OPINION: For Aviation Cybersecurity, the Horizon Is Nearer Than You Think

(Image by Martin Winkler from Pixabay)

Today’s commercial and military aircraft are critical infrastructure for transportation and logistics. However, researchers have detected vulnerabilities in them that pose potential cybersecurity risks, particularly during periods of military conflicts. Nevertheless, funding is rising for companies that secure the crucial operational technology (OT) layer powering flight systems; and public and private stakeholders are making sizable progress in adding visibility to this pocket of converged tech stacks where malicious actors could operate. Startups with tailored solutions have been key in advancing protections and I remain a strong advocate for continued innovation to further empower today’s defenders and to ultimately field these new capabilities.

While in previous years there may have been a love-hate relationship between aviation and cybersecurity (around implicit questions over safety), the tides have begun to change, and strong partnerships have been forged amid cybersecurity’s rapid ascent. While avionics and aviation systems are clearly more digital, fly-by-wire systems, versus the mechanical stick and yoke pilots flew in the 1950s, the industry has recognized areas to intervene and strengthen defenses. Stakeholders have responded in kind with research initiatives and operational testing, some of which I’ll explore here.

A Widening Attack Surface

Over time, today’s aircraft have become dotted with smart technologies. This has provided a more connected flight for passengers, smoother operations for pilots and more data for airline operators to make better fleet-wide decisions. However, this modernization brings with it cybersecurity risk. Exploits have been identified that can skirt weak authentication, jam GPS signals, or even tamper with misconfigured in-flight or ground systems.

In fact, in 2018, the U.S. Department of Homeland Security ran “nose to tail” tests of an aging commercial airliner to detect weak spots and found that the vessel could be hacked by breaching the plane’s radio frequency communications. Nevertheless, rising awareness and technological advancements have helped counter this activity. The DHS assessment, along with similar testing and certification processes, have helped enhance protections aboard our aircraft (from software and hardware to the wider network architecture).

Large suppliers like Boeing maintain that effective cybersecurity is essential to the business, including both operations and overall data protection, and for one, the manufacturer adheres to the National Institute of Standards and Technology’s (NIST) Cybersecurity Framework – and expects similar efforts from partners to secure the aviation supply chain.

Thanks to this type of recognition and progress, a once-held assumption that flight systems simply prioritize physical safety and reliability over cybersecurity is waning. Manufacturers have grown more aware of the physical (and fiscal) impact of today’s cyberattacks (ransomware hits on flight operation systems, grounded flights, etc.), which has hastened innovation. Now, scores of solution providers are emerging with capable products that can be deployed for immediate results.

(Image by StockSnap from Pixabay)

Data Visibility: A Source of Hope

Overall, I’m certainly optimistic about our future. As partner and head of AEI HorizonX, a VC venture formed in partnership with Boeing, I spend my time researching and investing in next-generation aerospace defense and security startups around the world. I believe that if the industry continues to foster innovation and increased awareness, cybersecurity challenges of all kinds can be overcome (and threats averted).

In fact, we’re seeing rapid innovation around the use of data, specifically. Companies providing tailored, dual-use solutions for both public and private deployment are primed to excel – and attract VC funding – in the current market. Security innovators like OT cyber firm Shift5, for example, are working to provide continuous monitoring of onboard networks and data buses (hardware subsystems used for data transmission), bringing greater observability, and therefore cybersecurity, to Airplane Information Management Systems (AIMS), ground/onboard systems, connected fuel gauges, and other mechanisms.

Data as a Force Multiplier

Early adopters of these tailored solutions are seeing security improvements, and performance and efficiency benefits. Enhanced data monitoring using artificial intelligence and machine learning, for example, helps defenders see patterns and anomalies that could indicate security issues. But they can also surface mechanical issues in real time – reducing the chances of a damaging cyberattack or malfunction.

I’m confident that with OT-level data available to innovative solution providers, operators can enhance their strategic decision-making around fleet usage and drive profitability. I believe it will take even further momentum, however, to up-level the overall security of every aircraft. Like the equipment retrofitting we’ve seen around new cabin services (personalized IFE software or purchase-tracking Wi-Fi sensors), enlightening OT security tools are an investment in the future, poised to uncover new efficiencies.

There’s never been a more exciting time for innovation in this space. Despite greater levels of connectivity and associated cyber-risk, operators proceeding with cybersecurity in mind will maintain safe flying conditions – and the industry has the tech offerings to make this happen.

Brian Schettler leads AEI HorizonX, the venture capital investment platform formed in partnership with The Boeing Company. He was also a founder and senior managing director of Boeing HorizonX Ventures and led Boeing’s venture capital team chartered with investing in next-generation aerospace defense and security startups around the world. He has more than two decades of experience in aerospace, technology and defense companies and has led numerous investment transactions. He was also formerly the VP of Corporate Strategy at Cobham and a senior strategist for Boeing Military Aircraft, Phantom Works, and the space systems division of Northrop Grumman.

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Reliable Robotics Receives FAA G-1 Acceptance for Autonomous Cessna Caravan System

Reliable Robotics is working toward certification of its autonomous navigation system on the Cessna 208 Caravan. (Photo, courtesy of Reliable Robotics.)

Reliable Robotics has received acceptance from the Federal Aviation Administration (FAA) for the certification basis associated with the autonomous aircraft navigation system it is developing. The California-based company’s G-1 issue paper was accepted by the FAA for the autonomous platform it is developing and has already demonstrated on the Cessna 208 Caravan.

First established in 2017, Reliable Robotics made headlines in recent years for completing several remotely piloted tests from its Mountain View, California headquarters of its autonomous systems on several Cessna aircraft. In February 2021, Reliable Robotics remotely piloted a Cessna 208 Caravan, following similar achievements in 2020 and the autonomous flight of a Cessna 172 Skyhawk over a populated region in 2019.

In August 2020, the company completed a fully automated landing with its system in a FedEx-owned Cessna 208, as the air cargo carrier has expressed interest in the potential benefits the technology could eventually provide to air cargo airlines. Now, with FAA acceptance of their G-1 issue paper, Reliable Robotics is ready to move into the next phase of their certification program and efforts to prepare their system for live operations.

