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US Air Force to Upgrade C-5M Super Galaxy Cockpit Controls and Displays

The largest cargo aircraft in the United States Air Force will undergo an avionics modernization program, including a high-resolution, large area cockpit display system from Intellisense. (Photo courtesy of Intellisense)

The U.S. Air Force is upgrading its fleet of C-5M Super Galaxy Transport aircraft with new cockpit displays under a recently announced contract with Intellisense Systems, a Torrance, California-based supplier of aircraft sensing and display electronics.

According to a June 7 announcement from Intellisense, the contract will provide “Replacement Multi-Function Controls and Displays” (RMCD) for the military cargo transport planes. Intellisense will replace the C-5M’s existing displays with an upgraded version of the video display terminal or VDT-1209s that is currently in operation on the MC-130J.

Some of the details on the upgrade released by Intellisense confirm that the upgrade will be enabled by the PU-3000 multicore avionics computer first introduced by CMC Electronics last year. This selection of the PU-3000 comes a year after it became the industry’s first avionics computer to use multicore processors certified to design assurance level (DAL) A, the highest level of assurance requirements imposed by civil aviation authorities for safety critical aircraft hardware and software.

The video display terminal, VDT-1209, developed by Intellisense, will replace the existing displays on the C-5M fleet. (Photo courtesy of Intellisense)

The existing C-5M cockpit configuration includes six multi-function smart displays that provide the pilot, copilot, and flight engineers with primary flight and navigation information, according to Intellisense. All six displays will be replaced with the company’s large-format 15-inch display and three separate GPU line-replaceable units (LRUs).

There are currently 52 total C-5Ms in operation by the Air Force. At a length of 143 feet and 9 inches, and maximum takeoff weight of 840,000 pounds, it is the third largest aircraft in the world and the largest in the Air Force inventory.

Airmen assigned to the 22nd Airlift Squadron from Travis AFB, Calif., offload 120,000 pounds of cargo from a C-5M Super Galaxy on April 1 at Joint Base Pearl Harbor-Hickam, Hawaii. (Photo courtesy of U.S. Air Force)

Lockheed Martin first started delivering the C-5M to the Air Force in 1970, and the aircraft has undergone several avionics refresh programs over its 50-year lifespan. The most recent one includes development work that first began in 2014, and continued into the 2020s, with the Air Force’s fiscal 2021 budget request including $50 million dedicated to communication, navigation, and surveillance/air traffic management (CNS/ATM) upgrades, according to previous reporting from Defense Daily, a sister publication to Avionics International.

Jack McParlane, director of business development in Intellisense’s airborne systems department, in a statement, called the C-5M RMCD win “an important step” for the company. “Not only will we be providing a Primary Flight Display for an essential USAF aircraft, but we will also be integrating and delivering the full C-5M cockpit display system, including state-of-the-art, multicore avionics computers from CMC Electronics,” he said. “The program scope further demonstrates our ability to address flight-critical avionics beyond just displays.”

The post US Air Force to Upgrade C-5M Super Galaxy Cockpit Controls and Displays appeared first on Aviation Today.

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Inmarsat Tests Signals for United Kingdom Positioning, Navigation and Timing System

A computer-generated rendering of the Inmarsat-3 spacecraft. (Photo, courtesy of Inmarsat)

A team of U.K. companies led by Inmarsat has broadcast a satellite navigation signal in a project to explore a United Kingdom sovereign positioning, navigation and timing (PNT) system. Inmarsat announced Wednesday the signal is stable and operational, enabling on-going testing and validation by industry, regulators, and users.

The United Kingdom is no longer part of Europe’s Galileo satellite navigation system after leaving the European Union, and cannot use the European Geostationary Navigation Overlay Service (EGNOS) safety of life services, which provide GPS for airport approach and landing operations for aircraft.

