Aircraft IT Operations – February / March 2015

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Articles

Name Author
The World according to IT …and me! View article
En-Route Flight Profile Optimization Dr. Oliver Kranz, Managing Partner, PACE View article
More than an EFB project Paul Stanley, EFB Project Manager, and Capt. Eamon Kierans, Manager Flight Operations Compliance, Aer Lingus View article
Developing a Future Avionics System Guillaume Lapeyronnie, Cockpit Marketing Manager, Thales Avionics View article
Connected Aircraft: No More A Flight of Fancy Mario Sabourin Sr. Product Manager EFB, SITAONAIR View article

More than an EFB project

Author: Paul Stanley, EFB Project Manager, and Capt. Eamon Kierans, Manager Flight Operations Compliance, Aer Lingus

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More than an EFB project

Paul Stanley, EFB Project Manager and Capt. Eamon Kierans, Manager Flight Operations Compliance, Aer Lingus share an EFB case study with an eye to broader airline connectivity

The EFB program at Aer Lingus follows in a long tradition of innovative IT applications: Aer Lingus has always been in the vanguard of IT in commercial aviation, having been the first company in Ireland to operate a mainframe computer in the early 1960s. By the mid-sixties the airline was part of a group of operators to develop and implement IPARS (international programmable airline reservation system) reservation and check-in system and has continued to be an innovator since then, including being an early adopter with web presence in the early 1990s, and an early online booking engine. So it was quite in character when Aer Lingus looked at digital information systems in 2006 and, in 2007, considered the possibilities for EFB.

However, we quickly realized that even if we had been able to immediately implement EFB in the cockpits it would not have been possible to use it because we were not prepared with the necessary supporting capabilities on the ground, in the back office… in our administration functions. Of course, we knew that there would be major benefits from EFB including the paperless cockpit, improved distribution of content which, in turn, would support better compliance and the streamlining of processes: but, in light of the lack of supporting capability already mentioned, we were finding it difficult to build a business case. So, it was decided that the best approach would be to break the program into different phases. This, it was felt, would minimize the risk to each phase, allow us to assess feedback for each individual phase and maximize the cost effectiveness of implementation.

Phase 1: electronic document implementation

The first phase, which commenced in 2007 and ran to 2011, was to implement an electronic document authoring and content management system and to assess the benefits of digital delivery. It was during this phase that we started to work with Arconics, using their applications and expertise as we progressed along the program. At the outset, we already had pilot and cabin crew portals that had been built in-house and were maintained by the airline’s cabin crew and pilot section. The first decision was to replace those portals with a new content management system (CMS), implementing an XML authoring application so that we could move to electronic manuals and a simplified editing process – a number of past features in Aircraft IT have explained the benefits of XML authoring.

Before embarking on this, we went through a process to define our requirements from which an RFP (request for proposal) enabled us to consider a number of vendors. As a result of this process, Arconics was selected to supply two of their web based tools… Manual Manager, which is a guided XML authoring tool and PublishPort, Arconics’ content management system, from which we developed new pilot and cabin crew portals. These first implementations went live in the first quarter of 2009 and any implementation issues that arose were quickly dealt with by the Arconics and Aer Lingus teams overseeing the program. The extent to which the implementation was a success can be judged from the fact that we soon felt able to develop additional functionality so that PublishPort is now used to support all portals in Aer Lingus and the staff intranet.

By 2011, Aer Lingus had digitized most of the key manuals including FCOM (flight crew operations manual), MEL (minimum equipment list), OMA (Operations Manual Part A) and ACSP (Air Carrier Security Program). A number of content types were also digitized, including flight crew notices, cabin crew notices, airfield briefing sheets, rosters and flight briefing packs. Because it’s a single content management system, we can publish content once and it becomes available everywhere through all relevant portals.

Finally, we assessed the benefits that had been achieved from this phase of the program which included:

  • Lower documentation editing costs;
  • Lower information distribution timescales;
  • Lower Flight Crew information production costs;
  • Lower information delivery costs;
  • Lower audit costs for compliance on proof of training evidence;
  • Reduced Flight Crew community workload with information more easily available through one portal;
  • Improved staff awareness;
  • Better crew situational awareness pre-flight;
  • Reduced rostering costs.

These results were very encouraging and added confidence as we moved into the next phase.


