This article is based on an official press release from Collins Aerospace.

Collins Aerospace, a division of RTX, has secured multiple contracts from Bell Textron to supply five essential systems for the U.S. Army’s MV-75 Future Long Range Assault Aircraft (FLRAA). The announcement, made on April 13, 2026, marks a significant step forward in the supply chain development of the Army’s next-generation rotorcraft.

The MV-75 FLRAA represents the U.S. Army’s first clean-sheet rotorcraft design in a generation. According to the official press release, the new military-aircraft is projected to deliver twice the speed and range of the military’s current fleet, fundamentally transforming operational capabilities for future missions.

By leveraging commercial acquisition authorities, Collins Aerospace aims to integrate military-grade commercial technology into the FLRAA program. This procurement approach is designed to accelerate delivery and ensure the long-term sustainment of the aircraft over the coming decades.

Critical Systems and Manufacturing

Under the newly announced agreements, Collins Aerospace will provide a suite of five critical components for the MV-75. As detailed in the company’s statement, these systems include the main power generation, the interconnect drive system, the SmartProbe® air data system, cockpit seating, and the ice protection system.

Production and development work for these systems will be distributed across multiple U.S. facilities to support the program’s scale. The company noted that operations will take place in Colorado, Illinois, Iowa, Minnesota, New York, Ohio, and West Virginia.

Leadership Perspectives

Executives from both companies emphasized the importance of readiness, advanced performance, and collaborative engineering in bringing the MV-75 to fruition.

“The Army’s new generation of rotorcraft needs to fly farther and faster, and we’re committed to helping Bell accelerate delivery of that advanced performance with Collins’ military-grade commercial technology,” said Troy Brunk, president of Collins Aerospace, in the press release. “We have ready-now manufacturing and service capabilities around the globe to ensure the Army can urgently deliver, modernize and sustain the MV-75 FLRAA for the next 50 years.”

“We are happy to work with Collins Aerospace and add their expertise to Team FLRAA,” stated Ryan Ehinger, senior vice president and program director at Bell. “Together, we are committed to delivering a high-performing, reliable aircraft that will provide the U.S. Army with the critical capability it needs for the future fight.”

Modernizing the Army’s Rotorcraft Fleet

The MV-75 FLRAA program is built around modern design principles, specifically utilizing digital engineering and a modular open systems approach. As outlined in the press release, these methodologies are intended to maximize efficiency and maintain flexibility throughout the entire lifecycle of the aircraft, allowing for easier upgrades as technology evolves.

The integration of Collins Aerospace’s systems is a key component of Bell’s broader strategy to meet the Army’s stringent requirements for speed, range, and reliability in future combat scenarios.

AirPro News analysis

We note that the selection of Collins Aerospace for these five specific systems highlights a growing trend of utilizing commercial acquisition authorities in major defense programs. By adapting “military-grade commercial technology,” defense contractors can often bypass some of the traditional, slower procurement bottlenecks associated with ground-up military development. Furthermore, the geographic spread of the manufacturing work across seven states underscores the broad industrial base required to support a major clean-sheet rotorcraft program like the MV-75 FLRAA. The explicit mention of a 50-year sustainment lifecycle also reflects the Pentagon’s long-term strategic planning and lifecycle cost considerations for this platform.

Frequently Asked Questions

What systems is Collins Aerospace providing for the MV-75 FLRAA?

Collins Aerospace is contracted to provide the main power generation, interconnect drive system, SmartProbe® air data system, cockpit seating, and ice protection system.

How does the MV-75 FLRAA compare to the current Army fleet?

According to the press release, the MV-75 is designed to deliver twice the speed and range of the Army’s current rotorcraft fleet.

Where will the manufacturing work take place?

Work for these five systems will be completed across facilities in Colorado, Illinois, Iowa, Minnesota, New York, Ohio, and West Virginia.

Sources

• Collins Aerospace Press Release

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

REGENT Completes Maiden Flight of “Squire” Autonomous Seaglider Drone

On April 13, 2026, Rhode Island-based aerospace company REGENT (Regional Electric Ground Effect Nautical Transport) successfully conducted the maiden flight of its “Squire” autonomous seaglider drone. Taking place in Narragansett Bay, the event marks the first flight of a defense-specific wing-in-ground-effect (WIG) craft in the United States. According to the company’s press release, the Squire is designed to provide high-speed, runway-independent logistics and reconnaissance capabilities for the U.S. military.

The successful demonstration was officially cleared by the United States Coast Guard, which serves as the primary regulator for seaglider vessels. By bridging the gap between maritime vessels and aviation, REGENT aims to sustain dispersed military forces in contested maritime environments, particularly supporting the U.S. Marine Corps in the Indo-Pacific region.

