This article is based on an official press release from Aerovecto Aviation Services and Vigelon via Zawya.

Aerovecto and Vigelon Sign MoU to Establish Digital Maintenance Infrastructure for Oman’s eVTOL Sector

MUSCAT, OMAN, Aerovecto Aviation Services (AVAS) has signed a Memorandum of Understanding (MoU) with Canadian aviation software provider Vigelon to localize advanced predictive maintenance technology in the Sultanate of Oman. The agreement, signed on January 20, 2026, aims to establish a digital safety framework for the country’s emerging electric vertical takeoff and landing (eVTOL) and drone sectors.

According to the joint announcement, this partnership positions AVAS as the primary local distributor and partner for Vigelon’s AI-driven fleet management software. The collaboration is designed to support the high-frequency, short-hop flight operations anticipated in the Advanced Air Mobility (AAM) market by ensuring regulatory compliance and maximizing aircraft uptime.

The deal aligns with Oman Vision 2040, the national roadmap focused on diversifying the economy through knowledge-based industries and sustainable transport solutions. By integrating Canadian artificial intelligence with local aviation expertise, the partners intend to create a “digital backbone” for Oman’s skies.

“This partnership represents more than a distribution agreement, it’s about building the foundation for safe, efficient, and sustainable eVTOL operations in Oman. By combining Vigelon’s innovative technology with our local expertise, we are positioning Oman as a leader in advanced air mobility services.”

Fahad Al Riyami, CEO of Aerovecto Aviation Services

Strategic Localization of Aviation Technology

Aerovecto Aviation Services, the services arm of the Omani aerospace entity SkyCrest Aviation, launched in December 2025. While its parent company focuses on manufacturing aircraft, AVAS is tasked with developing the ecosystem required to keep them flying, including vertiport management and Maintenance, Repair, and Overhaul (MRO).

Under the terms of the MoU, AVAS will leverage Vigelon’s software to offer a comprehensive support system for operators. This move addresses a critical gap in the regional market: while many entities are focused on acquiring aircraft, the infrastructure for maintaining complex electric propulsion systems remains in development.

The Role of AI in Maintenance

Vigelon, headquartered in Ottawa, Canada, specializes in Software-as-a-Service (SaaS) solutions for the aviation industry. Their platform utilizes algorithms to analyze sensor data from aircraft, predicting component failures before they occur. This shift from reactive to proactive maintenance is considered essential for eVTOL fleets, which rely on high-voltage battery systems and multiple electric motors.

According to the press release, the software also automates compliance reporting, a feature designed to help operators meet the stringent audit requirements of aviation authorities.

“Together, we will deliver revolutionary maintenance solutions that support operators and regulators in shaping the future of air mobility in the region.”

Ali Taleb, CEO of Vigelon

Market Context and Regulatory Landscape

The partnership comes as Oman accelerates its regulatory efforts to accommodate novel aircraft. The Civil Aviation Authority (CAA) has authorized a “Proof-of-Concept” program scheduled to begin in the first quarter of 2026. This program includes live trials involving hybrid-electric aircraft for logistics and industrial applications.

Oman has adopted the JARUS/SORA (Joint Authorities for Rulemaking on Unmanned Systems / Specific Operations Risk Assessment) package. This risk-based regulatory model allows for the approval of complex drone and eVTOL operations by assessing specific operational risks rather than applying blanket restrictions.

Regional Growth Projections

Data cited in the announcement suggests the Middle East eVTOL market is forecast to grow at a Compound Annual Growth Rate (CAGR) of 52.5% through 2030. This growth is driven by regional “Smart City” initiatives and a push to alleviate ground traffic congestion in expanding urban centers like Muscat.

AirPro News Analysis

While the spotlight in the Advanced Air Mobility sector often falls on the aircraft manufacturers, the “picks and shovels” of the industry, maintenance, software, and infrastructure, are becoming increasingly vital. The AVAS-Vigelon deal highlights a maturing market where operators are looking beyond the initial purchase of air taxis to the long-term realities of fleet sustainment.

Furthermore, Aerovecto’s development of “The Shuttle”, a hybrid-electric aircraft reportedly designed for high-density seating (approx. 18 seats) and short regional hops, suggests a divergence from the luxury air taxi model seen elsewhere. By securing a predictive maintenance partner early, AVAS appears to be preparing for high-cycle public transport operations where reliability is paramount.

Sources

• Zawya (Press Release)

This article is based on an official press release from Vertical Aerospace and additional market research data.