Inmarsat is testing a potential sovereign solution, the UK Space Based Augmentation System (UKSBAS), with British partners Goonhilly Earth Station Limited and GMVNSL Limited. UKSBAS repurposes the SBAS transponder on Inmarsat’s I-3 F5 satellite located at 54 degrees West. Inmarsat announced the project in December 2021.

Inmarsat said UKBAS is designated to provide more precise navigation for maritime and aviation users in U.K. waters and airspace, increasing accuracy in positioning to a few centimeters of accuracy rather than the few meters provided by standard GPS.

Nick Shave, vice president of Strategic Programmes for Inmarsat Global Government said the program allows Inmarsat to extend the live of its I-3 F5 satellite, two decades after its launch.

“We look forward to exploring the potential for this project and the benefits it could deliver to the U.K. with more precise, high-integrity, resilient navigation services, whilst also exploring future capabilities on new satellites through Inmarsat’s fully funded technology roadmap. This work also has the potential to be exported to other nations around the world, benefitting the U.K. economically as well as technologically,” Shave said.

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

The post Inmarsat Tests Signals for United Kingdom Positioning, Navigation and Timing System appeared first on Aviation Today.

Raytheon Technologies Moving Global Headquarters To Northern Virginia

Raytheon Technologies on Tuesday, June 7, announced that it will establish its global headquarters in Arlington, Virginia. (Photo, courtesy of Raytheon Technologies)

Raytheon Technologies on Tuesday said it will establish its global headquarters in Northern Virginia, close to many of its government customers in the Washington, D.C., area, a move that follows Boeing’s decision a month ago to relocate its corporate headquarters to the region.

Raytheon said it will be moving to Rosslyn, an area of Arlington Virginia across the Potomac River from Washington and the same neighborhood as its Intelligence & Space operating segment. The company is currently headquartered in Waltham, Mass., near Boston. Collins Aerospace, Pratt & Whitney, Raytheon Intelligence & Space and Raytheon Missiles & Defense are the four individual business units overseen by Raytheon Technologies Corporation, according to the company’s website.

“The location increases agility in supporting U.S. government and commercial aerospace customers and serves to reinforce partnerships that will progress innovative technologies to advance the industry,” Raytheon said. “Washington, D.C., serves as a convenient travel hub for the company’s global customers and employees.”

Boeing in early May said it would be moving its headquarters from Chicago to Arlington, where its defense business is based. Boeing also said it would create a research and technology hub as well in the Washington area.

General Dynamics and Northrop Grumman are also based in Northern Virginia and Lockheed Martin is headquartered in Bethesda, Md., adjacent to the beltway around Washington. These three companies combined with Boeing and Raytheon make up the five largest U.S. defense contractors.

Raytheon said that it already employs about 130 corporate staff in Rosslyn and doesn’t expect personnel there to increase significantly with the establishment of the new global headquarters. The company will slightly increase its leased space in Rosslyn.

Raytheon has a substantial operational presence in Massachusetts and will maintain its presence in the state and in Waltham. The company said the new global headquarters won’t impact its employee totals in Massachusetts or Virginia.

In the internet era, combined with the workforce shocks of the COVID-19 pandemic, many private and public sector employees and leaders have shifted to a hybrid work model that includes home and traditional offices, and some employees are fully remote, with less frequent office visits.

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.>>

The post Raytheon Technologies Moving Global Headquarters To Northern Virginia appeared first on Aviation Today.

CoreAVI, DDC-I Target Development of Next Generation Avionics Apps with New RTOS Graphics Platform

(Photo: CoreAVI)

Phoenix, Arizona-based operating systems and software supplier DDC-I, Inc. and CoreAVI, the Tampa, Florida-based provider of safety critical computing, have partnered to introduce a new integrated avionics real-time operating system (RTOS) graphics platform that could accelerate the development of compute and graphics-intensive avionics applications, according to an announcement made by the two companies last month.