During the test, the drone reached speeds of 40 knots as it became airborne. The company noted that the Squire’s development runs parallel to the sea trials of REGENT’s “Viceroy” prototype, a larger, 12-passenger commercial seaglider. This parallel testing allows the manufacturer to share data and accelerate both its commercial and defense programs.

The Mechanics of the Squire Seaglider

Wing-in-Ground (WIG) Technology

According to REGENT, the Squire operates using the wing-in-ground (WIG) effect. A WIG craft flies just a few feet above the water’s surface, at an altitude roughly equal to or less than half its wingspan. This aerodynamic profile traps compressed air between the wings and the water, creating a “cushion” that significantly reduces drag and increases lift. This allows the vehicle to travel faster and carry heavier payloads more efficiently than conventional boats or aircraft. REGENT classifies the Squire as a “USA-V” (Unmanned Surface and Aerial Vehicle), combining the persistent presence of an unmanned surface vessel with the speed of an unmanned aerial vehicle.

Flight Profile and Specifications

The recent demonstration showcased the Squire’s autonomous ability to transition through three distinct modes of travel. In “Hull Mode,” the craft floats and maneuvers on its boat-like hull. It then accelerates into “Foil Mode,” utilizing retractable hydrofoils to lift the hull out of the water and drastically reduce hydrodynamic drag. Finally, it enters “Flight Mode” by retracting the foils and taking off into wing-in-ground-effect flight.

While the test flight hit 40 knots, REGENT states that the fully operational Squire is being built to reach a top speed of up to 70 knots (approximately 81 mph) with an operational range of over 100 nautical miles. The drone features a payload capacity of 50 pounds, housed in a payload bay measuring 14 inches long, 12 inches high, and 14 inches wide, providing 2,400 cubic inches of internal volume. The company highlights that this internally mounted bay is designed for rapid reconfiguration by a two-person crew requiring minimal specialized training.

Strategic Military Applications

Solving Contested Logistics

The U.S. Marine Corps and the broader joint force are actively seeking solutions to sustain small, distributed units across vast maritime spaces. According to the provided research, the Squire addresses a critical vulnerability in “contested logistics” because it does not rely on traditional infrastructure like deep-water ports, roads, or airfields, which are highly susceptible to enemy strikes. REGENT is explicitly positioning the platform as a strategic asset to counter anti-access/area denial (A2/AD) capabilities in the Indo-Pacific region.

The drone is optimized for a variety of mission sets, including Intelligence, Surveillance, and Reconnaissance (ISR), tailored logistics and resupply, combat search and rescue (CSAR), counter-narcotics, and anti-submarine warfare (ASW) support. Furthermore, its low-altitude flight profile gives it a low radar signature, keeping it below conventional line-of-sight radar systems.

To date, REGENT has been awarded $15 million in contracts by the U.S. Marine Corps. Earlier in 2026, REGENT leadership presented the Squire program to Defense Secretary Pete Hegseth and senior military staff, emphasizing its potential to rapidly close time-critical logistical gaps in the field.

Leadership Perspectives

Company executives emphasized the strategic importance of the successful test flight in their official statements.

“This successful flight milestone is a major success for our defense program and a strong signal of what Seaglider technology can deliver for the warfighter. There are no products in the market today that combine the speed and wave tolerance of Squire at such a compelling price point. This will revolutionize maritime warfare.”

“Defense customers require platforms that can operate across wide maritime areas with speed, range, and mission flexibility, without relying on traditional and often vulnerable infrastructure. Squire is designed to meet that exact need.”

AirPro News analysis

We view the successful flight of the Squire as a fascinating intersection of historical physics and modern autonomous technology. The wing-in-ground effect is not a new concept, it was most famously utilized during the Cold War by the Soviet Union’s massive “Caspian Sea Monster” ekranoplans. However, applying this aerodynamic principle to a compact, autonomous, all-electric drone solves a very modern U.S. military aircraft problem. As the Pentagon shifts its focus toward distributed maritime operations in the Indo-Pacific, the ability to supply troops on remote islands without relying on easily targetable runways is paramount. The “runway-free” nature of the Squire, combined with its low radar signature, positions it as a highly relevant tool for modern naval and amphibious warfare.

Frequently Asked Questions

What is a seaglider?

A seaglider is a type of wing-in-ground-effect (WIG) craft that operates a few feet above the water’s surface. It combines the operational characteristics of a boat with the speed and aerodynamics of an aircraft, utilizing a cushion of trapped air to reduce drag and increase efficiency.

How fast can the REGENT Squire fly?

During its maiden test flight, the Squire reached speeds of 40 knots. However, the fully operational production model is designed to achieve a top speed of up to 70 knots (approximately 81 mph).

Who regulates the testing and operation of seagliders?

In the United States, seagliders are primarily regulated as maritime vessels. The recent testing of the Squire in Narragansett Bay was officially cleared by the United States Coast Guard.

