The Servair Blog - Avionics, IFE, Satcoms and IT Consultants

RTX’s Pratt & Whitney Receives $1.3 Billion F135 Engine Core Upgrade Contract – Oct. 1

RTX‘s Pratt & Whitney has received a more than $1.3 billion cost plus incentive fee contract for the F135 Engine Core Upgrade (ECU) for the Lockheed Martin F-35 fighter, DoD said on Monday.

U.S. Air Force Brig. Gen. Jason Rueschhoff, 56th Fighter Wing commander, boards an F-35A Lightning II for his final flight on June 14th at Luke AFB, Ariz. (U.S. Air Force Photo)

The contract includes design, analysis, rig testing, engine test preparation, developmental hardware, test asset assembly, air system integration, airworthiness evaluation, and product support planning to mature ECU, the Pentagon said.

In July, Pratt & Whitney said that it had finished preliminary design review on ECU.

Jill Albertelli, president of Pratt & Whitney’s military engines business, said on Monday that the contract is “critical” to allow continued work in the ECU risk reduction phase “with a fully staffed team focused on design maturation, aircraft integration, and mobilizing the supply base to prepare for production.”

In March last year, the Air Force said that it had decided to move forward on ECU for the F-35 and end the service’s Advanced Engine Transition Program (AETP).

As part of AETP, General Electric had proposed its XA100 Tri-Variant Adaptive (TVA) engine to accommodate the envisioned Block 4 weapons and other upgrades for the Lockheed Martin F-35.

A version of this story originally appeared in affiliate publication Defense Daily.

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Northrop Grumman Demonstrates MQ-4C Navigation In Arctic Circle – Sept. 20

Northrop Grumman on Thursday announced it demonstrated the ability of a navigation system used by a MQ-4C Triton unmanned aerial vehicle to operate at high latitudes within the Arctic Circle.

An MQ-4C named B8, the first production MQ-4C Triton upgraded to the IFC-4 configuration flies over California. It was delivered to the Naval Air Station Patuxent River, Md. on Feb. 1, 2022. (Photo: Northrop Grumman)

The company told sister publication Defense Daily this demonstration test flight used a company-owned manned aircraft with a mounted Triton navigation system. It started in Deadhorse, Alaska and flew within 100 miles of the North Pole.

The navigation system included the mission management computer and upgraded operational flight programs to demonstrate the Triton’s ability to navigate that far north.

The aircraft collected data over a five-hour flight, remaining in U.S. and Canadian airspace.

The company said this demonstration also validated ground-based GPS alignment and initialization procedures to allow operations from runways above 70 degrees north latitude.

Northrop Grumman also told Defense Daily this demonstration validated the hardware and software capability that currently exists on the MQ-4C.

Northrop Grumman argued this delivers on its commitment to provide intelligence, surveillance, reconnaissance and targeting capabilities in the High North, operating in the austere environment of the Arctic Circle.

The Triton itself is able to operate at altitudes over 50,000 feet for over 24 hours at a time. The company noted this means it can operate above harsh Arctic winds and avoid the speed and range impacts that limit performance at more medium altitudes in the 10,000-30,000 feet range.

This came after similar demonstrations over the Gulf of Alaska in summer 2023, including testing the Triton radar during the Northern Edge 2023 exercise.

The U.S. Navy and Royal Australian Air Force operate the MQ-4Cs.

A version of this story originally appeared in affiliate publication Defense Daily.

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Demand Accelerates for Virtual Reality Training in Avionics

Global Avionics Round-Up from Aircraft Value News (AVN)

VR training is emerging as a critical trend in avionics, promising to revolutionize how pilots, engineers, and maintenance crews are trained.

Rapid advancements in virtual reality (VR) are transcending gaming and entertainment, finding a pivotal role in industries like health care, engineering, and now aviation.

VR training is emerging as a critical trend in avionics, promising to revolutionize how pilots, engineers, and maintenance crews are trained. VR is transforming aviation training by offering immersive, realistic environments for skill development while reducing costs and improving safety.

The complexity of modern aircraft systems and the demand for highly skilled aviation professionals make VR an ideal training solution. VR’s ability to simulate real-world scenarios in a controlled environment allows pilots and technicians to engage in highly realistic exercises.

Trainees can experience flight dynamics, system malfunctions, and emergency procedures without risking equipment or lives. The technology also enables repetitive practice, which is crucial for mastering complicated procedures, all while saving time compared to traditional simulators or on-the-job training.

Several key players in recent months have been driving the adoption of VR in aviation, particularly in avionics:

CAE. A global leader in aviation training, CAE has integrated VR into its pilot training programs. The company’s VR-based solutions provide immersive cockpit environments for pilots, enhancing traditional training with virtual scenarios that mimic real-life conditions.

Thales Group. Thales has made significant strides so far this year in VR training for aviation. The company’s platforms combine augmented reality (AR) and VR, creating scenarios for both pilot and maintenance training. Thales’ immersive AR/VR tools allow trainees to troubleshoot avionics systems and practice routine inspections, enhancing their decision-making and technical skills.