“We are very appreciative of the FAA’s noteworthy attention to detail and ongoing support,” Mark Mondt, director of certification for Reliable Robotics, said in a statement. “This certification basis is the culmination of years of work with the FAA and represents a key step towards bringing advanced navigation and autoflight systems to normal category aircraft. We look forward to continuing our work together as we move into the next phase of the certification process.

The autonomous platform developed by Reliable Robotics is designed as an upgrade kit for fixed-wing aircraft. According to the company’s website, the system includes avionics, software, a communications system, remote command interfaces, and a “backup system that has the capability to take over if needed.” Demonstrations of their technology have been remotely piloted from workstations at their headquarters that feature an iPad programmed to provide information and a user interface for the remote pilot to manage the flight plan, and maintain situational awareness over the aircraft.

Command and control, voice, and data links are also enabled from the control center where their remote pilots can communicate with air traffic controllers as well as other aircraft with a push-to-talk function.

The FAA’s acceptance of the G-1 issue paper provides Reliable Robotics with airworthiness and environmental requirements for the certification of its autonomous system. Their next steps will include the development of a G-2 issue paper, followed by the eventual demonstration of how the design of their system is in compliance with the requirements outlined in the issue papers. This would allow Reliable Robotics to achieve supplemental type certification (STC) for their system on the Cessna 208 Caravan.

Crossing the G-1 issue paper milestone comes for Reliable Robotics following the addition of several new aviation industry veterans to their executive team. Kevin Sagis, who has held chief engineering roles at Lockheed Martin, NASA, the Department of Defense, and Virgin Orbit, was appointed chief engineer and senior vice president of Reliable Robotics in May. Brandon Suarez, a former technical director for General Atomics Aeronautical Systems Inc., was appointed Vice President of UAS Integration for Reliable Robotics in July.

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US Air Force Plans to Move Forward on MH-139A Developmental Testing

Pictured are two of the four MH-139A test aircraft at Duke Field, Fla. (Photo: U.S. Air Force)

Boeing has received the Federal Aviation Administration (FAA) Supplemental Type Certifications (STCs) for the company’s MH-139A Grey Wolf to enter developmental testing, the U.S. Air Force Life Cycle Management Center (AFLCMC) at Wright-Patterson AFB, Ohio said on Aug. 23.

AFLCMC said that the Air Force has accepted four MH-139As for flight testing–“mere weeks” after Boeing completed the final FAA STC “required for the MH-139A to achieve its military flight release.”

“These accomplishments allow the Air Force to conduct testing of critical military capabilities of the MH-139A as the program progresses towards Milestone C,” AFLCMC said.

Before the Air Force signed off on the four MH-139A test aircraft, they “went through rigorous acceptance test” by pilots from Air Force Global Strike Command Detachment 7 and the 413th Flight Test Squadron–both based at Duke Field, Fla., AFLCMC said.

Integration of two defensive systems on the MH-139A and FAA issuance of STCs on the MH-139A for those subsystems–the ALE-47 Airborne Countermeasures Dispenser System and the Northrop Grumman AAR-47 Missile Warning System–resulted in FAA STC delays for the MH-139A.

In June last year, the Air Force said that the fairing that connects the ALE-47 and the AAR-47 to the MH-139 had caused airflow anomalies but that Boeing had redesigned the fairing and was testing it to validate the fix.

Florida-based Extant Aerospace has said that, since 2001, it has been the Air Force’s prime contractor for the BAE Systems-designed ALE-47. Extant Aerospace said that it buys OEM designs for older products, or licenses them from the builders, to allow OEMs to focus on new product development.

In June, the company said that the FAA certification process had taken longer than expected due to the difficulties in getting hands-on examiners because of COVID-19 and due to the complexity of FAA certification of the military-unique systems.

A Boeing official said in June that an STC for an electronic box for the MH-139A’s Identification Friend or Foe (IFF) had “never gone through an FAA certification because it’s military.”

Commercial aircraft converted to military versions need FAA-approved STCs for military-specific equipment. For the MH-139, Boeing installs unique military equipment on the Leonardo-supplied AW139 commercial helicopter.

In June last year, Lt. Gen. Duke Richardson, at the time the service’s top uniformed acquisition official, told a Senate Armed Services Committee panel that the MH-139 requires three STCs from the FAA. Richardson is the new head of Air Force Materiel Command.

Boeing is eyeing a possible low-rate initial production decision for the MH-139A next year.

The MH-139As are to replace the Air Force’s 63 Bell UH-1N helicopters to provide security and support of the U.S. military’s intercontinental ballistic missile fields, civil search-and-rescue capabilities, airlift support and doomsday VIP transportation.

The Air Force awarded Boeing a contract worth $2.38 billion in September 2018 to include up to 84 MH-139As.

Air Force Lt. Col. Josh Hallford, the chief of MH-139 standardization and evaluations for MH-139 Test Detachment 7, said in an AFLCMC statement on Aug. 23 that “the built-in system redundancies and physical performance” of the MH-139A “show great potential for improving on the myriad of missions that have been covered by the venerable Huey for so long.”

This article was first published by Defense Daily, a sister publication to Avionics International, it has been edited, click here to view the original version.

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Drone Developers Fly their Latest Models at the Annual UAS Public Safety Summit

Drone manufacturers have started to design aircraft for very specific applications, believes Ken Stewart, CEO of NUAIR (Northeast UAS Airspace Integration Research Alliance, Inc.). Government agencies and departments are not usually looking for just one type of drone to perform a range of operations. They are more likely to want a fleet of drones, each tailored to a specific function or mission.

Stewart sees fixed-wing electric drones as perhaps the most valuable configuration in the industry. “Those give the ability to hover, land, and take off vertically like a helicopter, but they give endurance where you can fly for a very long period of time,” he told Avionics International. The challenge with electric drones, he noted, is the trade-off between batteries (and endurance) and weight.

An advantage of drones in a quadcopter or octocopter configuration is that they can perform very precise measurements. This is a more difficult or impossible task for a vertical take-off and landing (VTOL) aircraft to perform, according to Stewart.

Last week, NUAIR hosted the fourth annual UAS Public Safety Summit at Griffiss International Airport in upstate New York. Drone developers exhibiting their aircraft at the summit included Ascent Aerosystems, Skydio, BRINC, senseFly, and Inspired Flight, among others, with multiple companies performing flight demonstrations.