Vertical Aerospace Debuts “Valo” in New York, Outlines 2028 Launch Strategy

Vertical Aerospace (NYSE: EVTL) has officially introduced its production aircraft, named “Valo,” to the United States market, marking a significant milestone in the company’s commercialization strategy. In an announcement made on January 21, 2026, the company unveiled plans to establish New York City as a critical Launch market for its electric vertical take-off and landing (eVTOL) services.

The debut includes a public display of the aircraft at the Classic Car Club Manhattan. According to the company’s press release, this move signals a shift from prototype testing to preparing for commercial operations, with a targeted entry into service by 2028. Vertical Aerospace is positioning the Valo not merely as a concept, but as a “certification-ready” evolution of its previous VX4 prototype.

The “Valo” Aircraft: Specs and Hybrid Expansion

The Valo represents the finalized design intended for mass production. Vertical Aerospace states that the aircraft is designed to meet “airliner-level” safety standards, a critical requirement for operating in dense urban environments like New York and London.

According to the technical specifications released by the company, the Valo features:

• Capacity: Pilot plus four passengers (expandable to six).
• Range: Up to 100 miles on a single charge.
• Speed: Top speeds of 150 mph.
• Emissions: Zero operating emissions for the all-electric model.

In a notable strategic update, Vertical Aerospace also confirmed it is developing a hybrid-electric variant of the Valo. This version is intended to offer increased range and mission flexibility, potentially targeting defense, logistics, and longer regional routes that pure battery-electric aircraft cannot currently serve efficiently.

Planned New York Route Network

Vertical Aerospace, in collaboration with its operating partner Bristow Group, outlined a specific network of routes designed to connect key transit hubs and premium destinations in the tri-state area. The proposed network relies heavily on existing infrastructure upgrades currently underway.

The planned routes include:

• Airport Shuttles: Connecting John F. Kennedy International Airport (JFK) directly to Manhattan.
• Regional Connections: Flights to East Hampton Airport, targeting the high-demand premium traveler market.
• Event Access: Routes to MetLife Stadium via Teterboro Airport to facilitate game-day transport.
• Urban Transfers: Cross-town flights utilizing the Downtown Skyport (formerly the Downtown Manhattan Heliport).

Infrastructure development is being led by Skyports Infrastructure. Skyports, in a joint venture with Groupe ADP, is currently managing the upgrade of the Downtown Manhattan Heliport to include eVTOL charging capabilities, with completion targeted for later in 2026.

“New York is a natural next step to explore how electric aviation could support urban and regional travel in the US, working with partners like Bristow and Skyports to keep safety, certification and real-world operations at the core.”

, Stuart Simpson, CEO of Vertical Aerospace

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AirPro News Analysis: The 2028 Timeline vs. Competitors

Vertical Aerospace’s confirmation of a 2028 Certification and service entry target places it on a different trajectory than its primary U.S. competitors. While Joby Aviation and Archer Aviation have aggressively targeted 2026 for initial commercial operations, leveraging Partnerships with Delta and United Airlines, respectively, Vertical appears to be taking a more conservative approach.

By targeting 2028, Vertical may be prioritizing a “certification-first” strategy over being the first mover. This timeline allows for the maturation of the Downtown Skyport infrastructure, which Skyports expects to have ready by 2026. Furthermore, the introduction of a hybrid variant suggests Vertical is hedging its bets against battery density limitations, potentially opening up revenue streams in the defense and cargo sectors that strictly urban air taxi competitors might miss.

However, financial pressure remains a factor. Market reports indicate the company has a cash runway extending into mid-2026. Bridging the gap between 2026 and the 2028 commercial launch will likely require disciplined capital management or additional fundraising.

Strategic Partnerships

Vertical Aerospace is utilizing an asset-light model by partnering with established operators rather than building its own consumer-facing airline. Bristow Group, a global leader in vertical flight solutions, will serve as the operator for the Valo aircraft. This partnership allows Vertical to leverage Bristow’s existing regulatory certificates and operational experience.

Simultaneously, the collaboration with Skyports ensures that the physical ground infrastructure, vertiports, will be compatible with the Valo aircraft upon launch. This ecosystem approach is designed to reduce the operational burden on Vertical Aerospace as it focuses on manufacturing and certification.

Frequently Asked Questions

When will Vertical Aerospace launch in New York?
The company is targeting full regulatory certification and entry into service by 2028.