Boeing. The U.S.-based aerospace giant is investing heavily in VR for its own aircraft systems and has developed virtual training modules for pilots and engineers. Boeing’s VR solutions focus on operational and procedural training, including emergency protocols and maintenance tasks, providing an efficient and scalable solution for airline operators. As the company grapples with its continuing regulatory woes, it has been beefing up inspection and safety procedures in recent months through an increasing reliance on VR.

Airbus. Archrival to Boeing, the European-based Airbus recently introduced its VR Flight Trainer, which allows pilots to simulate and interact with advanced avionics systems, particularly for the A350 and A320neo families.

A320neo aircraft are particularly leveraging the VR Flight Trainer, which is just one of many factors lifting the aircraft’s base values and lease rates.

Airbus’ emphasis on virtual training reflects the growing demand for digital tools that can keep up with the complexity of modern aviation technology.

So far in 2024, several VR training programs have emerged as benchmarks in the aviation industry:

Project CAVOK by CAE. This project integrates AR and VR for pilot and technician training, combining immersive environments with real-world aircraft components. CAVOK aims to address the shortage of pilots globally by providing high-quality, scalable training.

Thales’ Maintenance VR Suite. Thales has expanded its VR suite to focus on avionics maintenance, enabling technicians to work on virtual replicas of critical aircraft components. The platform includes AI-based learning modules that adjust training difficulty based on user performance, offering personalized learning experiences.

Airbus VR Maintenance Trainer. Airbus’ program, launched in late 2023, offers a fully immersive maintenance trainer that simulates various systems within their A350 and A320neo families. This allows engineers to practice complex repairs and upgrades in a virtual environment before working on actual aircraft.

As aviation technology becomes more advanced, the need for specialized training solutions grows. VR (as well as AR) offer several benefits that make it an indispensable tool in avionics training for 2024 and beyond, notably cost efficiency, safety and risk management, and scalability for the growing workforce.

This article also appears in the October 7 issue of our partner publication Aircraft Value News.

John Persinos is the editor-in-chief of Aircraft Value News. You can reach John at: jpersinos@accessintel.com

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The Nexus of Avionics, Artificial Intelligence, and Aircraft Values

Global Avionics Round-Up from Aircraft Value News (AVN)

As AI systems enhance the operational performance of aircraft, demand for such planes is surging, driving up base values and lease rates.

The global avionics market is on track for major multiyear growth. What’s more, artificial intelligence (AI)-infused avionics upgrades already are influencing aircraft base values and lease rates.

According to new research released in September 2024 by Fortune Business Insights, the global avionics market size was valued at USD 91.32 billion in 2023 and is projected to grow from USD 99.33 billion in 2024 to USD 179.44 billion by 2032, for a compound annual growth rate (CAGR) of 7.67% during the forecast period. North America dominated the avionics market in 2023 with a market share of 37.25% (see chart).

The avionics market’s growth is driven by technological advancements, as well as increasing revenue opportunities in international routes. Moreover, the rising procurement of next-generation military aircraft, both for transport and combat operations, is further accelerating market expansion during the forecast period. Innovations in military aviation typically spill over into the civilian sector, making commercial and defense aerospace two sides of the same coin.

Many avionics advancements in commercial aircraft got their start through military research and development. Global military budgets are ballooning, fueled during the past two years by increasing superpower rivalry and the Russia-Ukraine war. The U.S. spends by far more on defense than any other country. Avionics capabilities are expanding in tandem with these expenditures.

The avionics market is divided into two primary categories: hardware and software. In 2023 and so far into 2024, hardware has maintained a leading market share due to its multitasking capabilities, such as trajectory prediction and route guidance. Many original equipment manufacturers (OEMs) have introduced new high-performance hardware solutions for both commercial and military aviation.

However, the software segment is projected to experience the highest CAGR in the coming years. This surge is driven by the increasing integration of software in avionics to enhance flight operations. Many OEMs are forming partnerships and joint ventures to develop the most advanced avionics software solutions.

The AI revolution…

A megatrend reshaping avionics is the integration of AI. Avionics systems powered by AI are revolutionizing the way aircraft are flown, introducing unprecedented levels of automation, decision-making, and predictive capabilities.

According to Precedence Research, the global AI in aviation market size was estimated at USD 653.74 million in 2021 and it is expected to surpass around USD 9.98 billion by 2030 with a CAGR of 35.38% from 2022 to 2030 (see chart).

Recent developments in avionics and information technology have greatly minimized the need for manual inputs and actions by pilots, particularly for routine tasks. Pilots now spend more time overseeing, managing, and programming control panels within the cockpit, rather than focusing on the traditional hands-on flying of the aircraft.

AI-infused avionics are poised to further streamline operations, improve safety, and optimize fuel efficiency. Leading-edge avionics can help reduce fuel burn, which in turn reduces carbon emissions and helps aircraft meet new and stringent “green” regulations.