Phase 2: Class 1 EFB implementation
From 2011, the second phase of the program was to implement the Class 1 EFB solution using Windows. We had first needed to have a documentation system that was available on the ground, which we achieved with the new portals; by the time we set out on this second phase, every part of the airline had a portal that could be accessed through the intranet. So the next step was to bring this all on board the airplane. In 2011, we got management approval but, at the time, class 2 devices to be viewable and available throughout all stages of the flight were very expensive, so we opted to get approval for a class 1 project using a lap-top computer.

The device that we chose was the Panasonic Toughbook for a number of reasons including that we knew that the case and the shape of it wasn’t going to change; so, when we built a lockable docking station in the cockpit (to store the device during take-off and landing and while on the ground, and to charge the batteries) it was unlikely that we’d have to change that for a later generation of the device. We also used a local (Irish) company called Flightman for the device management software: but more important than being local, they had a good back end system that gave us tracking facilities which pleased our EFB administrator.

Based on the successful experience we’d had with the ground portals, we wanted to introduce the EFB and bring onto it the Arconics Manual Manager and viewer system. One reason for that was that Manual Manager uses XML documents and we also wanted these devices to be able to be updated using 3G. Arconics has a system whereby we won’t need to run around aircraft with USBs to update the EFBs – that would be tedious and labor intensive – but will be able to update everything over 3G. After discussion with our mobile provider about stability, we have opted to use a more stable 3G M2M (machine to machine) secure private network platform managed service. Arconics’ system is able to compare new issues of manuals or documents with the previous issue to identify the differences so that it only needs to send the difference, the Delta changes, over 3G which makes for much lower 3G costs. The software on the device has the capacity to replace the old version of a manual or document with the new amended version to be viewed.

We used an in-house performance application called ALPS (Aer Lingus Performance System) which is also on the Toughbook. And we have set up an EFB administration in Aer Lingus’ Flight Operations Engineering Department where the head of performance engineering is also the EFB administrator who set up the EFB manual and accompanying procedures. Furthermore, we’ve designed SOPs (standard operating procedures) for the flight crew to use the devices which are assigned to aircraft rather than to pilots. There are two devices on each airplane, on the left and on the right, and they are registered to that aircraft so that, for sections such as the FCOM, only the information applicable to that specific aircraft will be displayed.

As far as the implementation was concerned, we wanted to achieve some specific cost savings including a reduction of the cost for producing paper manuals right across the organization, a reduction in the cost of distribution of manuals and notices and some cost improvements on the performance side with the ALPS performance calculator allowing us to use, for instance, optimal flap settings and being able to get better flexible take-off thrust figures for reduced power take-off.

On the corporate side we needed to address some extra details so we have an electronic journey log that records all times – ‘off-gate’, ‘take-off’, ‘landing’, etc. – as well as letting the flight crew enter reasons for delays, to support better data gathering and better analysis tools. Also, on the ground handling side, we have a form for the flight crew to record if all the ground handling services that they’re supposed to get at the station where they have arrived were actually available and delivered. This helps our financial people when dealing with the ground handling services providers.

Phase 3: Full mobile device implementation
On completion of phase 2, the general view was that it had been a success, so much so that we got a lot of feedback from crews including that they wanted some information to be available off the aircraft. This was largely because we had decided to fix our EFBs in the cockpit but the flight crew wanted access to items like the flight briefing packs in advance of arriving in the cockpit or even arriving in the operations area at the airport. This is particularly useful for overnight crew stays at stations such as New York or Chicago where they can download their flight plan briefing pack onto a mobile device and even be reading it on the bus to the airport to get the information in advance. This works really well and for that project we decided that the iPad would be the best device and we’re now feeding the information that the crew needs also onto an iPad so that they can have access to everything, on the ground, before they even arrive at the airport.

We selected Arconics again for this based on their proven success with the ground operations portal we thought it would be best to transfer that onto a mobile platform which Arconics built for us to give mobile devices access to all of the information on the ground portal, including flight plans, weather information, security information… everything coming from our flight planning system plus some extra information from engineering about defects on the airplane and where the airplane is parked.

During 2014 we issued iPads to all pilots based on a business case that saw further improvements in costs. Aircraft cost savings came from a reduced cockpit workload with improved crew awareness and preparation as a result of having more time to assimilate the information provided, plus there’s a growing body of information available digitally. The mobility aspect of the program, using iPads, started to be implemented with the third phase which commenced in 2012 and which, with the second (EFB implementation) phase is continuing in the current year.