The two companies have confirmed that the partnership will target the development of a new integrated avionics RTOS/graphics platform for “high-performance multicore SoCs equipped with on-board graphical processing units (GPUs), including the NXP i.MX 8 and 11th Generation Intel Core i7 (formerly Tiger Lake).” Some of the specific avionics applications that could see accelerated development resulting from the new platform include those requiring data fusion, sense/detect, synthetic vision, graphics, and other advanced control functionality.

By combining DDC-I’s Deos RTOS with CoreAVI’s Vulkan-based VkCoreSC graphics and compute driver portfolio, the partnership combines technologies that both companies have continued to win new avionics embedded development contract awards for in recent years. As an example, Deos was also confirmed by DDC-I to provide RTOS hosting for Honeywell Aerospace’s Anthem cloud-native cockpit system.

First certified to Design Assurance Level (DAL) A in the late 1990s, the Deos RTOS has been used to host DO-178 certifiable avionics software including functions such as air data computers, air data inertial reference units, cockpit video, displays and flight instrumentation, radios, traffic collision avoidance systems, and weather radar, among other systems.

CoreAVI’s Vulkan-based VkCoreSC graphics and compute driver portfolio is based on a subset of Khronos’ Vulkan application programmable interface (API) open standard, and supports applications aligned to DO-178C DAL A. Vulkan can allow itself to receive either graphics or compute commands and allocate them to the correct execution unit in the graphics processing unit (GPU), and then render the result on the display.

Furthermore, the graphics and compute driver portfolio enable avionics developers to implement a full software stack on NXP’s i.MX8 and Intel’s 11th Gen Core i7 application processors.

A block diagram of NXP’s i.MX 8 processor (Photo: NXP)

Neil Stroud, VP of Marketing and Business Development at CoreAVI, commented on the new partnership with DDC-I, noting that avionics developers “targeting emerging SoCs like the i.MX8 and Intel’s 11th Gen Core i7 now have a versatile, high-performance GPU acceleration platform to develop highly converged mission and avionics processing solutions with an accelerated, low risk path to flight safety certification.”

DDC-I and CoreAVI provided a combined set of emailed statements to Avionics International in response to questions about the new partnership, including an explanation of why emerging SoCs like the i.MX8 and Intel’s 11th Gen Core i7 are ideal for developing new graphics-intensive avionics display applications.

“The avionics industry is driven to emerging SoCs such as NXP’s i.MX 8 or Intel’s 11th Gen Core i7 as these SoCs consolidate functions into smaller pieces of silicon for the A&D space. They combine the best of small form factor, performance levels, and power consumption, which allows integrators to use state-of-the-art technology while maintaining strict [size, weight, and power] SWaP requirements,” the representatives said. Printed circuit board (PCB) and system level space is also reduced when SoCs are used due to fewer and higher-density components, according to the two companies.

The new DDC-I and CoreAVI integrated RTOS graphics computing platform could help accelerate the development of graphics-intensive avionics applications, the two companies say. (Photo: CoreAVI)

Further, aside from SWaP optimization, SoCs provide a standardization of processor, I/O, and interconnect targeted for application-specific embedded applications.

“This reduces the level of customization required and level of engineering effort needed to employ an SoC in an avionics system. That is, the hardware and software engineering effort and time to deploy these SoCs is generally lower than to do the same with multiple discrete IC components,” the representatives said. “This cost savings continues through to procurement and manufacturing where consolidating functions onto a single chip reduces the number of components purchased (generally at a lower cost for the SoC and compared to purchasing than multiple discrete ICs) and put into assembly (manufacturing overhead) of the avionics system.”

While neither DDC-I or CoreAVI were able to confirm any specific companies or avionics OEMS they’re providing the new platform for, they did provide a list of the types of companies they believe it could be ideal for.

These include avionics companies developing display or artificial intelligence-based systems. Systems they create include more advanced display and user interfaces, high compute applications such as “sense and avoid,” or AI-based systems determining flight management or various AI military applications, according to the two companies.