As AI systems enhance the operational performance of aircraft, demand for such planes is surging, driving up base values and leasing prices.

Conversely, older aircraft lacking these capabilities may see depreciation, pushing down their value in the secondary market. This trend is likely to redefine the competitive landscape in aviation, positioning AI-enabled aircraft as the future standard for both commercial and military aviation.

This article also appears in the October 7 issue of our partner publication Aircraft Value News.

Editor’s Note: To watch a video presentation on this avionics-related topic, visit https://www.aircraftvaluenews.com/video/

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Cybersecurity in the Skies

Securing aircraft and associated systems against potential cyberattacks ensures the safety and integrity of communication, navigation and operational systems.

In 2015, Chris Roberts, a cybersecurity consultant told the FBI he hacked into computer systems aboard airliners up to 20 times and even managed to control an aircraft engine during a flight, according to federal court documents. He told investigators he did it via the in-flight entertainment systems. Roberts also said that once he even hacked into the systems and then overwrote code, enabling him to issue a “CLB,” or climb, command.

In 2018 The Cathay Pacific Airways data breach resulted in 9.4 million accounts being breached with stolen data including credit card information, passport information and phone numbers. This attack was the direct result of negligence by the airline carrier to keep its data secure from malware; it was a full-scale attack on their servers. The attacks continued until May 2020.

Cybersecurity aims to prevent events like these. Cyberattacks are one of the top concerns for the aviation industry, and it is imperative for airline companies to mitigate risks and protect their flights and sensitive data from having them happen.

Securing Aircraft and Data

The aviation industry has undertaken a massive digital transformation over the past 15 to 20 years, from the corporate side of the airline to the aircraft, its ground and its interconnected systems. With these digital systems and advanced technologies, the industry requires necessary cybersecurity measures in order to sustain and ensure safety, reliability and resilience.

The primary role of aviation cybersecurity is to secure aircraft and associated systems against potential cyberattacks. This includes ensuring the safety and integrity of communication, navigation and operational systems on board the aircraft. “The uniqueness of aviation in relation to cybersecurity lies in the complexity and interconnectedness of its systems, which operate both on the ground and in the air,” says Roy Arad chief revenue officer at Cyviation, New York City. “Upcoming EASA Regulations Part IS will require airlines to address cybersecurity comprehensively and start proactively monitoring and mitigating cyber threats to comply with these new standards.”

Cybersecurity plays an integral role in the day-to-day operations of aviation. Michael Goodfellow, technical officer, global interoperable systems, air navigation bureau, International Civil Aviation Organization (ICAO), Montreal compares it to safety, “rarely seen or publicly appreciated, but its absence is quickly observed and seriously missed. What makes cybersecurity unique in aviation is that while assets must be protected, this cannot be done at the expense of the safety of operations and the personnel involved.”

Cybersecurity ensures that data being transmitted from an aircraft to organizational networks is always protected to prevent the unauthorized theft of information. The continuous mitigation of risk forms a key component of cybersecurity activity. Josh Wheeler, senior director entry into service & client services at Satcom Direct Inc., Melbourne, Fla., says it’s the numbers that explain why this matters. “In 2023, the cost of cyber data breaches averaged around US$4.45 million. This doesn’t include reputational damage. Alarmingly, the average time to detect a violation was nearly four months. With 53% of users not changing passwords regularly or recycling the same password across different accounts and additionally, an alarming 57% of users writing passwords on sticky notes for all to see, some eight billion data records were compromised.”

Wheeler adds that “if your airframe is connected to your organization’s internal network or intranet and there are no cyber protocols or strategies in place, passengers are as vulnerable on the aircraft as if they were sitting in a coffee shop. Altitude does not make data exchange secure. If the internet is visible to the aircraft, then the aircraft data is visible to the internet. Aviation cybersecurity is like terrestrial cyber security in that it operates via an extensive supply chain network and as such airports, FBOs, trip planners, fuel management systems, caterers etc. can all affect cyber vigilance.”

Satcom Direct EIS training gives crew, flight department and ops team essential understanding of onboard connectivity systems. (Photo: Satcom Direct)

Preventing Aviation Cyberattacks

To minimize the risks of aviation cyberattacks, aviation companies are taking appropriate measures. National Business Aviation Association’s (NBAA) Security Council recommends that operators take the following steps to help protect their companies:

Assess the level of risk for the aircraft and mobile devices based on location and operation
Develop formal policies regarding the use, storage and sharing of flight department data that mitigate the risks of hacking or corruption
Establish best practices for device usage, especially away from the home network (i.e. international travel, etc.)
Protect aircraft identification information by prohibiting public distribution of aircraft photos, registration information and other identifying features
Publish social media usage and network policies that mitigate the risk of sensitive data leaking from the organization

Organizations and operators must actively educate their staff, suppliers and passengers about what can be done to reduce a cyber event. Training and education are essential. Satcom Direct runs cyber awareness courses constantly updated for aviation IT professionals, crew and passengers. Its Aviation CyberThreat Awareness course is designed specifically for business aviation professionals, owners and operators. The program navigates the complexities of security and cyber threat prevention from an aviation perspective.