The drones on display included a variety of sizes, configurations, capabilities, payloads, and use cases. Several platforms prioritize quiet operations, an especially valuable feature for applications in law enforcement as well as military. Some of the aircraft are designed with high levels of autonomy or are built to operate even in extreme weather conditions.

Ascent Aerosystems, one of the companies participating in the UAS Public Safety Summit, designs and manufactures coaxial UAVs for defense, public safety, and industrial applications. Ascent flew its Spirit platform during the summit for a live demonstration of the aircraft’s performance and low audio signature. The Spirit, along with Ascent’s other platforms, has one of the more unique configurations in the industry.

The Spirit platform is entirely modular, according to Bobby Sakaki, Sr. Product Manager at Ascent. The coaxial design uses two counter-rotating props that allow for more efficient flight. “Maximum payload capacity is about 6.5 pounds,” Sakaki said, noting that it can fly for 30 to 55 minutes depending on the payload. In addition to its modular architecture, the hardware itself is also modular, he added.

Ascent’s Spirit drone can fly in hail, sleet, snow, and winds over 40 miles an hour. Sakaki remarked that the Spirit is the most ruggedized platform in its class.

Ascent designs and manufactures coaxial UAVs for defense, public safety, and industrial applications.

Ascent’s drone in flight at the UAS Public Safety Summit (Photos: Jessica Reed)

The company has also developed a larger platform called the NX30, unveiled in April and launching later this year. The NX30 is tailored for material transport operations. “It’s built for heavy lift and endurance, and can carry a payload of 15 pounds,” Katie Glennon, Marketing Manager, told Avionics. “Right now it’s outperforming any of the delivery drones that are currently on the market,” she added.

Ascent’s team has also been working on a smaller and quieter platform that was originally developed with military applications in mind. “We realized law enforcement would like to use something they could carry on them all the time for tactical applications,” Ascent’s Sakaki explained. He described the drone as an ultralight, affordable ISR platform that can be used for overwatch. This smaller platform will have a flight time of over 30 minutes, and it could be available to customers by the end of 2022.

Skydio is another manufacturer that exhibited and demonstrated the capabilities of their drone platform at the Summit. Deepu John, Solutions Engineer, explained during the demonstration that Skydio’s drone avoids obstacles with full autonomy while capturing necessary data, even in complex environments.

John previously worked on the Technical Assistance Response Unit for the New York City Police Department (NYPD) before joining Skydio. He began developing the NYPD drone program that launched in 2019 and observed firsthand the challenges that come with piloting a manual drone in a complex urban setting or tactical scenario.

Skydio’s drones use artificial intelligence to create a three-dimensional model of its surroundings in real time and fly autonomously. The hardware on the aircraft includes the NVIDIA TX2, an AI computing device, and six 4K navigation cameras to enable 360-degree obstacle avoidance.

Skydio’s drone demonstrated its 3D scanning capabilities during the summit. (Photo: Jessica Reed)

”This takes all the cognitive load off of the pilot while they’re flying,” said Skydio’s Melanie Donaldson, Enterprise Account Manager – SLED, talking about their autonomous platform. “The pilot can actually focus on the mission and have full confidence that the drone is not going to crash.”

BRINC is a new company, launched in 2021, offering a lightweight drone ideal for use by first responders. BRINC’s team flew its LEMUR S drone into a building and throughout multiple rooms during a live demonstration, utilizing LiDAR-based pilot assistance that simplifies operation of the drone.

The LEMUR S platform is equipped with a two-way communication system including a speaker on the underside of the drone and two microphones on the front. It can fly indoors and it is designed to enter dangerous situations and ensure that it is safe before first responders or law enforcement enter the building.

The BRINC operator flying the drone had it crash into a wall to demonstrate that it can continue flying normally after a collision. Pictured above is the LEMUR S drone in midair after colliding with the wall. (Photo: Jessica Reed)

“We offer a care plan that covers everything—you can break it, you can crash it,” shared one of the representatives from BRINC. “Our goal is to put the new guys on it and get them trained up rather than putting them on a more expensive and sensitive drone.

The LEMUR S developed by BRINC has a 31-minute flight time and the battery charges to 90% in 45 minutes. Its maximum speed is 50 mph, and it weighs less than 2.5 pounds. (Photo: Jessica Reed)

Another lightweight drone featured at the UAS Public Safety Summit was senseFly’s 3.5-pound eBee TAC. The UAV can operate in disconnected environments to provide a tactical mapping solution. Its eMotion flight planning software enables offline flight planning and 3D flight planning. And the mission-directed sensor suite allows the operator to collect data for immediate use via the SD card.

Pictured above is the eBee TAC drone, and a photo of Gary Licquia of senseFly launching the drone into flight. The eBee TAC had one of the lowest operating noise levels of all UAVs that performed flights during the summit. (Top photo: senseFly)

Gary Licquia of senseFly remarked during the flight demonstration of the eBee TAC, “High-accuracy mapping is what we do best.”

The drone launches by hand and can perform two types of landings depending on wind conditions and available space. Some of the applications for the eBee TAC are VR simulation, map annotation and updating, surveying, and estimating line of sight.

Licquia explained, “This is meant to be the Swiss army knife. It’s utilitarian, easy to use, and simple. It just works when you need it to.”

The company Inspired Flight designs and manufactures UAVs like the IF750, tailored for applications such as physical asset inspections and geospatial applications like aerial surveying. Their drones are also ideal for public safety applications including emergency response, search and rescue, and border patrol.

One of Inspired Flight’s drones in flight at NUAIR’s UAS Public Safety Summit (Photo: Jessica Reed)

Inspired Flight recently launched a new model, the IF1200A, which it describes as an “industrial workhorse” ideal for high-value data collection. It can fly for up to 43 minutes and has a maximum payload capacity of 19.1 pounds.

The IF750 uses a ModalAI Flight Core flight controller, while the IF1200A relies on CubePilot Cube Blue H7 Triple Redundant IMUs.

“The smaller one, the quadcopter, has a payload of about 4 pounds,” according to Dale Crowner of Inspired Flight. “We are an integrator as well, so we can integrate any type of payload you’re looking for, like cameras or LiDAR,” he told Avionics.