Sources: REGENT

This article is based on an official press release from GE Aerospace.

GE Aerospace and Indian Air Forces Partner on In-Country Engine Depot for Tejas Fleet

GE Aerospace announced a contract with the Indian Air Force (IAF) on April 13, 2026, to establish an in-country depot facility for the F404-IN20 engines. These engines are the primary power plant for the IAF’s Light Combat Aircraft (LCA) Tejas fleet.

According to the official press release, the new facility will be owned, operated, and maintained entirely by the Indian Air Force. GE Aerospace will support the initiative by providing technical inputs, specialized repair equipment, spare parts, training, and expert support staff.

This development is designed to eliminate India’s reliance on overseas repair centers. By localizing deep maintenance and overhaul work, the IAF expects to significantly improve turnaround times for engine servicing, thereby boosting the operational readiness and availability of the Tejas fighter fleet.

Enhancing Local Sustainment for the Tejas Fleet

The establishment of the new depot marks a significant milestone in the four-decade partnership between GE Aerospace and the Indian military. The initiative strongly aligns with the Indian government’s “Make in India” campaign, focusing on building robust local aerospace infrastructure and indigenous defense sustainment.

“Our commitment to supporting India’s armed forces continues to guide our collaboration and partnership in expanding local sustainment capabilities of the Tejas fleet,” stated Rita Flaherty, Vice President of Sales and Business Development for Defense & Systems at GE Aerospace, in the company’s release.

Addressing Supply Chain Challenges

While the press release highlights the strategic benefits of the new depot, broader industry data indicates that this move arrives at a critical juncture for the LCA Tejas program. Hindustan Aeronautics Limited (HAL) and the IAF have recently navigated significant supply-chain challenges regarding engine deliveries.

In August 2021, HAL signed a $716 million contract with GE Aerospace for 99 F404-IN20 engines to power the Tejas Mk1A fleet. However, industry reports note that as of April 2026, only six of the 99 contracted engines have been delivered. Due to these delays, HAL has reportedly invoked contractual penalty clauses amounting to 10% of the contract value, or approximately $71.6 million. To address the backlog, HAL Chairman and Managing Director D.K. Sunil recently stated that GE plans to accelerate deliveries, aiming to supply up to 20 engines by the end of the 2026 calendar year.

Deepening US-India Defense Ties

The collaboration on the F404 depot is part of a wider expansion of defense technology sharing between the United States and India. Beyond the F404, GE Aerospace and HAL have recently concluded technical discussions regarding the co-production of the more advanced F414 engines in India. This follows a landmark Memorandum of Understanding (MoU) signed in June 2023, paving the way for the F414 engines to power the next-generation LCA Tejas Mk2.

GE Aerospace’s Expanding Footprint in India

According to the GE Aerospace press release, the company’s engines power a diverse array of Indian military assets. This includes the Indian Navy’s P-8I maritime patrol aircraft and MH60R helicopters, as well as the IAF’s AH-64 Apache helicopters. Furthermore, GE’s LM2500 marine gas turbines provide propulsion for the INS Vikrant aircraft carrier and the P-17 Shivalik Class frigates.

The company also emphasized its ongoing investments in India’s aerospace ecosystem and workforce. Over the past decade, GE has trained more than 5,000 individuals in core manufacturing skills at its Pune factory. Additionally, 150 engineers have graduated from the company’s local two-year Edison Engineering Development Program. In September 2025, the GE Aerospace Foundation launched the “Next Engineers” program in Bengaluru, a four-year initiative designed to prepare 4,000 young students for engineering careers.

AirPro News analysis

We view the establishment of this in-country depot as a vital strategic mitigation effort by the Indian Air Force. Given the ongoing delays in new engine deliveries for the Tejas Mk1A program, ensuring that the existing F404-IN20 engines can be repaired domestically and rapidly is essential for maintaining fleet readiness. This localized maintenance, repair, and overhaul (MRO) capability not only fulfills domestic manufacturing goals but also serves as a necessary buffer against global supply chain vulnerabilities, allowing the IAF to maximize the utility of its current engine inventory while awaiting new deliveries.

Frequently Asked Questions

What is the purpose of the new GE Aerospace depot in India?
The depot will provide in-country maintenance, repair, and overhaul for the F404-IN20 engines that power the IAF’s Tejas fleet, drastically reducing turnaround times by eliminating the need to send engines overseas for repair.

Who will own and operate the facility?
The facility will be entirely owned, operated, and maintained by the Indian Air Force. GE Aerospace will provide technical inputs, specialized equipment, spare parts, and training.

How many F404 engines did HAL order in 2021?
HAL signed a $716 million contract for 99 F404-IN20 engines in August 2021.

Sources

• GE Aerospace