“Identifying common hacking techniques, attack methodology and current cybersecurity concerns within aviation supports building awareness about inherent vulnerabilities,” Wheeler says. “Modules relating to data protection during international travel are complemented by information pertaining to the use of personal digital devices before, during and after a flight. [We offer] three levels of service to support cybersecurity mitigation.” Its SD Private Network transforms the aircraft cabin into a secure corporate workspace, effectively making the aircraft as secure as an office while also giving visibility to a network to which typically corporate IT had no access.

One of Cyviation’s main goals is to educate both the public and aviation professionals about the importance of cybersecurity. “We believe that cyber attacks on aircraft are a matter of when, not if, and we must be prepared for such events,” Arad says. “Continuous education, training and implementation of advanced cybersecurity solutions are crucial to safeguarding aviation from evolving cyber threats.”

“Cybersecurity is a cross-cutting issue and team sport,” Goodfellow says. “Various parts of organizations (both aviation and non-aviation) need to work together to successfully identify, mitigate and respond to cyber threats.”

Josh Wheeler, senior director entry into service & client services at Satcom Direct Inc. (photo: Satcom Direct)

Aviation Cybersecurity Evolution

Aviation cyber attacks didn’t just start overnight, but Goodfellow says, “At first, little attention was paid to cybersecurity in aviation. We started with simple CRC checks and similar mechanisms, mainly to ensure data integrity in the system, without worrying about any threat actors. Beginning in the late 2000s, ICAO began to work on how cybersecurity was going to factor into and potentially impact aeronautical communications systems and equipment. Currently, cybersecurity in ICAO is a very active area of work, involving international organizations, government, industry, academia and other stakeholders who are all working to help develop practical and pragmatic solutions to problems in their respective spaces.”

Cybersecurity is a dynamic sector and Wheeler says the changing practices of malevolent actors partly trigger its evolution. “As the attacks become more sophisticated, the response or proactive protection needs to evolve. It really is a game of cat and mouse, not just for aviation but for all users of technology platforms.”

Recent cyber-attack developments include the increased use of AI technology and machine learning to target victims and evade detection layers. AI-powered phishing/smishing/vishing attacks and deep-fake scams are also on the rise. Simple computer viruses and Trojan horses have transformed into highly sophisticated ransomware, spyware and advanced persistent threats (APTs). Malware is designed to disrupt operations and steal data and funds.

Wheeler says a notable development in the cyber security sphere is the increase in nation/state-sponsored cyberattacks. “Such attacks are carried out for espionage, to sabotage critical infrastructure and can influence geo-political events. With each new development comes an equal and opposite development in terms of cybersecurity. However, the key recommendation is that aviation organizations, stakeholders, and suppliers be cyber vigilant and employ various tools to mitigate the threat. A combination of human understanding, implementation of tech protocols and investment in robust cyber management solutions can help protect aviation assets.”

Aviation Cybersecurity Strategies

A robust aviation cybersecurity strategy combines advanced technology with continuous education and training. Since no solution can be entirely foolproof against cyberattacks, Arad stresses it is essential to maintain a high level of awareness and preparedness. “At Cyviation, we offer a comprehensive suite of products that complement each other, including SkyRay for assessment and mitigation, SkyWiz for training, Sky Beep as a cockpit device, and SkySIEM for event management. These tools, combined with ongoing training, form the backbone of a strong cybersecurity strategy.”

ICAO has developed a cybersecurity strategy that includes seven pillars (www.icao.int/aviationcybersecurity/Pages/Aviation-Cybersecurity-Strategy.aspx) that cover the most important factors in protecting from, recognizing and addressing cyber threats. “People are often the most important defense against cyber threats, which is why there is a dedicated pillar in the strategy on training and awareness,” Goodfellow explains. “Apart from this, good cyber-hygiene—making sure that systems, training and procedures are up to date, etc.—and having staff being cyber-aware are some key best practices.”

Wheeler explains an effective cyberstrategy is driven by cyber awareness, vigilance and education. “Recognizing that the cyber landscape is dynamic and then implementing the right technologies, policies, procedures and controls to implement solid security management systems are vital. Operators need to discuss all these elements with their connectivity provider to reduce risk. The in-flight connectivity must be paired with a robust, secure ground infrastructure that can support secure connectivity solutions. There is no one size fits all and the operator must trust the connectivity provider to tailor the security system according to their needs.”

Wheeler lists the following questions for flight departments/fleet operators/owners to ask:

Do you have a cyber protocol in place if someone asks for it?
Is the company hardware and software updated with patches, security updates, and firmware updates? Do you ask your vendors about their cyber activity?
Are passengers allowed to bring non-corporate/non-qualified digital devices (phones, tablets, etc.) aboard the aircraft?
Is the onboard wireless network encrypted and are scheduled password changes made?