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Eve Plans to Conduct Passenger Flights with Helicopters in Urban Air Mobility Study

Eve will be conducting flights via helicopter as part of a simulation to evaluate urban air mobility requirements for launching operations of its eVTOL aircraft. (Photo: Eve)

Eve Holding, electric air taxi developer, announced this week that it will conduct an urban air mobility (UAM) simulation using Blade Air Mobility helicopters in September. The simulation will take place at a heliport facility in downtown Chicago over the course of three weeks and will include passenger flights.

Eve’s main objective is to study UAM operations, ground services, and passenger journeys in order to prepare for eventually launching operations of its own aircraft, an electric vertical take-off and landing (eVTOL) vehicle.

André Stein, Eve’s co-CEO, remarked in the announcement, “Simulating the eVTOL operation in Chicago allows us to study how people will experience this service and understand the entire ecosystem requirements for our product and services.”

The simulation will also inform the City of Chicago about the infrastructure that will be required to enable growth of UAM in the city.

In addition to Blade Air Mobility, other partners working with Eve to conduct the simulation include Republic Airways, Halo Aviation, Vertiport Chicago, ACCIONA, SkyWest, Inc., and Speedbird Aero, as well as Village of Tinley Park and Village of Schaumburg.

“It is essential to understand and address through these projects involving partners and the community the key challenges associated with the main pillars of the UAM ecosystem,” commented Luiz Mauad, Eve’s Vice President of Services and Fleet Operations.

During the simulation, passengers will be transported via helicopter on one of two routes from Vertiport Chicago, the heliport facility. The routes are each about 25 to 30 miles long.

A full-size mockup of the eVTOL aircraft’s cabin at the Farnborough Airshow (Photo courtesy of Embraer and Eve)

Eve unveiled a full-sized mockup of its eVTOL’s cabin for the first time at the Farnborough Airshow last month.

In February of this year, Eve formalized the process to receive type certification with the Brazilian Civil Aviation Authority (ANAC) for its eVTOL. The company is also working with the Federal Aviation Administration and Europe’s EASA in order to formalize the validation process for type certification for Eve worldwide.

Eve has been listed on the New York Stock Exchange since May, following a business combination with Zanite Acquisition Corp. Customers have signed Letters of Intent for orders of 1,910 of Eve’s aircraft, as of the end of June, according to the company’s Q2 financial results.

In its letter to shareholders, the company stated, “Eve’s strategic partnership with Embraer is our most significant competitive advantage. The partnership includes a royalty-free license to Embraer’s background IP to be used within the UAM market as well as access to thousands of skilled Embraer employees on a flexible, first-priority basis and use of Embraer’s global infrastructure.”

Eve’s financial results from the first half of 2022 included a net loss of $21,282,359, as well as total assets recorded at a little over $331 million. Eve’s total assets amounted to about $15.3 million at the end of last year. Net cash used in Eve’s operating activities totaled more than $13 million, up from $5 million for the first half of 2021.

“As we continue to advance our eVTOL development, Eve expects to transition part of its non-binding orders into firm contracts,” the company stated in its letter to shareholders. “Those firm orders may result in significant cash advances and inflow to the company through down payments that tend to occur several months prior to final eVTOL delivery.”

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New Drone Technologies Emerge for Low-Altitude Public Safety Applications

Several companies developing next generation technologies for drones exhibited their solutions at the fourth annual UAS Public Safety Summit last week. The summit was focused on applications related to public safety that enhance capabilities for law enforcement and first responders.

Solutions presented at the summit included detect-and-avoid technologies, a module that tracks cell phone signals for search and rescue missions, and a platform for public safety officials to publish safety advisories about drone operations.

Hidden Level, headquartered in Syracuse, New York, specializes in low-altitude drone sensing software. The company offers a cloud-based solution, the Airspace Monitoring Service (AMS), to process data from sensors to track drones in real time. According to the company, its technology can detect the movements of more than 95% of commercially manufactured unmanned aerial vehicles (UAVs).

Hidden Level’s team has collaborated with NASA’s Ames Research Center to evaluate use of the AMS for drone traffic management applications and advanced air mobility (AAM) services. Hidden Level’s sensors enabled monitoring of both cooperative and non-cooperative low-altitude airspace traffic at Moffett Federal Airfield. The AMS data can also support research efforts related to airspace characterization; enable safe take-off and landing at vertiports; and monitor flight conformance.

Hidden Level is also involved in a partnership with Joby Aviation, developer of electric vertical take-off and landing (eVTOL) aircraft. The companies share their expertise in designing scalable airspace operations, relying on data collected by Hidden Level’s sensors installed in dense urban environments.

“We offer drone detection as a service,” explained James Licata, VP of Strategy and Partnerships at Hidden Level. “We build our own sensor technology and install it ourselves on rooftops and cell towers, typically in metropolitan areas, to cover as wide an area as we can,” he told Avionics International during the Public Safety Summit.

The AMS collects data on any drones operating in a given airspace and shares that data with agencies such as local law enforcement or corporate security. Hidden Level installs the technology and maintains it, and provides a data feed to the agency.

According to Licata, the company’s current focus is expanding its network to new cities. He noted that they have expanded coverage in the Northeast, and have installations in Mountain View, California, as well as Dallas Fort Worth. “We’re also working on some FAA initiatives,” he mentioned. “It’s been a lot of growth over the past year—we’ve doubled in size.”

Echodyne, a company that designs and manufactures radars for a range of markets, also exhibited its radars at last week’s UAS Public Safety Summit. The radar combines proprietary MESA radar technology with advanced software to detect and avoid objects in the airspace such as birds, drones, and other aircraft. It detects not only location and speed but also altitude, size, and range.

Leo McCloskey, VP Marketing for Echodyne, told Avionics that the company is constantly updating its radars through software. “Detecting and tracking small, fast aircraft in the airspace is both a new and difficult challenge,” he said.

“What Echodyne contributes is a breakthrough technology that shatters the price performance barrier to bring advanced radars that meet the challenge of airspace situational awareness. Our radar technology is essentially the same ESA [electronically scanned array] radar that is found in the nose of fighter jets. Radar technology is almost required to deal with the volumes of drones predicted over time.”

Some of the use cases include putting Echodyne’s radars on tethered quadcopters, autonomously flown vehicles, and fixed-wing aircraft. For public safety applications, the radar’s software allows the users to customize the performance to the location, mission profile, or other requirements.