Was it a success?
Overall we’d say yes, the EFB program in Aer Lingus has been a success. It was a pleasant surprise for us when the crews requested the information to be available outside of the cockpit (see phase 3 above). We had decided to make the actual EFB devices aircraft assigned to give us better control over the ships’ library and to ensure that the devices were always with the aircraft to avoid any delays in dispatching. However, we’ve revisited this to add in pilot mobility.

As with any program, this one did encounter some problems including that the docking station supplier went out of business. Fortunately, we have enough units for the whole fleet but have had to locate new sources for spares and to carry out repairs. This was a project that ran for two years until completion in 2014 and, at the start we were dealing with very new technology. There were also some teething problems with software and the 3G communications, requiring rapid team responses to deliver remediation and a re-platform of infrastructure (see above). We worked with our suppliers on these issues and they were very supportive to the extent that we now have the regulator’s approval to remove the paper manuals from the airplane and have the confidence to be able to do that. Approval was granted during December 2014 and we are now proceeding to remove the paper manuals from the aircraft.  This will remove 35-40 kilos of weight from each aircraft.

iPads, while they met one of the crews’ own requirements, were initially a cause for concern with pilots and their unions concerning whether, as trackable devices, they would allow the airline to invade an individual’s privacy. We overcame this with a number of assurances from management. Other issues included working with the commercial department to release aircraft for the new equipment to be installed and we have had to extend the scope of the program to take account of new aircraft entering the fleet.

Benefits from the changes
Some of the gains enjoyed by Aer Lingus and its staff from the EFB and associated technologies program have already been mentioned above. We’re also moving to optimal flap settings in early 2015, although this will be a bias rather than an absolute rule so that pilots will continue to have the final say. And while pilots might have had reservations about the EFB at the outset (when they had to work with the old and new systems in parallel to meet the regulator’s requirements and were still learning the new processes) the digitization strategy now enjoys high levels of acceptance among flight crews.

Once the privacy issues had been ironed out (see above) the iPad with Arconics’ software has become completely embedded in the organization and is regarded by pilots as a given in the support they get from Aer Lingus. This will be helpful in any future additions that we make to the system on the ground or in the cockpit.

Lessons learned

Following the program, we have made a few notes to ourselves for future projects starting with the need to spend time properly capturing the requirements that the project has to meet and to ensure adequate risk reduction on the new technology integration – to avoid exposing the operation to risk. It’s also important to be very careful when selecting suppliers to be sure that they’re adaptable and can work with an airline when its operation might generate particular needs that are not standard to, say, a vendor’s software. Don’t underestimate the effort involved in testing the software, communications and processes, and updates and processes to ensure they work well enough to replace the paper. And remember that it will be important to work hard to bring the staff along with any changes, even if they are resistant at the outset, and to involve the regulator at every stage because without regulatory approval, the program won’t fly (forgive the pun). Finally, the involvement of IT at every stage is critically important given the reliance on servers and communications systems, and for the provision of back-up and fallback capabilities.

Next steps

The next development for Aer Lingus will be to move to a class 2 EFB with a tablet PC mounted in the cockpit but a Windows device not an iPad because it will be easier to integrate. We’re also going to install an interface device in the aircraft which will be able to access the ARINC (Aeronautical Radio INC) data from the data buses on the airplane. Our ultimate objective is a fully paperless cockpit with electronic charting (including ‘own ship’s position’) to be introduced over the next two years and an electronic flight folder with the integrated information flow that will need.

The business case for this has been approved and the next phase will commence in the first quarter of 2015.

Contributor’s Details

Paul Stanley, EFB Project Manager, Aer Lingus

 
Paul Stanley is project manager in Aer Lingus IT specializing in Flight Operations and Operations projects. Paul is the program manager for the Aer Lingus EFB program, including the implementation of Crew Portals, mobile apps and EFB projects.
Capt. Eamon Kierans, Manager Flight Operations Control, Aer Lingus 
Capt. Eamon Kierans is A320 EFB project pilot, Type rating Instructor and Examiner and Manager for Flight Operations Compliance. He has 30 years’ experience with Aer Lingus initially as a Technician and Licensed Engineer (seven years) then as a pilot (23 years).
Aer Lingus



Aer Lingus was founded by the Irish Government in 1936 to provide air services between Ireland and the UK. Its name is derived from the Irish ‘long’ meaning ‘ship’ and is therefore translated as ‘Air Fleet.’ Today, with a fleet of 50 aircraft (mainly Airbus models plus three B757-200) and with A350s on order, Aer Lingus serves mainly European and North American destinations with a few Middle- and Far-East centers plus three in Australia.

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