Passwords, Procedures and Protocol

One of the easiest, yet frequently overlooked cybersecurity solutions is having a robust password that is changed regularly. Wheeler says many business aircraft operators fail to implement this option. “Some CEOs and owners just want to get online and connect and passwords are deemed an inconvenience. Alarmingly, many jets are not configured with their own passwords.”

Wheeler cites the following procedures and protocol (most of which simple actions) for protecting against cyberattacks:

Using passwords to protect cabin Wi-Fi is an obvious one. Flight departments can be reluctant to create Wi-Fi passwords due to the perceived inconvenience to passengers, yet the inconvenience of learning a password far outweighs the potential risks. You can even put passwords into a QR code for passengers to scan when they board.
Interestingly password length trumps complexity in terms of strength as it is harder for the decoders to crack a long password, say the first line of a favorite song, than it is to figure out a short password that includes numbers, special characters and letters.
Think before connecting. It is better to switch off auto-connect and actively decide which Wi-Fi networks to connect to if you’re in a public space, an FBO, or MRO. If you’re not sure the Wi-Fi is legitimate, stay on the cellular network.
Make a habit of locking devices and securing them with a password. Don’t use a USB drive unless you know it is yours.
Don’t plug devices into unfamiliar docking stations.
If you travel, use a virtual private network, VPN, for an encrypted connection. This creates another layer of defense when logging on to a hotel or FBO network.
Equally, when traveling to a new country, ask the technology department to confirm if it is high risk in terms of cyber events and if it is, leave data-rich devices at home and use loaner devices.

The Satcom Direct Data Center Attack Map indicates attempted cyber events. (Photo: Satcom Direct)

Encryption

Encryption plays a strong role in cybersecurity, and is vital to ensure the integrity and confidentiality of data within aircraft systems. Goodfellow says encryption is made even more challenging in aviation because of the nature of the avionics that are widely deployed. “High levels of encryption add a computational cost in aeronautical communications that some installed avionics are not able to handle and therefore decisions need to be carefully made on the tradeoffs with respect to achieving the desired level of security with the required level of safety performance for those systems. Encryption plays a key role in digital signatures that the industry relies on for maintenance and configuration control such as ensuring that software parts have not been modified, that LRUs are correctly adopted by the aircraft, and that PDLs are correctly authenticated.”

Many aircraft systems currently lack adequate encryption, exposing them to potential cyber threats. Cyviation can identify vulnerabilities in aircraft systems caused by inadequate encryption and recommend implementing robust encryption protocols and hardening systems to protect against unauthorized access and cyberattacks.

While Satcom Direct links are encrypted by the provider, Wheeler says the encryption ends once the traffic reaches the ground station. “If this ground station is hosted in a country with a high risk for data compromise, passengers may want to consider encrypting data over the entire internet. VPNs can be tricky on an aircraft as most VPNs come at a high data cost.”

Aviation Cybersecurity Regulations and Standards

Earlier this year, the U.S. National Institute of Standards and Technology (NIST) released version 2.0 of its Cybersecurity Framework. These updated guidelines provide a template for the aviation community to follow; it’s a joint effort across several nations, all providing guidance.

Wheeler explains that there are other guidelines in place. “The International Air Transport Association (IATA) has prepared a useful document that explores risks and solutions for aviation, and regulatory frameworks are being created at regional levels. The industry is aware, but we would benefit from further cooperation and knowledge sharing.”

IATA supports industry-wide aviation cybersecurity activities to coordinate and calibrate, through advocacy, standards, services and guidance material development, for the most appropriate level of holistic cybermaturity for the industry. IATA’s Aviation Cybersecurity Strategy is focused on three main principles in support of the airline industry.

Communities of Trust: development of communities of trust among the different stakeholders to tackle complex challenges over aviation cybersecurity and resilience.
Information Exchange, Standards and Recommended Practices: articulation and coordination of different activities and forums in support of better awareness and information exchange as well as the development of standards and recommended practices and guidance material.
Center of Excellence: establishment of strong collaborations for increased knowledge and crosspollination of ideas.

Initially, aviation cybersecurity focused primarily on IT and OT systems on the ground; however, Arad says over the past three years, there has been a noticeable increase in “technical glitches” on aircraft, prompting regulatory bodies to address these threats more rigorously. “New regulations are now being implemented to ensure that potential cyber vulnerabilities are proactively assessed and mitigated, reflecting the evolving nature of cybersecurity in aviation. Both EASA and the FAA have issued new regulations that mandate proactive assessment and mitigation of potential cyber vulnerabilities in aviation. These regulations are designed to ensure that airlines and other aviation stakeholders take necessary steps to protect aircraft and associated systems from cyber threats.”

