This article is based on an official press release from AIR via PR Newswire.

On June 3, 2026, Israeli electric vertical takeoff and landing (eVTOL) manufacturer AIR announced a strategic partnership with U.S.-based Dynon Avionics. According to the company’s official press release, Dynon will serve as the exclusive avionics provider across AIR’s entire smart aircraft portfolio.

This collaboration bridges the gap between traditional general aviation and the emerging Advanced Air Mobility (AAM) sector. By adapting Dynon’s widely utilized SkyView HDX flight display system for electric powered-lift operations, AIR aims to streamline the piloting experience for its upcoming vehicles while relying on proven aerospace technology.

The integration agreement covers both the piloted AIR ONE, a two-seat personal eVTOL designed for private ownership, and the uncrewed AIR ONE Cargo, a heavy-lift unmanned aerial system (UAS) utilized by defense and logistics organizations.

Adapting Proven Avionics for Electric Flight

Rather than developing a proprietary flight display from scratch, AIR has opted to customize Dynon’s flagship SkyView HDX avionics platform specifically for its eVTOL architecture. Originally introduced in 2016 for experimental and light sport airplanes, the SkyView HDX system features touchscreens that combine a primary flight display, moving-map navigation, synthetic vision, autopilot, and ADS-B traffic and weather data.

Customizing for eVTOL Operations

Because the AIR ONE utilizes electric propulsion rather than a traditional piston engine, Dynon’s engineering team adapted the SkyView HDX to meet the unique demands of powered-lift flight. According to the release, the customized system tracks electric propulsion metrics and battery energy management, ensuring pilots have clear, intuitive access to critical flight data.

“SkyView HDX is built to adapt to evolving aircraft architectures. Partnering with AIR allows us to take the proven reliability of SkyView HDX, which pilots rely on daily, and extend it directly into the advanced air mobility space.”

AIR’s Path to Commercialization and Manufacturing

AIR is positioning itself uniquely within the AAM market by focusing on personal and cargo air mobility rather than commercial air taxi services. The company’s flagship product, the AIR ONE, is designed as a “flying sports car” for private owners. According to company specifications, the aircraft features a target range of 100 miles, cruise speeds up to 155 mph, and a payload capacity of 550 pounds.

Production and Financial Traction

The avionics partnership comes at a time of significant growth for the Israeli manufacturer. As of March 2026, AIR reported surpassing $1 billion in its order backlog. This figure represents over 3,300 waitlisted customers, including 3,290 reservations specifically for the AIR ONE personal eVTOL. Furthermore, the company stated it has already generated over $35 million in booked revenue, primarily driven by deliveries of its heavy-lift UAS variants.

To support this backlog, AIR transitioned to commercial-scale serial manufacturing in July 2025 by opening a 32,000-square-foot production facility in Pardes Hanna, Israel. The company notes that this facility is capable of assembling up to six aircraft simultaneously.

“From the start, AIR has focused on making advanced flight systems intuitive, safe, and accessible. Working with Dynon allows us to bring proven avionics capability into a fundamentally new aircraft environment that demands more than a standard integration, while keeping the simplicity and operational clarity that define how we think about flight.”

Regulatory Tailwinds: The FAA MOSAIC Rule

The timing of this avionics integration aligns closely with a major regulatory shift in the United States. The Federal Aviation Administration’s (FAA) Modernization of Special Airworthiness Certification (MOSAIC) rule, finalized in July 2025, fundamentally changes how personal aircraft are certified.

Certification Timeline

Previously, Light Sport Aircraft (LSA) regulations excluded powered-lift aircraft and enforced strict weight limits. The MOSAIC rule removes these prescriptive weight limits in favor of performance-based metrics, officially allowing powered-lift aircraft like eVTOLs to be certified in the LSA category. While pilot privileges under MOSAIC took effect in October 2025, the new aircraft certification provisions for manufacturers take effect on July 24, 2026. AIR expects the FAA to approve the AIR ONE under these new rules this year, enabling the company to begin fulfilling its U.S. backlog.

