According to the release, cameras will recognize a passenger’s vehicle upon entry, automatically processing parking fees and initiating the check-in process for their flight. This system is intended to eliminate the need for physical tickets, gates, or kiosks, aligning with the industry’s push for a frictionless passenger experience.
“The real world is the next frontier for AI… We are taking the data and recognition capabilities we’ve built in our network and extending it to air travel, creating the seamless, personalized, and magical experience that is the foundation of the Recognition Economy.”
, Alex Israel, CEO of Metropolis Technologies
While the construction of full vertiports is a longer-term project targeting 2026, the partnership includes immediate operational steps. Metropolis subsidiary Bags Inc. will begin providing VIP baggage handling services for Blade Urban Air Mobility, a partner of Joby Aviation, in New York City. This service will support flights between Manhattan and major airports such as JFK and Newark.
Los Angeles has been identified as a primary market for the initial vertiport rollout. The companies are currently evaluating downtown parking structures that can be adapted to support high-frequency air taxi operations. This focus on Los Angeles aligns with Joby’s broader strategy to establish a foothold in regions with high traffic congestion, where the time-saving value of eVTOL aircraft is most apparent.
We observe that this partnership represents a divergent strategy in the race for UAM infrastructure. While competitors like Archer Aviation have partnered with Atlantic Aviation to electrify existing private aviation terminals (FBOs), Joby is betting on bringing aircraft closer to the consumer’s daily commute via parking garages.
The “retrofit” model proposed by Joby and Metropolis may offer scalability advantages. Parking garages are ubiquitous in city centers, whereas private air terminals are typically located on the periphery at airports. If successful, this approach could allow Joby to penetrate dense urban cores more deeply than competitors relying solely on airport-based infrastructure.
However, we note that retrofitting parking decks presents its own engineering challenges, particularly regarding the structural reinforcement required to handle the weight and dynamic loads of landing aircraft, as well as the installation of high-voltage charging infrastructure in older buildings.
Transforming Parking Garages into Mobility Hubs
Integration of AI Technology
Immediate Rollout and Strategic Markets
AirPro News Analysis
Frequently Asked Questions
Sources
Photo Credit: Joby Aviation
Technology & Innovation
H55 Completes First EASA Battery Certification Tests in Aviation
H55 successfully passes all EASA-required propulsion battery certification tests, advancing electric aviation safety and production readiness.
This article is based on an official press release from H55.
H55, the Swiss electric aviation company spun off from the Solar Impulse project, announced it has successfully completed the full sequence of propulsion battery module certification tests required by the European Union Aviation Safety Agency (EASA). The milestone, achieved on December 19, 2025, marks a significant step forward for the sector, addressing the critical safety challenge of thermal runaway containment in high-energy lithium-ion batteries.
According to the company, this is the first time in the aviation industry that a propulsion battery module has passed these rigorous, authority-witnessed tests using serial-conforming hardware. The successful campaign clears the path for H55 to submit final test reports to EASA in the first quarter of 2026, with commercial entry-into-service projected for early 2027.
The primary hurdle for certifying electric-aviation has long been the safety of high-energy density batteries. Regulators require proof that if a single cell catches fire (a process known as thermal runaway), the failure will not propagate to neighboring cells or cause a catastrophic explosion. H55 reports that its “Adagio” battery module successfully demonstrated this containment capability under EASA supervision.
Instead of relying on heavy containment boxes, which add prohibitive weight to airframes, H55 utilizes a patented encapsulation technology. This system manages each cell individually, directing released energy and hot gases out of the module through a specific venting path. This approach prevents heat from triggering adjacent cells, effectively neutralizing the risk of propagation.
“Electric aviation has faced a single, unresolved bottleneck: proving to regulators that high-energy propulsion batteries can safely contain worst-case failures. Rather than attempting to contain a thermal runaway by shielding… H55 opts for a different approach, preventing fire propagation at the cell level.”
, André Borschberg, Co-Founder of H55
The tests were conducted on H55’s Adagio battery modules, which utilize commercial 21700 lithium-ion cells, a standard cylindrical format adapted for aviation safety. The company states the modules achieve an energy density of approximately 200 Wh/kg. Crucially, the tests utilized production-grade units rather than experimental prototypes, signaling that H55’s manufacturing lines in Sion, Switzerland, are ready for mass production.
In addition to the physical battery architecture, the system includes a redundant Battery Management System (BMS) capable of monitoring the voltage, temperature, and health of every single cell in real-time. While major eVTOL developers like Joby Aviation and Beta Technologies have made significant progress with flight testing, much of the industry has operated under experimental permits or is currently navigating the earlier stages of certification. H55’s completion of the specific battery module test sequence positions it as a critical supplier for airframers who prefer to integrate certified components rather than developing proprietary battery systems. Furthermore, the move from theoretical safety models to empirical, regulator-witnessed data is expected to assist insurers in transitioning from estimated risk models to actuarial data, potentially lowering premiums for electric fleets.