ICAO is rolling out standards and guidance materials for secured IPS connectivity to the ACD as aircraft communications evolve from OSI to IPS solutions. ICAO is also working on standards for using digital identities to secure navigation augmentation systems such as SBAS to reduce the threat of spoofing, especially when receiving signals from multiple satellite constellations at the same time (DFMC). Goodfellow explains, “Currently ICAO has Annex 17 standard 4.9.1 which is directly applicable to cybersecurity. Other ICAO Annexes (e.g. Annex 10 – Aeronautical Communications) also have cybersecurity-related standards, and ICAO has also developed several guidance documents for cyber-related topics. Other industry associations such as EUROCAE and RTCA have standards such as ED-200 series and DO-326A that are focused on the manufacturing industry.”

In August 2024, the Federal Aviation Administration proposed rulemaking that would impose new design standards to address cybersecurity threats for transport category airplanes, engines and propellers. The intended effect of this proposed action is to standardize the FAA’s criteria for addressing cybersecurity threats, reducing certification costs and time while maintaining the same level of safety provided by current special conditions.

The FAA proposes to add new regulations to and revise certain existing regulations in title 14, Code of Federal Regulations (14 CFR) part 25 (Airworthiness Standards: Transport Category Airplanes), part 33 (Airworthiness Standards: Aircraft Engines), and part 35 (Airworthiness Standards: Propellers). These changes would introduce type certification and continued airworthiness requirements to protect the equipment, systems and networks of transport category airplanes, engines and propellers against intentional unauthorized electronic interactions (IUEI) that could create safety hazards. Design approval applicants would be required to identify, assess and mitigate such hazards, and develop Instructions for Continued Airworthiness (ICA) that would ensure such protections continue in service. Proposed changes to parts 25, 33, and 35 would mandate such protection and apply to applicants for design approval of transport category airplanes, engines and propellers.

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Army Completes Initial Flight Demos, MOSA Evaluation With FTUAS Prototypes – Sept. 11

The Army has completed initial flight demonstrations and Modular Open Systems Approach (MOSA) evaluations with Textron Systems and Griffon Aerospace’s offerings for the Future Tactical UAS (FTUAS) program, the service said on Tuesday.

The update on the latest FTUAS milestones arrives as the two firms continue prototype development ahead of delivering production-representative test systems to the Army and the service’s plans to potentially move into procurement in 2026.

“Each vendor will continue prototype development, incorporate feedback and lessons learned and deliver production representative prototypes for use in future government-led testing at [the Redstone Test Center in Huntsville, Alabama] ultimately informing the Army’s selection for the FTUAS program of record,” the Army said on Tuesday.

The Army in September 2023 selected Textron and Griffon Aerospace to move forward in the prototyping effort to develop an enduring FTUAS capability, and in April awarded the third and fourth contract options for the FTUAS prototyping effort following a critical design review with the two firms’ offerings.

Option 3 is covering flight demonstrations and the MOSA verification testing, while Option 4 will include delivery of production representative prototypes for further testing and operational demonstrations that will culminate in a production readiness review.

Textron is offering its Aerosonde Mk. 4.8 Hybrid Quad UAS and Griffon Aerospace is pitching its Valiant drone platform for the FTUAS program.

The Army has said FTUAS aims to replace the legacy Shadow drone, also built by Textron, with a “vertical takeoff and landing (VTOL), runway-independent, reduced acoustic signature aircraft that can be transported organically while providing commanders with ‘on the move’ reconnaissance, surveillance, and target acquisition capabilities.

The MOSA conformance evaluations occurred in May, the Army said, and involved replacing each the mission computers on each vendors’ prototypes with a third-party surrogate mission computer and a mix of third-party and vendor software.

“Swapping the hardware and software allowed an independent assessor to measure the openness and modularity of the prototype systems to determine the extent to which MOSA objectives were satisfied. This MOSA conformance verification demonstrated early implementation of and alignment with required MOSA functional boundaries and will serve as a model for follow-on MOSA evaluations,” the Army said. FTUAS’ [MOSA] approach allows the system to keep pace with technology through rapid capability insertion.”

The flight demonstrations at the Redstone Test Center occurred after the MOSA verification event, with Texton and Griffin Aerospace conducting multiple flights to demonstrate their offerings’ capabilities for Vertical Takeoff and Landing (VTOL), reduced acoustic signature, on-the-move command and control, rapid emplacement, system integration and flight performance, the Army noted.

Brig. Gen. David Phillips, the Army’s program executive officer for aviation, told reporters in April the Army’s FTUAS prototyping effort will inform its push to “aggressively” get after procurement plans, potentially looking at 2026 to begin buying the new drone systems.

“We’re still in competition there, but we’ll have both those aircraft built and we’ll have them out in the field here getting tested later this year is what we anticipate. We’ll get that feedback in, incorporate it into any final design updates or test updates and then move forward with the program starting out in ‘26 with procurement. We’re posturing ourselves appropriately there to aggressively get after procurement with the resources that we’re provided,” Phillips said at the time.

