In short
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PROJECT ID
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PJ02 EARTH |
PROJECT TYPE
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Industrial research |
FLAGSHIP
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Not applicable |
STATUS
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Completed |
SESAR PROGRAMME
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SESAR 2020 |
PROJECT DURATION
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2016-12-01 > 2020-03-31 |
TOTAL COST
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€ 37.430.158,57 |
EU CONTR.
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€15.592.782,56 |
GRANT ID
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731781 |
PARTICIPANTS
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Airbus, Deutsches Zentrum für Luft- und Raumfahrt, Leonardo, Polska Agencja Zeglugi Powietrznej, Luftfartsverket, Direction Des Services De La Navigation Aerienne (DSNA), Enaire, Enav, Honeywell Aerospace, Indra Sistemas Sa, NATS, Swedavia, Eurocontrol, Skyguide, Thales Las France , Thales Italia, Stichting Koninklijk Nederlands Lucht - En Ruimtevaartcentrum, Austro Control , Heathrow Airport, Avinor Flysikring, Flughafen Zurich, Rizeni Letoveho Provozu Ceske Republiky Statni Podnik, Letove prevadzkove, Oro Navigacija, Hrvatska Kontrola Zracne Plovidbe, Udaras Eitliochta Na Heireann - The Irish Aviation Authority (IAA), Naviair, Airtel Atn , Saab Aktiebolag, Aéroports de Paris, Flughafen Munchen , Schiphol Nederland, Sintef |
Addressing capacity and delays at airports
It is estimated that by 2035, more than 20 airports will be operating at 80% or more of capacity on a daily basis, resulting in delays of up to 5-6 minutes (2013 Challenges of Growth Report, Eurocontrol).
Addressing capacity is challenging given the socio and environmental constraints preventing airports from building new runways or the technical, infrastructure and meteorological limitations hindering secondary airports from absorbing additional traffic..
Project objectives
The EARTH project united key European aviation partners combining the right expertise and investment to address issues and drive deployment of operational and technical improvements to enhance infrastructure, increase traffic throughput while preserving safety and environment.
EARTH focused on separation and procedures to improve runway and airport throughput considering wake-vortex, weather, environment and noise, while taking account of different traffic demand, future aircraft capability and airport configurations.
Benefits
EARTH supported the SESAR deployment regulation and addressed European concerns on environmental sustainability, reduction of noise and fuel consumption and brings low cost improved access to regional airports making regions economically attractive with potential for new jobs.
Other news and documents
Integrated Runway Sequence Function: <Flyer> - <Poster>
July 2019: An article on PJ02 project published on NATS blog
Activities supporting the delivery of solutions
Wake turbulence separation optimisation |
The project aims to optimise wake turbulence separation minima for arrivals and departures to enhance airport runway throughput. It focuses on development of:
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Enhanced arrival procedures enabled by satellite technologies |
The project will investigate the use of satellite navigation and augmentation capabilities, such as GBAS and satellite-based augmentation systems (SBAS), to enhance landing performance and to facilitate advanced arrival procedures (e.g. curved approaches, glide slope increase, displaced runway threshold). By doing so, noise is reduced while runway occupancy time (ROT) is optimised. The aim is to also reduce the need for separation for wake vortex avoidance. |
Minimum-pair separations based on required surveillance performance (RSP) |
The project will work on the application (by air traffic control) of non-wake turbulence pair wise separation (PWS) of 2 nautical miles for arrivals on final approach (at the point that the leading aircraft in the pair crosses the runway threshold), based upon required surveillance performance (RSP). |
Independent rotorcraft operations at airports SJU reference PJ.02-05 |
The work refers to RC specific approach procedures and SBAS-based point-in-space (PinS), which aim to improve access to secondary airports in low-visibility conditions. |
Improved access into secondary airports in low-visibility conditions |
Improved access into secondary airports in low-visibility conditions will be possible thanks to the introduction of new airborne capabilities, such as RNP and global navigation satellite system (GNSS)-based landing systems. |
Traffic optimisation on single and multiple runway airports |
The project will develop and validate a system that enables tower and approach controllers to optimise runway operations arrival and/or departure spacing and make the best use of minimum separations, runway occupancy, runway capacity and airport capacity. |
Enhanced terminal area for efficient curved operations |
The project will look a curved segment approaches as close to the runway as possible to optimise procedures in terms of fuel consumption or noise abatement. Using geometric vertical navigation guidance in the TMA will facilitate a more efficient transition from barometric to geometric vertical navigation. |