H55 holds both Design Organization Approval (DOA) and Production Organization Approval (POA) from EASA. The company is currently working with a joint Certification Management Team involving EASA and the U.S. Federal Aviation Administration (FAA). Under mutual recognition agreements, the data generated from the EASA tests is intended to support “fast-track” approval for operations in North America.
To demonstrate the technology’s reliability to the North American market, H55 has announced an “Across America” tour for 2025. The company will fly its Bristell B23 Energic, a two-seater electric trainer aircraft equipped with the Adagio system, across the United States to engage with flight schools and operators.
H55 is also establishing a new production facility in Montreal, Canada, to serve customers in the region.
Sources: PR Newswire / H55
H55 Completes Aviation Industry’s First EASA-Required Battery Certification Tests
Solving the Thermal Runaway Challenge
Technical Specifications and Production Readiness
AirPro News analysis
Regulatory Pathway and North American Expansion
Sources
Photo Credit: H55
Technology & Innovation
Horizon Aircraft Selects RAMPF for Cavorite X7 Fuselage Production
Horizon Aircraft chooses RAMPF Composite Solutions to manufacture the fuselage of the Cavorite X7 hybrid-electric eVTOL, targeting prototype assembly in 2026.
This article is based on an official press release from Horizon Aircraft.
Horizon Aircraft (NASDAQ: HOVR) has officially selected RAMPF Composite Solutions to manufacture the fuselage for its full-scale Cavorite X7 hybrid-electric eVTOL. Announced on January 29, 2026, this Partnerships marks a critical transition from design to physical production for the Canadian aerospace company.
The agreement tasks RAMPF with constructing the main body of the aircraft using advanced lightweight carbon fiber and fiberglass materials. According to the company’s statement, this collaboration is a prerequisite for meeting Horizon’s aggressive timeline: assembling the full-scale prototype in 2026 and commencing flight testing in early 2027.
A key factor in this selection appears to be geographic proximity. Both Horizon Aircraft and RAMPF Composite Solutions are based in Ontario, Canada, with RAMPF operating out of Burlington. Horizon CEO Brandon Robinson noted that this localization allows for tighter quality control and real-time engineering collaboration, which are often logistical bottlenecks in aerospace development.
RAMPF Composite Solutions, a subsidiary of the German-based RAMPF Group, specializes in manufacturing complex composite parts for the aerospace and defense sectors. Their scope of work involves creating a fuselage capable of withstanding high-impact forces and harsh environmental conditions while adhering to the strict weight limits required for electric flight.
“We are thrilled to partner with Horizon Aircraft on this revolutionary new aircraft. This opportunity allows us to demonstrate how our high-performance composite materials and Manufacturing processes can push the boundaries of engineering.”
Larry Fitzgerald, CEO of RAMPF Composite Solutions
Brandon Robinson, CEO of Horizon Aircraft, emphasized the importance of RAMPF’s track record in the industry:
“RAMPF’s aerospace manufacturing capabilities are industry-leading, and we are excited to see the fuselage of our Cavorite X7 coming to life.”
Brandon Robinson, CEO of Horizon Aircraft
The Cavorite X7 is designed to operate in the Regional Air Mobility (RAM) market rather than the intra-city air taxi market targeted by many competitors. The aircraft features a seven-seat configuration (one pilot and six passengers) and utilizes a hybrid-electric Propulsion system. This system employs a gasoline engine to generate electricity, which powers the flight fans and recharges the battery pack, effectively mitigating the range anxiety associated with pure electric platforms.
According to Horizon’s official specifications, the aircraft targets a range of approximately 800 kilometers (500 miles) and a top speed of 450 km/h (280 mph). The design utilizes a patented “Fan-in-Wing” system, where vertical lift fans are covered by sliding panels during forward flight, allowing the vehicle to fly efficiently like a traditional fixed-wing airplane.
The move to commission fuselage manufacturing is a significant indicator of technical maturity. In aerospace engineering, committing to hard tooling and physical production of the primary structure, the fuselage, typically signals that the outer mold line (OML) and internal structural architecture are “frozen.”
Furthermore, by securing a partner with defense and aerospace pedigree like RAMPF, Horizon is likely positioning itself to meet the rigorous Certification standards of Transport Canada and the FAA. The choice of a hybrid system also differentiates Horizon in a crowded market; while competitors struggle with battery density limits, the Cavorite X7’s hybrid architecture allows it to utilize existing aviation infrastructure immediately upon entry into service.
This manufacturing announcement follows a recent financial update from Horizon Aircraft on January 14, 2026. The company reported a cash position of over $24 million, which management states is sufficient to fund operations through 2026. Additionally, the company was recently awarded a grant of approximately $10.5 million from the Initiative for Sustainable Aviation Technology (INSAT) to support the development of all-weather flight systems.
With funding secured for the near term and the supply chain for major components now activating, Horizon appears on track to meet its goal of a flying full-scale prototype by early 2027.