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Boeing Commercial Airplanes Workers On Strike After Union Members Reject Contract Offer – Sept. 13

More than 30,000 Boeing employees began a strike on Sept. 13 at the company’s Commercial Airplanes’ facilities in the Pacific Northwest after union members voted overwhelmingly last Thursday to reject the company’s contract offer.

Nearly 95 percent of International Association of Machinists and Aerospace Workers District 751 and District 24 members voted against the four-year contract, and 96 percent voted to strike. Boeing’s previous contract with the union expired last Thursday, Sept. 12.

The company said the next step is to resume contract negotiations.

Some of the work done by Boeing Commercial Airplanes in Seattle includes derivatives of commercial aircraft for the Navy’s P-8 Poseidon anti-submarine warfare aircraft and the Air Force’s KC-46A aerial refueling tanker.

Jefferies aerospace and defense analyst Sheila Kahyaoglu said in a client note Sept. 13 that in 2008, which is the most recent strike by union members in the Pacific Northwest, Boeing delayed delivery of more than 100 aircraft, and took hits of $1.2 billion to net income and $2.5 billion to free cash flow. That strike lasted 58 days.

IAM 751 and W24 members rejected a contract offer, which their leadership had recommended, that would have provided a 25 percent general wage hike over the four years, added retirement benefits, and lowered healthcare costs. Some union members have lobbied for a 40 percent wage increase.

A version of this story originally appeared in affiliate publication Defense Daily.

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Starlink Lands United Deal for the Airline’s Full Fleet – Sept. 13

United Airlines tapped Starlink as its in-flight connectivity (IFC) provider, announcing a deal on Friday to equip the airline’s entire fleet with Starlink and offer the service to passengers for free.

United said this deal covers all aircraft, both mainline and regional, which is more than 1,000 planes. Installation will take place over the next several years. Testing begins in early 2025 with the first passenger flights expected later that year.

United currently has four Wi-Fi providers, and works with Gogo (now part of Intelsat), Panasonic, Thales, and Viasat on different planes and routes.

“Everything you can do on the ground, you’ll soon be able to do onboard a United plane at 35,000 feet, just about anywhere in the world,” said United CEO Scott Kirby. “This connectivity opens the door for an even better inflight entertainment experience, in every seatback – more content, that’s more personalized. United’s culture of innovation is, once again, delivering big for our customers.”

This is the largest airline to go with Starlink’s service. Starlink has also signed deals with Qatar Airways, Hawaiian Airlines, Latvian airline airBaltic, Japan’s Zipair, and charter operator JSX.

United Passengers can use Starlink connectivity on their personal devices and seatback screens. United said that it has nearly 100,000 seatback screens and plans to grow these numbers with new airplanes and retrofits. The Starlink service via the Low-Earth Orbit (LEO) satellite constellation will support applications like live streaming, working in cloud applications, gaming, and support with the United app.

“We’re excited to team up with United Airlines to transform the inflight experience,” said Gwynne Shotwell, president and COO of SpaceX. “With Starlink onboard your United flight, you’ll have access to the world’s most advanced high-speed internet from gate to gate, and all the miles in between.”

United follows Delta in making IFC service free for customers. Delta is working with Viasat and Hughes Network Systems for satellite connectivity.

A version of this story originally appeared in affiliate publication Via Satellite.

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Piasecki Aircraft Achieves Historic Milestone With First Flight of Aerial Reconfigurable Embedded System (ARES) Tilt-Duct VTOL Vehicle – Sept. 10

ESSINGTON, Pa., September 10, 2024 (Newswire.com) – In an aviation milestone, Piasecki Aircraft Corporation (PiAC) successfully conducted the first flight of its innovative proof of concept tilt-duct Aerial Reconfigurable Embedded System Demonstration Vehicle (ARES-DV), marking a significant leap forward in vertical take-off and landing (VTOL) technology. The flight event, which consisted of two tethered hover flights, is the first step in a program to demonstrate the potential of ARES to revolutionize autonomous airborne casualty evacuation (CASEVAC), cargo resupply, and provide other multi-mission capabilities in support of small distributed combat units. This flight represents a commencement milestone in Piasecki’s experimental flight test program sponsored by the U.S. Air Force and Army under a $37 million Strategic Funding Initiative (STRATFI).

ARES is a modular multi-mission tilt-duct VTOL vehicle that can be operated as an unmanned aerial system (UAS) or with an optional manned flight module. ARES is designed with a small landing footprint to enable shipboard and expeditionary operations as well as provide embedded multi-mission C4I, ISR, combat, and logistics support to small, distributed combat forces operating over extended distances and in complex terrain. Rapidly reconfigurable Mission Payload Modules are supported by a common Flight Module to deliver multi-mission flexibility with significantly reduced overall logistics footprint and cost.