Who will fly the aircraft?
The aircraft will be piloted. Bristow Group has been selected as the operating partner to manage the flights.

What is the difference between the Valo and the VX4?
The Valo is the commercial, production-ready evolution of the VX4 prototype, featuring a redesigned airframe, improved aerodynamics, and an under-floor battery system.

Sources

• Vertical Aerospace Press Release

This article is based on an official press release from Argonne National Laboratory.

Argonne National Laboratory and Spirit AeroSystems Unveil AI Tool for Aerospace Inspections

A new collaboration between government research facilities and private industry aims to resolve one of the most persistent bottlenecks in modern Commercial-Aircraft manufacturing: the inspection of composite materials. On January 7, 2026, Argonne National Laboratory (ANL) announced the development of an artificial intelligence tool designed to accelerate the analysis of ultrasonic scans, a move they report will significantly reduce production time and energy consumption.

The project, led by ANL in partnership with Spirit AeroSystems, Northern Illinois University, and Texas Research Institute Austin, utilizes advanced machine learning to assist human inspectors. According to the laboratory’s announcement, the tool reduces human inspection time by 7% and cuts facility-level energy usage by approximately 3% per aircraft.

Addressing the Composite Challenge

Modern aerospace engineering relies heavily on composite materials due to their superior strength-to-weight ratios. However, verifying the structural integrity of these materials is a data-intensive process. Manufacturers typically use ultrasonic non-destructive testing (NDT) to scan components, generating massive datasets that human experts must manually review to identify defects.

Argonne National Laboratory describes this manual review process as time-consuming and mentally fatiguing. To address this, the research team utilized the Argonne Leadership Computing Facility (ALCF), a U.S. Department of Energy Office of Science user facility, to develop a solution based on Convolutional Neural Networks (CNNs).

According to the technical details released by the laboratory, the AI model does not replace human inspectors. Instead, it functions as an intelligent assistant that rapidly processes scan data to highlight “regions of interest.”

“It rapidly processes scan data and highlights specific areas that contain potential defects or anomalies. This allows human experts to focus their attention solely on ‘regions of interest’ rather than reviewing empty or flawless data.”

— Argonne National Laboratory Announcement

Operational and Environmental Benefits

The integration of this technology offers measurable gains in both efficiency and Sustainability. Spirit AeroSystems, a major aerostructures manufacturer, provided the proprietary dataset of ultrasonic scans used to train the model. The resulting tool has demonstrated the ability to shorten the overall production flow time.

Efficiency Gains

By automating the initial screening of ultrasonic data, the tool reduces the time human inspectors spend on each component by 7%. In high-volume manufacturing environments, this reduction allows for increased throughput and helps alleviate production backlogs.

Energy Reduction

Perhaps most notably, the efficiency gains translate directly into energy savings. The announcement states that the tool lowers energy use by roughly 3% per aircraft. This reduction is achieved at the facility level; shorter inspection times mean that heavy machinery, HVAC systems, and lighting operate for fewer hours per unit produced.

AirPro News Analysis

The deployment of this AI tool highlights a critical shift in the aerospace sector’s approach to “Industry 4.0.” While much of the past decade’s innovation focused on physical Automation, such as robotic drilling or fastening, the current frontier is digital automation.

We observe that the bottleneck in composite manufacturing has shifted from layup (placing the material) to verification (proving the material is safe). As aircraft designs become increasingly complex, the volume of NDT data is outpacing human capacity to review it. The “human-in-the-loop” approach taken by Argonne and Spirit AeroSystems is significant because it mitigates the regulatory hurdles associated with fully autonomous inspection. By keeping the human inspector as the final authority, manufacturers can likely integrate these tools faster than if they sought to replace the human entirely.

Furthermore, the “open-framework” nature of the underlying techniques, mentioned in the release as being available for academic research, suggests that this methodology could soon expand beyond aerospace into wind energy and automotive sectors, where composite usage is also rising.

Partnership Details

The success of this initiative relied on a multi-sector collaboration. While Argonne provided the supercomputing power and machine learning expertise, Spirit AeroSystems supplied the domain knowledge and real-world data necessary to train the AI effectively. Northern Illinois University and Texas Research Institute Austin contributed to validating the technology’s robustness and reliability.

Rajkumar Kettimuthu, a Senior Scientist and Group Leader at Argonne, emphasized the collaborative nature of the work in the official release, noting the combination of industrial constraints and high-performance computing.

Sources

• Argonne National Laboratory