A live demonstration of Echodyne’s software at the UAS Public Safety Summit (Photos: Jessica Reed)

Echodyne radars can detect any object moving in the airspace, regardless of the drone’s configuration or capabilities. The radars are widely used by U.S. Government Agencies for security and surveillance and by a number of UAS test centers and FAA and NASA test scenarios. An example is a $20m IDIQ contract awarded to Echodyne by the U.S. Department of Homeland Security. As the new technologies mature, they will be used more widely by state and local public safety agencies.

“Our radar is going to see everything that moves in the airspace, including the rotors on hovering drones,” McCloskey mentioned. The range of detection varies by product and use case. EchoGuard radar will track small drones at 1 km and large aircraft, like helicopters and Cessnas, at 2.5 km.

Each radar panel offers 120 degrees azimuth by 80 degrees elevation in coverage, with 4 panels providing very robust hemispherical coverage for events and portable use cases.

A new company called Flyhound, which also participated in the UAS Public Safety Summit, is set to launch its solution in October. Flyhound makes a module that can attach to a commercial drone and detect cell phone signals. The solution was originally designed with search and rescue missions in mind, said Manny Cerniglia, CEO and founder of the company.

Flyhound’s module can help first responders during or after a natural disaster like a flood or tornado to locate survivors that may still be in their homes. According to Cerniglia, they are considering a version of the technology that tracks specific individuals. The module would attach to a firefighter’s equipment, for example, to detect their location inside a building and assist them more quickly.

Flyhound’s module is attached to a drone and tracks cell phone signals to quickly locate individuals for search and rescue operations. (Photo: Flyhound)

Another company at the summit that demonstrated its solutions for drones was Aloft. Aloft powers the Federal Aviation Administration’s drone safety app, B4UFLY. The app allows recreational and commercial drone operators to check the airspace before taking flight, and it provides alerts regarding active airspace advisories.

Aloft launched Geo Portal, a free tool for publishing safety advisories related to drone operations, in May this year. The platform supports both permanent and temporary advisories, according to CEO and founder Jon Hegranes, and operators can also schedule future advisories. The Aloft Geo Portal was developed for use cases such as firefighting, public events with special drone rules in effect, and operations in areas with relevant local drone regulations.

Aloft Geo Portal was launched earlier this year as a free tool for publishing safety advisories. (Photo: Aloft)

“About a third of Geo users are law enforcement or first responders,” Hegranes remarked.
One unique feature of the app is called Notify & Fly. This allows operators to anonymously announce to other drone pilots that they are flying in a particular area, increasing situational awareness as more drones are integrated into the national airspace—without sacrificing privacy, according to Aloft.

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EHang Releases Q2 Financial Results Showing Increased Total Revenue and Net Loss of $11M

EHang plans to debut its eVTOL aircraft for passenger flights at the 2025 World Expo. The company recently announced its Q2 financial results, and the management team held an earnings call to share details about their progress. (Photo: EHang)

Electric air taxi developer EHang announced financial results for the second quarter of 2022 on August 18, following financial updates from two other leading electric vertical take-off and landing (eVTOL) aircraft developers, Joby and Archer, this month. EHang is pursuing type certification with the Civil Aviation Administration of China (CAAC) for its vehicle, the autonomous EH216, and has made significant progress towards this objective in the past year.

EHang performed a series of demonstration flights last month in Japan, including the country’s first eVTOL demo flight over the sea in Fukuyama City. The company’s CEO, Hu Huazhi, remarked that they expect to offer crewed flights with the EH216 at the World Expo 2025 in Osaka.

The EHang team has also claims to have conducted over 5,700 operational trial flights of the EH216 so far.

According to EHang’s unaudited Q2 results, total revenue amounted to $2.2 million (USD), a 152.5% increase from the first quarter of 2022. Net loss increased slightly for EHang’s second quarter, totaling $11 million.

Huazhi commented during the earnings conference call that the company “continues to expand our orders, preorders, deliveries and customers, especially in China and Southeast Asia” in 2022.

EHang recorded sales and deliveries of 8 units of its autonomous aerial vehicle (AAV); the company recorded just 3 units in Q1.

A flight demonstration of the EH216 in Bali, Indonesia (Photo: EHang)

The CAAC announced in February the formal adoption of Special Conditions for Type Certification of EHang’s EH216-S aircraft. The 216-S model is specifically designed for transporting passengers; EHang also plans to offer a 216-L model for logistics and a 216F for firefighting operations. These Special Conditions define the process by which EHang will proceed with compliance verification as the company works towards type certification.

Huazhi explained during the earnings call, “The most important thing for us at present is the EH216-S airworthiness certification, and the process has progressed into new phases since this year. Before the CAAC issued the special conditions, there had not been any available airworthiness certification standards applicable to this new type of aircraft.”

He continued, “As there was no precedent, we had to closely work with the CEC to further develop this new type of airworthiness standards together according to the relevant airworthiness concept and principles.”

Once the EH216 has been awarded an airworthiness certificate, it will offer a cost-effective, low-altitude platform for customers in the tourism industry, according to Xin Fang, Chief Operating Officer. He noted that they received a pre-order for 100 EH 216 aircraft from Prestige Aviation, based in Indonesia. “We are actively expanding our presence through the empowerment of local partners in Southeast Asia, where the UAM market is also in high demand,” he stated during the earnings call. EHang is also collaborating with CP Group to introduce its AAVs in Thailand.

COO Xin Fang also shared that the company has invested all of its efforts into autonomous technologies from the start, “including flight control algorithms, the flight lift systems, and battery systems and also the command and control systems.”

A total of 210 of EHang’s passenger-grade AAVs have been pre-ordered in Asia, and Fang shared that they expect at least 200 of customer pre-orders to be delivered in roughly three years. EHang has already delivered five aircraft that are performing trial operations now.

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FreeFlight Systems Receives TSO Authorization for 5G-Ready Altimeters

(Photo: FreeFlight Systems)

FreeFlight Systems, the Irving, Texas-based avionics manufacturer, has received Technical Standard Order (TSO) authorization from the Federal Aviation Administration for its RA-6500 and RA-5500 Terrain series radar altimeters. TSO authorization is the latest milestone completed by FreeFlight on the new altimeters that use radiofrequency (RF) filters and digital signal processing techniques to protect radar altimeter signals from potential 5G C-band wireless network interference.