The ARES-DV Flight Module lifted off from Piasecki’s West Helipad in Essington, Pennsylvania, on Friday, September 6, and achieved a sustained hover for a duration of approximately one minute before descending. Upon landing, the team attached the U.S. Army’s Mobile Multiple Mission Module (M4) to the ARES-DV Flight Module, and conducted a second successful one-minute hover, demonstrating the ability of its triplex fly-by-wire flight control system to sustain a stable hover in multiple configurations and a dynamic ground environment.

“Since its origins as a DARPA conceptual design project, Piasecki has led ARES through years of research and development — design iterations, rigorous component testing, system level validation, and more — to mature the technology leading up to today’s landmark achievement. ARES represents another significant milestone in Piasecki’s 80-year history of bringing innovation to flight,” said John Piasecki, CEO of Piasecki Aircraft. “I’d like to thank our Air Force and Army customers as well as our dedicated employees and partners for their continued support as we move forward with the next phases of development. After successfully expanding the aircraft’s flight envelope, we will implement modifications to enable flight demonstration of a fully autonomous CASEVAC and logistics resupply capability. Successful flight demonstration of the ARES proof of concept demonstrator significantly reduces risk and accelerates the development timeline for a family of operational tilt-duct configurations for multi-mission VTOL UAS and high-speed VTOL applications.”

“ARES creates a new baseline for VTOL technology applied to heavy-payload, time-critical logistics crucial for dispersed operations,” said Barth Shenk, Program Manager at Air Force Research Laboratory.

ARES features Honeywell Aerospace’s Compact Fly-By-Wire system, an integrated flight control system that is both lightweight and robust. Designed to fit into the limited space available on smaller aircraft, this state-of-the-art system provides safety-critical flight control capabilities typically found in much larger airliners and advanced fighter aircraft. It enables precise handling and stability across a wide range of flight conditions, thereby enhancing safety and performance — and is especially advantageous for VTOLs, where space is at a premium and weight efficiency is paramount.

“The application of Honeywell’s Compact Fly By Wire in the ARES-DV not only showcases the ability of this technology to support a future multi-mission VTOL aircraft but also the great cooperation between Honeywell and Piasecki in a fast-moving program,” said Dave Shilliday, VP & GM, Advanced Air Mobility, Honeywell Aerospace Technologies.

The hover test flight was funded by an Army SBIR Sequential Phase II contract and by an Air Force TACFI Sequential SBIR II award. In November 2023, Piasecki announced that it was awarded a $37 million multi-year contract by AFWERX, the Air Force’s innovation arm, in conjunction with the Air Force Research Laboratory (AFRL) and Army Medical Research and Development Command (MRDC), as part of its Strategic Funding Increase (STRATFI) program to accelerate ARES development and flight testing, among other advanced VTOL enabling technologies.

“We are deeply grateful to all our supporters, especially the visionary leadership and commitment of AFRL and TATRC,” Piasecki added.

The post Piasecki Aircraft Achieves Historic Milestone With First Flight of Aerial Reconfigurable Embedded System (ARES) Tilt-Duct VTOL Vehicle – Sept. 10 appeared first on Avionics International.

USAF Building New Site for Testing B-2 Flight Component RCS and Antenna Calibration

By September next year, the U.S. Air Force is to establish a new Composite Aircraft Antenna Calibration Facility (CAACF) at Hill AFB, Utah for testing flight components’ radar cross section (RCS) and antenna calibration of the Northrop Grumman B-2 bomber.

The 309th Maintenance Support Group at Ogden Air Logistics Complex is adapting the Resonant Adaptive Zonal Radar (RAZR) to test B-2 RCS at Ogden, while the Air Force builds CAACF.

Resonant Sciences, a small business in Beavercreek, Ohio outside Dayton, builds RAZR–a robotic monitor that depot and field mechanics use after a B-2 mission to inspect the aircraft’s composite material to pinpoint areas that need repair.

RAZR has been among B-2 program efforts that have saved 15,000 maintenance man hours per year, Scott Carlson, Air Force Life Cycle Management Center’s deputy system program officer for the B-2, said in July.

In the last two years, the Air Force has funded seven RAZRs.

“The CAACF will be a dual use facility for RCS testing of B-2 flight control components and for calibrating composite aircraft antennas,” according to a Wednesday business notice. “Hill AFB procured the RAZR to be used with the B-2 composite flight control surfaces RCS testing. This SOW [statement of work] pertains to the new RCS system to be used for the B-2 RCS testing.”

The B-2 program has said that it wants to reduce low-observable (LO) maintenance costs and time, which reduced the stealth bomber’s mission capable rate to 56 percent last year (Defense Daily, Aug. 2). The LO effort comes under the B-2’s Low Observable Signature and Supportable Modifications (LOSSM) relatively scant funding line. In fiscal 2025, the Air Force requested $1 million for LOSSM, which the service said “supports the B-2 ability to penetrate anti-access combat environments, performing missions directed by the National Command Authority while ensuring aircrew survivability.”

A version of this story originally appeared in affiliate publication Defense Daily.

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