AirPro News analysis

We view this partnership as a prime example of traditional general aviation technology successfully pivoting to support the booming AAM sector. It demonstrates that eVTOL manufacturers do not necessarily need to reinvent the wheel regarding cockpit displays; they can adapt proven, trusted systems to save on development costs and certification hurdles. Furthermore, by integrating a familiar system like Dynon’s SkyView HDX, AIR is strategically lowering the barrier to entry for existing private pilots transitioning to electric aircraft. Finalizing its supply chain and technology stack just ahead of the July 2026 MOSAIC implementation positions AIR favorably to capitalize on the emerging personal eVTOL market.

Frequently Asked Questions (FAQ)

• What is the AIR ONE?
  The AIR ONE is a two-seat personal electric vertical takeoff and landing (eVTOL) aircraft designed for private ownership. It features a target range of 100 miles and cruise speeds up to 155 mph.
• Why did AIR partner with Dynon Avionics?
  AIR selected Dynon to adapt its proven SkyView HDX flight display system for electric powered-lift operations, providing pilots with a familiar, reliable, and intuitive interface for tracking electric propulsion and battery management.
• When will the AIR ONE be available in the U.S.?
  AIR expects to receive FAA approval for the AIR ONE this year under the new MOSAIC regulations, which take effect for manufacturers on July 24, 2026. This certification will allow the company to begin fulfilling its U.S. order backlog.

Sources: AIR via PR Newswire

This article is based on an official statement from Robinson Helicopter Company.

Unither Bioélectronique has successfully completed the world’s first piloted hydrogen-electric Helicopters circuit flight in Québec, marking a significant milestone in zero-emission aviation. The historic flight was achieved using a modified Robinson R44 helicopter as part of the ongoing Project Proticity initiative.

According to an official company press release, the milestone serves as a critical proof of concept for the future of clean vertical lift. The company emphasized the dual benefits of the new propulsion system combined with established airframes.

“This successful demonstration highlights the potential of hydrogen-electric Propulsion to deliver zero-emission flight while building on the proven reliability and cost efficiency that Robinson helicopters have come to define,” the company stated in its release.

The achievement represents a major step forward from initial hover tests, moving the technology closer to real-world applications. Industry reports indicate that the ultimate goal of this technology is to create a scalable, zero-emission transportation network for critical medical deliveries.

Project Proticity and the Historic Flight

Flight Details

The milestone circuit flight took place on April 10, 2026, at Roland-Désourdy Airport in Bromont, Québec, with Unither Bioélectronique test pilot Ric Webb at the controls. According to industry reporting by Vertical Magazine and Skies Mag, the flight advanced the company’s testing from a basic hover demonstration, first achieved in March 2025, to a full airport traffic circuit. This comprehensive flight profile included a controlled takeoff, climb, pattern flight, approach, and landing, all conducted under an experimental flight permit.

The Technology

The modified Robinson R44 test aircraft was equipped with a Hydrogen-electric proton exchange membrane (PEM) fuel-cell and battery architecture. The system was powered by locally produced green hydrogen, replacing the traditional piston engine. In its press release, Unither Bioélectronique highlighted that the demonstration showcases the potential of hydrogen-electric propulsion to deliver zero-emission flight without sacrificing operational reliability.

Future Implications for Zero-Emission Aviation

Scaling to the R66

Project Proticity, a collaboration between Unither Bioélectronique and Robinson Helicopter Company announced in August 2024, is not stopping at the R44 airframe. According to reporting by Aviation International News, the partners intend to scale the hydrogen-electric architecture to the larger Robinson R66 platform. Future phases of development are expected to integrate a liquid hydrogen storage system. This upgrade could significantly extend the aircraft’s range compared to the current gaseous hydrogen setup, with industry estimates from Vertical Magazine suggesting a potential range of around 100 nautical miles.

Organ Delivery Mission

Unither Bioélectronique operates as a subsidiary of United Therapeutics. Public remarks and company statements from previous milestones reveal that the intended end-use for these zero-emission helicopters is the rapid transport of manufactured organs to transplant patients. By utilizing hydrogen propulsion, the company hopes to establish a clean, efficient logistics network for life-saving medical supplies across North-America.