Anthony Rios, president of FreeFlight Systems, first provided an overview of how their new altimeters mitigate against 5G C-band interference in December last year as the FAA was preparing a series of directives and policy updates related to landing at airports located near new stations operated by AT&T and Verizon. The company’s TSO authorization received for the RA-6500 dual install and RA-5500 single install altimeters follows its launch of the RA-4500 Mark II (MK II) in March.

The FAA issues TSO authorization to aviation companies for equipment that has demonstrated the ability to meet government-industry agreed upon minimum performance standards. Receiving a TSO authorization confirms both design and production approval, according to the FAA.

The RA-5500 (Photo: FreeFlight Systems)

“We have a considerable backlog of orders from operators and OEMs, particularly the Advanced Air Mobility (AAM) segment. Now having the TSO certification, we are ready to begin product shipments,” Rios said in a statement released by FreeFlight. “This is good timing considering the accelerating deployment of 5G networks across the country which continues to challenge flight safety.”

TSO authorization for the new altimeter technology has been issued for FreeFlight two months after the FAA released its latest 5G C-band policy update. In June, the agency released a statement explaining that operators of regional aircraft determined to be the most susceptible to interference from 5G C-band wireless signals will need to install 5G-tolerant RF filters by the end of the year.

AT&T and Verizon also reached an agreement with the FAA in June to delay switching on some portions of their respective 5G C-band wireless networks until July 2023.

The RA-6500 and RA-5500 altimeters have been developed for “all segments of aviation,” according to FreeFlight, including fixed and rotary-wing commercial transport, business, and military aircraft.

FreeFlight has also retained an analog ARINC 552 interface on the RA-5500 and RA-6500 for “integration with legacy indicators and components,” according to the company.

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Britten-Norman Developing Garmin TXi Certification for Islander Cockpits

A computer rendering of Britten-Norman’s BN2T Islander with Garmin TXi EIS instrumentation (Photo courtesy of Britten-Norman)

Britten-Norman, the U.K.-based turboprop aircraft manufacturer, is developing a type certification path for the integration of Garmin’s TXi engine indication system (EIS) into its Islander aircraft, according to an AUg. 18 announcement by the two companies.

Britten-Norman has been manufacturing its BN-2 Islander since 1965, with 1,250 of the light utility aircraft produced and an estimated 750 still in service with commercial operators around the world. Garmin signed a development and distribution agreement with the company to create a Civil Aviation Authority (CAA)-approved supplemental type certificate allowing TXi to be retrofitted or added to new Islander aircraft.

“It not only gives our customers an affordable technology solution, but it also provides improved engine efficiency which is essential when considering sustainability,” Mark Shipp, technical director and head of design at Britten-Norman, said in a statement. “This is one of several enhancements being launched this year under a larger 2022 R&D investment strategy.”

The TXi was developed by Garmin as a system capable of monitoring the performance of “aspirated or turbocharged Lycoming and Continental 4- to 6-cylinder engines powering GA singles and twins,” according to the company’s website. Garmin manufactures the TXi in a 7-inch and larger 10.6-inch display with color-coded pointers and data bands serving as indicators for normal operating ranges, cautions, and exceedances.

“We have a great heritage of innovation at Britten-Norman and we are excited to continue our work in that tradition. We are concurrently working on multiple projects to provide enhanced technology options and digitisation,” Grahame Stone, commercial director for Britten-Norman, said in a statement. “Having a technology partner such as Garmin working so closely with the company on products like their intuitively designed EIS helps us to keep the Islander cockpit relevant and up-to-date and ensures that we are able to pass on significant safety benefits and product enhancements to our customers at prices that are appropriate to the current international market conditions.”

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National Aviation Day: Looking Back at How Boeing Integrated the 787’s Avionics Systems

(Photo courtesy of Boeing)

In 1939, Franklin D. Roosevelt issued a presidential proclamation designating August 19 as National Aviation Day to commemorate the Wright Brothers’ first flight completed in 1903. As the aviation industry celebrates the day with a wide array of historical facts and figures, we’re re-publishing an article from the Avionics International magazine’s digital/print archives first published in June 2005 analyzing how Boeing constructed the Boeing 787’s avionics systems architecture.

The article was written by former editor-in-chief David Jensen, and he explains how the avionics network came together for the 787 Dreamliner, which first entered passenger-carrying commercial service in 2011. Our coverage from six years prior has been re-published in its original form below, with updated images of 787’s avionics.

Happy National Aviation Day!

B787 Cockpit: Boeing’s Bold Move

By David Jensen | November 1, 2005

It is the most integrated, most supplier-based cockpit, using the largest display system and the most open architecture of any commercial aircraft developed by Boeing. The B787 flight deck also represents a major realignment in the way the airframe manufacturer manages avionics development and production.

EVERETT, Wash., Aug. 31, 2005 — “Boeing worked with airlines and pilots around the world to develop a flight deck that complements the unique improvements featured in the passenger cabin of the all-new 787 Dreamliner. All display formats in the 787 flight deck are the same as in the 777, including the flight management computer pages the overhead (systems controls) layout is identical the autoflight mode control panel layout also is identical. Key features of the Dreamliner flight deck include larger displays, dual head-up displays and dual electronic flight bags.” – Boeing Commercial Airplanes

To save weight and space, Boeing has called for fewer wires and greater integration of subsystems. (The company plans to make the B787’s avionics suite 2,000 pounds [907 kg] lighter than earlier-generation systems.) And to save acquisition costs and exploit economies of scale, it chose to standardize the avionics package. No longer will Boeing’s airline customers receive an unequipped airplane and then select the avionics systems piecemeal. Rather they will receive a comprehensive package that incorporates new standard systems, such as dual head-up displays (HUDs) and dual electronic flight bags (EFBs), plus an architecture that will readily accommodate the addition of new functions and upgrades.

Rockwell Collins is probably the biggest beneficiary of Boeing’s new philosophy and development of the B787. Although it played a major role in equipping the B737 Classic, B757 and B767, Collins’ largest enterprise with Boeing, in terms of line replaceable units (LRUs) and in engineering, is unquestionably the B787 program, according the Greg Irmen, Collins’ senior director of Boeing programs. The electronic systems supplier and integrator stands to gain up to $3.5 billion over the life of the B787 program.