The post CoreAVI, DDC-I Target Development of Next Generation Avionics Apps with New RTOS Graphics Platform appeared first on Aviation Today.

Electra Acquires Airflow, Consolidates eSTOL Development

Electra has acquired Airflow, and the combined teams are consolidating efforts to develop an electric short take-off and landing (eSTOL) aircraft. (Photo courtesy of Electra)

In an announcement this week, Electra.aero shared news of its acquisition of the company Airflow. Both companies have developed electric short take-off and landing (eSTOL) aircraft, and Airflow’s eSTOL business will now be consolidated into the Electra brand. Marc Ausman, co-founder and CEO of Airflow—now Chief Product Officer of Electra—believes that working together with Electra will be a much stronger approach for bringing their eSTOL aircraft to market. “We are combining the best of both worlds,” he told Avionics International in an interview, “taking the best of what each company has learned.” The most immediate objective for Electra is to fly a technology demonstrator within the next 12 months.

The teams from both Electra and Airflow had prior experience in developing electric aircraft and working for major aircraft OEMs. Based on that experience, Ausman explained, each company had independently determined that an eSTOL model was the optimal method for bringing electric propulsion to market.

The Electra brand now includes the teams from both Airflow and Electra, and an even larger combined order book—with letters of interest for about 800 aircraft, said Ausman. “Many of the folks from Airflow fill in gaps in the team at Electra,” and vice versa, he added.

Airflow’s existing partnerships offer potential opportunities for growth to Electra. In October 2021, Airflow began partnering with Plug Power, a leading hydrogen fuel cell company. In what Ausman describes as a long-term partnership, the collaborators “are actively developing the technology to bring hydrogen fuel cells and other hydrogen technology to smaller Part 23 aircraft. That helps move us towards our ultimate goal of sustainability.” A key point of consideration in this partnership is determining what the entire product family will look like in the future, he noted.

“We’re really thinking about ways that the aircraft can be used outside of traditional runways.” – Marc Ausman, Chief Product Officer of Electra (Photo courtesy of Airflow)

Another potential area for growth for Electra is moving to an adjacent market, such as the seaplane market. The eSTOL model is well-suited for this specific market, Ausman said. “We’re really thinking about ways that the aircraft can be used outside of traditional runways. We think we can grow significantly [in the seaplane market] and help our customers grow,” he explained.

At the end of last year, Airflow entered into a partnership with Tailwind Air to explore development of an amphibious seaplane powered by distributed electric propulsion. Tailwind’s current fleet, offering a scheduled seaplane service from New York to Boston Harbor, is currently made up of Cessna Caravan amphibious seaplanes.

Another one of Airflow’s existing partnerships is with the company Pipistrel, an electric airplane manufacturer. Pipistrel agreed to supply motors, motor controllers, and batteries for Airflow’s proof-of-concept aircraft, which was intended to be a modified version of an existing fixed-wing design.

Ausman told Avionics that the first launch will be a hybrid electric aircraft. The next generation will be hydrogen electric, “then ultimately, when batteries are good enough, we’ll have a pure battery electric aircraft.” Unless there are any major breakthroughs in the technology, he views battery development as a path of incremental improvements.

The eSTOL model itself will combine aspects from both Airflow’s and Electra’s development programs. Each company found success with certain types of customers, resulting in an order book that is very complementary, Ausman commented. The new Electra team will develop an aircraft with “the broadest market appeal for regional air mobility and urban air mobility.”

Electra hopes to fly a technology demonstrator as soon as possible—in the upcoming year, Ausman shared. Following that, they will work on the pre-production prototype aircraft. Both teams had very similar milestones in mind as they developed their eSTOL aircraft, he added, saying, “We’re combining efforts in terms of what we’ve learned and what customer needs are moving forward—to [achieve] those milestones and be able to fly as soon as we can.”