AirPro News analysis

The transition from a three-minute hover test in early 2025 to a full circuit flight in April 2026 demonstrates a rapid maturation of Unither Bioélectronique’s PEM fuel-cell technology. However, scaling this architecture to the Robinson R66 and transitioning to liquid hydrogen will introduce new thermal management and storage complexities. Furthermore, achieving Certification from Transport Canada Civil Aviation and the U.S. Federal Aviation Administration (FAA) remains a critical hurdle before these aircraft can enter commercial service for organ delivery. We will continue to monitor the regulatory progress of Project Proticity as it moves toward commercialization.

Frequently Asked Questions

What is Project Proticity?

Project Proticity is a collaborative development program between Unither Bioélectronique and Robinson Helicopter Company aimed at creating zero-emission, hydrogen-electric helicopters based on the Robinson R44 and R66 models.

When did the first circuit flight take place?

The world’s first piloted hydrogen-electric helicopter circuit flight was conducted on April 10, 2026, at Roland-Désourdy Airport in Bromont, Québec.

What is the ultimate goal of these hydrogen helicopters?

Unither Bioélectronique plans to use these zero-emission helicopters to transport manufactured organs for transplant patients across a scalable transportation network.

Sources: Robinson Helicopter Company

This article is based on an official press release from Vaeridion.

Electric aircraft manufacturer Vaeridion has announced the selection of Garmin avionics to equip the initial test articles of its fully electric Microliner. According to a company press release, the manufacturer will integrate Garmin’s G600 TXi flight displays into the test aircraft, marking a critical milestone as the company prepares for its inaugural flight.

The integration of established avionics is a key step in advancing the development of the Microliner. Vaeridion has stated that the aircraft is currently targeted to enter commercial service in 2030, aiming to bring zero-emission commercial flights to the regional aviation market.

Advancing the Microliner Test Campaign

Avionics Selection and Integration

In its official announcement, Vaeridion highlighted that the Garmin G600 TXi flight display was chosen for its flexible integration and proven performance. The system features a modern touchscreen interface designed to enhance situational awareness and operational efficiency for test pilots.

Company officials noted that Garmin’s safety systems set a benchmark in the sector, making the G600 TXi an ideal foundation not only for the upcoming flight-test campaign but also for future cockpit developments.

“Equipping the Microliner with a best-in-class avionics suite from Garmin was a natural choice for us,”

stated Markus Kochs-Kämper, Chief Technology Officer at Vaeridion, in the press release. He added that the system provides the reliability and flexibility required for a rigorous flight-test program.

Garmin also expressed enthusiasm for the partnership. In the release, Carl Wolf, Garmin’s Vice President of Aviation Sales, Marketing, Programs & Support, noted the benefits of the integration:

“The advanced flight display capabilities coupled with a touchscreen interface provide a modern solution and safety-enhancing technologies to the aircraft,”

Wolf stated.

Scaling Up for First Flight

Recent Infrastructure Milestones

Beyond the avionics selection, Vaeridion is actively scaling its physical infrastructure to support the Microliner’s development timeline. According to the company’s statement, the manufacturer recently inaugurated a new battery manufacturing facility and test house.

Located at the Oberpfaffenhofen special airport, this new facility is intended to strengthen Vaeridion’s vertical integration. The company emphasized that expanding its in-house capabilities allows for greater control over critical technologies as it pushes toward its first-flight and subsequent certification phases.

AirPro News analysis

We view Vaeridion’s decision to partner with an established avionics provider like Garmin as a strategic move to mitigate risk during the flight-test phase. By utilizing off-the-shelf, certified components such as the G600 TXi, electric aircraft startups can focus their engineering resources on their core proprietary technologies, namely, the electric propulsion and battery systems.

The 2030 target for commercial service remains ambitious but aligns with the broader industry timeline for next-generation regional aircraft. The recent opening of the battery facility at Oberpfaffenhofen further indicates that Vaeridion is transitioning from conceptual design to physical hardware testing, a critical phase where supply chain and integration partnerships become paramount.

Frequently Asked Questions

What avionics system will the Vaeridion Microliner use?

According to the company’s press release, the initial test aircraft will be equipped with Garmin G600 TXi flight displays.

When is the Vaeridion Microliner expected to enter service?

Vaeridion has stated that the fully electric Microliner is slated to enter commercial service in 2030.

Where is Vaeridion’s new battery facility located?

The company recently opened a battery manufacturing facility and test house at the Oberpfaffenhofen special airport.

Sources

• Vaeridion