A Systems Integrator

Collins also is a B787 systems integrator. It, rather than Boeing, will be gathering large sections of the flight deck subsystems to produce system packages–work that will take place in a specially built lab in Cedar Rapids, Iowa. The packages then will be delivered to Seattle in modules for installation in B787 airframes. Collins’ work represents a major part of Boeing’s new philosophy of having first-tier suppliers carry out most of the B787’s integration work.

“A lot of equipment below the flight deck used to be sent to Boeing in hundreds of pieces for assembly,” says Irmen, referring in this case to the pilot controls. “Now we will provide just a few modules.” The B787’s pilot controls will consist of just four modules: the control stand assembly, pitch control assembly, lateral control assembly, and yaw control/brake assembly.

In addition to being a systems integrator and pilot control supplier, Rockwell Collins will provide the B787’s displays and crew alerting system, communications radios, and the surveillance system. Smiths Aerospace will supply the B787’s Common Core System (CCS) that provides the processing, network and input/output (I/O) resources to many aircraft functions. And Honeywell will provide the B787’s navigational package, terrain awareness warning system (TAWS), flight management system (FMS) and fly-by-wire system.

Like the B777—Somewhat

Although the B787 cockpit represents a major shift in development and design, it also is meant to provide commonality with the B777 flight deck, to facilitate transition training. (Boeing’s goal is for B777 pilots to train no more than five days for B787 transition.) This commonality posed unique challenges for Collins. “One of the biggest challenges was the check lists; we wanted to make sure the check lists in the two aircraft are extremely common,” says Irmen.

“The other area that’s a challenge is the pilot controls,” he adds. “We’re working to make the feedback from the 787 controls feel the same as in the 777. In other words, we’re working to duplicate the force feel curves for each axis: pitch, yaw and roll.” Rockwell Collins Electroprecision in Irvine, Calif., is developing the B787 pilot controls.

A major distinction between the two aircraft cockpits is the display size. The B787 boasts five 15.1-inch diagonal, liquid crystal displays (LCDs)–twice as large as the B777’s screens. The B787 will be the first commercial aircraft to be equipped with these large displays, although they may be installed in a government/military aircraft prior to the the Dreamliner’s scheduled entry into operation in 2008. “We’re working on another program on the government side,” says Irmen, adding that he could provide no further details of potential display system orders.

The B787 has two primary displays and two navigational displays for the two pilot positions and a display in the center console, also referred to as the “aisle stand.” All displays are in landscape format. The center display “is where the pilot and copilot do their flight management activity and route planning,” says Irmen. “There is a keyboard and cursor control [a scratch pad] on either side of the display, and each pilot can enter data independently.”

The large, 12-by-9.1-inch displays provide the obvious benefit of better pilot viewing, but Collins also selected the size to protect against obsolescence. “The displays are commercial glass [provided by Japan’s Sharp Corp.]; they’re the same LCD as you use with your laptop, only enhanced,” says Irmen. “We think laptops with screens that size will be around for a long time.” For aviation use, those screens will be ruggedized.

The large displays can present more information. One new feature that Collins plans for the B787 panel displays is the presentation of airport surface maps. These graphical displays will be able to show ownship position on the runways and taxiways. “As we progress and improve the technology, we could also use the onboard radar and transponder to show the surface traffic and obstacles on the surface map and perhaps provide runway guidance,” Irmen adds.

Surface maps could, of course, also appear on the B787’s two electronic flight bags. However, the extent to which the EFBs interface with onboard systems–most notably the FMS–is still under discussion, says Irmen.

As in the B777 and the newest version B737, the EFB hardware for the B787 will supplied by Astronautics Corp. of America and the software, by Jeppesen, now part of Boeing.

Offering the B787 pilots further situational awareness are the two head-up displays, furnished by Rockwell Collins Flight Dynamics, in Portland, Ore. In addition to primary flight display (PFD) symbology—attitude, altitude, airspeed, etc.—the B787 HUDs also will present windshear warnings and escape guidance, as well as “some takeoff cues” for guidance when visibility is limited, according to Irmen.

EVERETT, Wash., June 20, 2008 – Boeing [NYSE: BA] has completed Power On for the first 787 Dreamliner. The test sequence lasted for just over a week and proved the functionality and installation of the airplane’s electric systems.
Running tests in the flight deck are (from left) James Townsend, aviation manufacturing technician inspector; Allen Smith, test technician; Jon Stephenson, production test manufacturing engineer; and Riger Vazquez Jr., production test team leader.

The CCS

The B787’s nerve center is its common core system, which Smiths Aerospace refers to as an “open architecture platform,” with the ability to adopt new applications not unlike a desktop computer. Hosted functions–for example, flight management–utilize the processing, network and input/output resources provided by the CCS in a similar manner that desktop computer applications use the processor, operating system and peripherals.

The CCS consists of three major elements: processing resources to execute hosted function applications software; the common data network (CDN) that provides reliable communications between processing, I/O and function-specific equipment; and remote data concentrators that provide gateways to analog, discrete, controller area network (CAN) bus , and legacy ARINC 429-based equipment. For specialized functionality—for example, graphics generation—hosted functions can implement special modules that interface to the CCS, based on an open standard network interface.

Smiths distinguishes the CCS’ distributed open architecture from the federated systems of past. Instead of each LRU’s having its own processing, infrastructure, I/O and internal bus, the CCS has common processing with “robust” partitioning, a common infrastructure and distributed system bus.

Robust partitioning means not just separating the software, according to Gerry Vossler, Smiths’ vice president of advanced marketing and technology. “The system is proven to maintain partitions robustly over the processing, the network and, to some extent, the I/O,” he explains.

The open architecture facilitates the addition of new applications. It accommodates upgrades and allows Boeing freedom in selecting the best providers of subsystems, says Vossler. To develop a new system for the B787, the vendor need only know the specifications for the power and the AFDX network interfaces, which apply the ARINC 653 standard.

“With ARINC 653 you know how to communicate [with the CCS]. Every supplier [for the B787] does it the same way; there’s no ambiguity,” Vossler maintains.

Recognizing that in many cases some processing has to reside in the individual LRU, Boeing nevertheless has set a goal to have as much onboard processing as possible performed by the CCS. In fact the CCS hosts even the flight management system function.

