Engineered under the direction of Ascendance's teams and manufactured by DUQUEINE Group - an industrial partner specializing in aeronautical composite structures - this strategic milestone marks the culmination of years of design work, aerodynamic optimization, and industrialization.
Alongside ATEA's development, Ascendance is already putting its STERNA hybrid-electric technologies to work with partners, notably in the drone sector as well as for civil aviation. These collaborations validate the hybrid architecture in operational environments, demonstrate its robustness across diverse mission profiles, and accelerate the industrial maturity of the technology. ATEA is thus part of a continuous journey: it serves as both an integrated demonstrator and a technology catalyst for civil and defense applications.
A Breakthrough Architecture, the Result of Years of Design and Validation
Prior to the launch of prototype production, ATEA's architecture underwent advanced design campaigns, structural analyses, aerodynamic studies, and wind tunnel testing. This work validated the architectural choices specific to a hybrid VTOL aircraft integrating distributed propulsion and fly-by-wire flight controls.
With the structure now in place, full integration can begin of:
- The STERNA hybrid-electric propulsion system, developed by Ascendance, integrating Safran's ENGINeUS electric motor
- A distributed propulsion architecture, full avionics systems and flight control system
- Fly-by-wire flight controls - key elements of the new more-electric aircraft architectures
This milestone marks the transformation of an engineering program into a tangible industrial reality.
Four Years of Hybrid Testing and Avionics Validation
ATEA's entry into integration is not a starting point — it is the outcome of a four-year maturation cycle. Ascendance's hybrid propulsion system has undergone four years of continuous bench testing (over 500 hours), validating its architecture, technologies and equipment, reliability, and performance. In parallel, avionics systems and flight control laws were tested through advanced flight simulations integrating the full operational chain: complete cockpit, integrated onboard systems, and ground communications.
These campaigns were conducted with Ascendance's test pilots and also involved EASA-certified pilots, contributing to the robustness of the control architecture and its compliance with regulatory requirements. This integrated approach — hybrid-electric propulsion, avionics, and flight controls — positions ATEA as a technologically mature platform.
A Dual-Use Aircraft for Civil and Defense Applications
ATEA embodies a pragmatic and versatile approach to electric hybridization. Its distributed hybrid-electric architecture enables:
- Significant improvement in energy performance
- Reduced fuel consumption and CO₂ emissions
- Adaptability to civil missions and defense applications
The versatility of its applications — passenger, cargo, medical, and security missions — is a defining axis of the program.
A European Ambition Built on Technological Mastery
Designed, assembled, and tested in France, ATEA is the product of a national and European industrial ecosystem united around a shared ambition: building a sovereign hybrid-electric aviation sector. Through its STERNA hybrid-electric technologies and the ATEA demonstrator, Ascendance is developing an integrated approach combining:
- Mastery of hybrid-electric and distributed propulsion
- Advanced avionics architecture
- Flight control laws and fly-by-wire flight controls
- Full system integration
This milestone strengthens Ascendance's ambition to position itself in Europe as the leader in high-performance, dual-use, and exportable hybrid-electric solutions — capable of meeting both decarbonization requirements and strategic resilience imperatives.