Electra announced an investment from Lockheed Martin at the beginning of this year to support Electra’s goal of flying a technology demonstrator. In February, the U.S. Air Force awarded Electra a Phase III Small Business Innovation Research (SBIR) contract as part of the Agility Prime program, following a $1.5 million investment from the USAF in 2021. In March of this year, the USAF also awarded Electra a Small Business Technology Transfer (STTR) Phase II contract in which Electra will collaborate with the Massachusetts Institute of Technology (MIT) for developing flight control systems to integrate into its eSTOL aircraft.

The post Electra Acquires Airflow, Consolidates eSTOL Development appeared first on Aviation Today.

How Much Value Does In-Flight Connectivity Offer Ultra Low-Cost Carriers?

Colton Snow of Sun Country Airlines shared his thoughts on the value of in-flight connectivity for their airline’s customer base. “Lots of folks travel other airlines for business and expect connectivity,” said Snow. (Photo courtesy of Sun Country)

In-flight connectivity (IFC) topics were a central point of focus during last week’s Connected Aviation Intelligence (CAI) Summit, held in Reston, Virginia. Representatives from Air Canada, Panasonic Avionics, Intelsat Corp, and Stellar Blu Solutions discussed the value of satellite technology for in-flight entertainment (IFE) offerings. Another panel including representatives from Breeze Airways, El Al Airlines, and ST Engineering iDirect featured next-generation strategies for increasing bandwidth to support in-flight connectivity (IFC).

On the final day of the CAI Summit, Colton Snow, Vice President of Product and eCommerce for Sun Country Airlines, delivered the keynote presentation regarding the airline’s current un-connected in-flight passenger experience strategy. There are multiple use cases for IFC, Snow conceded, such as enabling connectivity for the cabin crew to increase aircraft safety and reliability, or for processing on-board transactions and eliminating issues with declined payment methods. However, he said, none of these are compelling enough at this point to drive an investment from Sun Country into the technology.

“In the long-term, there are catalysts that will move us to in-flight connectivity,” Snow explained. One of these is a change in customer expectations. Fewer than 0.5% of passengers from Sun Country mention Wi-Fi in their feedback submitted through surveys. At some point in the future, once more customers include access to IFC in their decision-making criteria, it would justify an investment into the technology.

Colton Snow, Vice President of Product and eCommerce for Sun Country Airlines, delivered the keynote presentation at the CAI Summit on Friday, June 3.

A significant portion of the customer base for Sun Country Airlines is leisure travelers; 97% of the markets served are seasonal. Popular destinations include Aruba, Honolulu, Turks & Caicos, and St. Thomas. For leisure customers, Snow stated, streaming and entertainment cover the bases for their in-flight experience. The target customer demographics for the airline are 46- to 51-year-olds, married, and earning a household income of $97,000 to $107,000. “These customers ultimately care about getting value,” he said. They value low fares and a good in-flight experience. As an ultra low-cost carrier (ULCC), Sun Country has to maintain low costs to ensure low fares. Snow explained, “This creates a high bar for capital intensive investments in the onboard experience, like in-flight connectivity, that may not have a tangible or direct ROI that we can manage or own.”

To compete with other ULCCs such as Allegiant and Frontier, Sun Country aims to balance low fares with a positive in-flight experience by offering a free beverage service, in-seat power, and free streaming of IFE content to passengers’ personal devices. The company had three choices in their approach to IFC and IFE, Snow explained: do nothing, offer streaming of IFE, or offer both IFE and internet access. For leisure travelers that are visiting friends or going on vacation, having Wi-Fi on board does not offer as much value as the option to watch TV or movies while in flight. “Lots of folks travel other airlines for business and expect connectivity,” he added.

“We experimented with in-flight tablets but found they required more maintenance, and most folks prefer to bring their own tech onboard like smartphones, tablets, or laptops,” Brian Davis, chief marketing officer for Sun Country, told Avionics in an emailed statement last year.