Horizon Aircraft Taps RAMPF Composite Solutions for Cavorite X7 Fuselage Manufacturing
Strategic Localization of the Supply Chain
The Cavorite X7: Technical Context
AirPro News Analysis: Maturity of Design
Financial and Operational Outlook
Sources
Photo Credit: Horizon Aircraft
Technology & Innovation
AutoFlight Completes Transition Flight for 5-Ton Matrix eVTOL
AutoFlight’s V5000 Matrix eVTOL completed a full transition flight, marking a milestone for heavy-lift electric aircraft with 10-passenger capacity.
This article summarizes reporting by AeroTime.
AutoFlight has successfully completed a full transition flight with its V5000 “Matrix” aircraft, marking a significant milestone in the development of heavy-lift electric vertical takeoff and landing (eVTOL) technology. According to reporting by AeroTime, the demonstration took place at the company’s test center in Kunshan, China, around February 5, 2026.
The event represents a major technical breakthrough for the sector. While several manufacturers have achieved transition flights with smaller air taxis, the Matrix is reportedly the world’s first 5-ton class eVTOL to perform the complex maneuver. The flight profile involved a vertical takeoff, a transition to wing-borne horizontal flight, and a return to vertical mode for landing.
The transition phase, switching from rotor-supported lift to wing-supported lift, is widely regarded as the most critical aerodynamic challenge for eVTOL aircraft. Successfully executing this phase with a heavy airframe validates the scalability of AutoFlight’s electric-aviation propulsion technology.
According to manufacturer specifications cited in the report, the V5000 “Matrix” is significantly larger than the 4-to-5-seat air taxis currently being developed by Western competitors like Joby Aviation and Archer Aviation. The aircraft features a maximum takeoff weight (MTOW) of approximately 5,700 kilograms (5.7 tons) and a wingspan of roughly 20 meters.
AutoFlight has designed the Matrix to serve both passenger and cargo-aircraft markets with a focus on regional connectivity rather than just intra-city hops. Key specifications include:
The successful flight of the Matrix distinguishes AutoFlight in a crowded market. While U.S. and European firms are largely focused on the 1.5-to-2-ton class of aircraft intended for urban air mobility, AutoFlight is pursuing a “heavy-lift” strategy.
Industry data indicates that the larger capacity of the Matrix could allow for different economic models. By carrying 10 passengers instead of four, the aircraft may offer a lower cost-per-seat-mile, potentially making regional air travel more accessible. Additionally, the cargo variant targets heavy logistics and offshore supply chains, sectors that smaller eVTOLs cannot efficiently serve.
AutoFlight, founded by Tian Yu, operates R&D centers in Shanghai, Kunshan, and Augsburg, Germany. The company previously secured type Certification from the Civil Aviation Administration of China (CAAC) for its smaller “CarryAll” cargo drone in 2024. The Shift Toward Regional Mobility
AutoFlight’s achievement with the V5000 Matrix suggests a potential pivot in the Advanced Air Mobility (AAM) sector. Until now, the dominant narrative has focused on “air taxis” replacing cars for short city trips. However, the physics and economics of a 5-ton, 10-passenger aircraft point toward a “regional shuttle” model, replacing buses or trains for inter-city travel.
We observe that by targeting the heavy-lift segment, AutoFlight is effectively creating a new vehicle class that sits between a helicopter and a regional turboprop. If the company can certify this platform, it may bypass the intense competition for urban vertiport space that smaller competitors face, instead utilizing existing regional airports and industrial hubs.
What is a transition flight? How does the Matrix compare to other eVTOLs? When did this flight occur? Sources: AeroTime, AutoFlight
AutoFlight Completes Transition Flight for 5-Ton “Matrix” eVTOL
Breaking the Weight Barrier
Technical Specifications
Strategic Positioning in the AAM Market
AirPro News Analysis
Frequently Asked Questions
A transition flight is when an eVTOL aircraft switches from vertical flight (using rotors like a helicopter) to horizontal flight (using wings like an airplane). It is considered the most technically difficult phase of flight.
Most leading competitors, such as Joby or Archer, are building aircraft in the 2-ton class with 4-5 seats. The AutoFlight Matrix is a 5-ton class aircraft designed for 10 passengers or heavy cargo.
The demonstration was reported to have occurred around February 5, 2026.
Photo Credit: Sergio Cecutta – SMG Consulting
-
Commercial Aviation3 days agoAirbus Nears Launch of Stretched A350 Variant to Compete with Boeing 777X
-
Aircraft Orders & Deliveries4 days agoHarbor Diversified Sells Air Wisconsin Assets for $113.2 Million
-
MRO & Manufacturing4 days agoFedEx A300 Nose Gear Collapse During Maintenance at BWI Airport
-
Defense & Military4 days agoAirbus and Singapore Complete Manned-Unmanned Teaming Flight Trials
-
Sustainable Aviation6 days agoAsia-Pacific Aviation Growth and Sustainable Aviation Fuel Initiatives 2026