The CSS performs most of the processing for the B787’s display system, as well. “There is a very tight integration between our displays and the CCS,” says Collins’ Irmen. “The majority of the display applications are run on the general processing modules of the CCS. The display information is then sent over to our graphics generation module [GGM], housed in the CCS cabinets. It’s sent using ARINC 661 [standard for flight deck display interface] over Ethernet, where it is formatted for display and sent to the displays over a pixel bus. Other systems, such as the CISS [configurable integrated surveillance system], also generate display information and send it to the GGMs over ARINC 661 for display.”

Some systems on the B787 do retain their own processing, however. And the challenge, Vossler, observes, is determining how the processing is divided between the LRU and CCS. For example, in the anti-skid braking system, rapid processing is required but only during a brief interval of the flight. “So you would have all of the fast processing done locally in the LRU,” he says.

The B787’s CCS processing resources are comparable to the core processor that Smiths developed for the C-130 AMP (Avionics Modernization Program). Both use the ARINC 653 standard, and both employ the same real-time operating system, Wind River Systems’ Platform Safety Critical for ARINC 653 (PSC). But while the C-130 system incorporates about seven applications, the CCS can accommodate up to 100 applications. Vossler attributes the difference to the CCS’ increased processing power and networking bandwidth plus the fact that some C-130 functions may require more processing resources. He adds that the B787’s CCS will initially amalgamate about 70 applications for 20 to 25 suppliers.

The 787’s common core system (CCS) (Photo courtesy of GE Aviation)

A key element of CCS is the common data network (CDN), a deterministic Ethernet avionics duplex switched (AFDX) network, using ARINC 664 protocols and standards. Collins provides Smiths the CDN’s elements: the network switches and end systems. The CDN connects the processors, the remote data concentrators and specialized LRUs, using fiber or copper connections.

To support the distributed nature of CCS, network switches are located in the common computing resources (CCR) cabinets and are mounted throughout the aircraft.

RDCs—Reducing Wires

The CCS also incorporates remote data concentrators (RDCs), which are distributed throughout the aircraft and serve as digital gateways for the B787’s various functions. They are gateways for analog, discrete, ARINC 429 and CAN bus data off and on to the CDN.

Among other benefits, the RDCs reduce the amount of wiring in the B787. Instead of each function being linked (often by long wires) directly to the CCS, a group of functions is connected by short wires to the local RDC, which, in turn, is linked to the CCS via AFDX cable. The use of RDCs is similar to the use of USB-based devices on a personal computer, but now they are distributed. The RDC distributes the I/O interface, removing it from the electronics rack, says Vossler.

The B787’s forward electronics bay houses the CCS in two common computing resource cabinets. The dual cabinets don’t represent the system’s redundancy, however. Vossler explains that the redundancy on board the aircraft is based on the overall architecture, combining a set of high-integrity processing resources, a high-integrity network, and distributed remote I/O devices (RDCs). “The CCS provides the resources to the meet the function’s integrity requirement,” he adds.

As a key component of the Smiths common core system, Rockwell Collins is providing the common data network, which joins the B787’s less critical systems. Indeed, it has a firewall that isolates the less critical applications, such as cabin systems, from the highly critical flight deck systems. Essentially an onboard server, the common core network has room for five file server modules, each with processing power equivalent to a PowerPC, says Collins’ Irmen. The module can host various applications:

One module hosts the aircraft’s health management data load system; it allows the secure transfer of maintenance data to a ground-based laptop or data loader, or over a data link.
One module is available to host the Connexion by Boeing broadband data link service.
One module hosts Boeing Commercial Aviation Services (CAS) software, used to provide, for example, in-flight entertainment system or other marketing data.
The remaining two modules are open to the airline’s use at its discretion.

Com/Nav/Surveillance

Collins will supply Boeing’s new aircraft its CISS 2100 configurable integrated surveillance system, which combines the processing for the weather radar, Mode S transponders, TAWS, and traffic alert collision avoidance system (TCAS) in a single cabinet in the electronics bay. Honeywell supplies the TAWS, and Collins provides its PMR-2100 MultiScan weather radar and transponders. The CISS processor gathers radar data over a fiber optic line and then processes the weather information along with the TAWS and TCAS data for presentation on one of the cockpit displays. The pilots can select various options in the radar and TCAS independently.

The Collins communications package includes the VHF 2100 radio, which is VHF digital link, Mode 2 (VDL-2)-capable and can be upgraded to accommodate VDL-3, according to Irmen. He adds that the company is investigating an upgrade to VDL-4, as well. Rounding out the B787 com package is the HFS-900C HF radio and the SAT-2100 satellite communications radio, offering three voice channels and the capability of adding Inmarsat’s data service.

In addition to the flight management function, Honeywell will supply the following navigation equipment for the B787:

Inertial reference system (IRS),
Air data system,
Two DME radios,
Two radar altimeters,
Emergency locator transmitter, and
Two integrated nav receivers (INRs), each containing an ILS (localizer and glideslope), marker beacons, VOR, GPS and GPS landing system (GLS). The INRs provide capability for Category IIIB ILS and Cat I GLS approaches.

Honeywell also provides the B787’s two attitude heading reference systems (AHRS), capable of attitude and heading in the remote case that the aircraft has a dual IRS failure.

Boeing 787 Customers

The folks at Boeing have been working diligently to both develop and market the new twin-aisle aircraft, the B787. In late April it unveiled the aircraft’s final exterior design. Major assembly of the first aircraft is to begin next year, and first flight is scheduled for 2007, followed by initial deliveries in 2008.

Since it announced its launch customer, All Nippon Airways, in April 2004 Boeing has accumulated firm orders and commitments for 273 aircraft from 23 airlines in four continents: Africa, Asia, Europe and North America. The first North American operator of the B787 will be Northwest Airlines, which ordered 18 aircraft. The following are the B787 customers plus their combined commitments and firm orders:

Air India 20
Air New Zealand 2
All Nippon Airways 50
Blue Panorama 4
Continental Airlines 10
Ethiopian Airlines 10
First Choice Airways 6
Garuda Indonesia Airlines 19
Icelandair 2
Japan Airlines 30
Korean Air 10
LOT Polish Airlines 7
Northwest Airlines 18
Primaris Airlines 20
Royal Air Maroc 4
Vietnam Airlines 4

In addition, Boeing has booked a firm order for six aircraft from an unidentified customer and has commitments for 36 aircraft and firm orders for 24 aircraft from a group of six Chinese airlines. In total, Boeing had, in September, commitments for 99 B787s and firm orders for 174 B787s.

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