The cost of offering in-flight connectivity is also major point of consideration for the airline. With such a strong focus on low fares, the cost passed on to customers for IFC must be minimal. “We would really have to go forward with a strategy where it was baked into the cost of the fare,” Snow remarked in his keynote presentation.

The post How Much Value Does In-Flight Connectivity Offer Ultra Low-Cost Carriers? appeared first on Aviation Today.

PODCAST: NSR’s Brad Grady Talks Market Outlook for In-flight Satellite Connectivity Services

Brad Grady, Research Director for Northern Sky Research, is the guest on this episode.

On this episode of the Connected Aviation Intelligence Podcast, we provide a replay of the live presentation given by Brad Grady, Research Director for Northern Sky Research, during the 2022 Connected Aviation Intelligence Summit.

Grady covers a range of different topics from the potential of Low Earth Orbit (LEO) satellite networks to disrupt the IFC market to airline business models, the impact of the increase in business jet operations and more.

Have suggestions or topics we should focus on in the next episode? Email the host, Woodrow Bellamy, at wbellamy@accessintel.com, or drop him a line on Twitter @WbellamyIIIAC.

Listen to this episode below, or check it out on iTunes or Google Play. If you like the show, subscribe on your favorite podcast app to get new episodes as soon as they’re released.

The post PODCAST: NSR’s Brad Grady Talks Market Outlook for In-flight Satellite Connectivity Services appeared first on Aviation Today.

Volocopter’s Third eVTOL Prototype VoloConnect Makes Its First Flight

Volocopter’s four-seater, fixed-wing eVTOL aircraft completed its first flight in May, the company announced this week. (Photo courtesy of Volocopter)

German urban air mobility company Volocopter just announced that the four-seater VoloConnect aircraft completed its first flight in May. The VoloConnect, an electric fixed-wing passenger aircraft capable of vertical take-off and landing, could enter into service as early as 2026. Volocopter has two other electric vertical take-off and landing (eVTOL) designs—the VoloCity, designed for urban air mobility (UAM) applications, and the VoloDrone, an uncrewed utility drone.

Volocopter’s team plans to continue increasing the flight envelope as they carry out more tests. To gradually test the aircraft’s limits, according to a source from Volocopter, they will increase flight speeds and durations as well as failure cases.

The VoloConnect will offer customers flights of 60+ miles. As battery density increases, the aircraft’s range will automatically increase as well. “The 60-mile range is based on the battery cell density that can be purchased off-the shelf today for aviation applications,” according to the source.

The VoloCity model has been undergoing extensive flight testing since the end of 2021, and according to a spokesperson from the company, they are quickly progressing towards type certification. The team’s objective is to launch at the Paris Olympics in 2024 and begin offering the first commercial routes at that time. “We are working on receiving our type certification from EASA,” the spokesperson shared, “and we have been working with EASA since 2017.” The two-seater VoloCity eVTOL aircraft is designed specifically for short inter-city flights, with a range of about 22 miles.

The VoloConnect, pictured above in take-off, has a target launch date of 2026. (Photo courtesy of Volocopter)

Volocopter has already received two out of four major certifications that are necessary to begin commercial services—the Design Organization Approval and Production Organization Approval. The company has also entered into agreements with Paris, Rome, NEOM, and Singapore to launch air taxi and other UAM services. The joint venture with NEOM includes plans to develop a “smart city” to host the world’s first customized public vertical mobility system. The enterprise NEOM has placed an order for 10 VoloCity passenger eVTOL aircraft and 5 VoloDrones to incorporate into this planned city.

Volocopter’s heavy-lift drone model, the VoloDrone, performed its first public flight in October 2021 in Hamburg. The drone was first unveiled in 2019 along with the company’s vertiport concept, called the VoloPort. Volocopter continues to identify use cases for the VoloDrone and partner for collaboration, said the company’s representative. In looking for partnerships, the source shared, they intend to focus only on areas where they can add value.

“What’s impressive with this announcement [about the first flight of the VoloConnect] is the turnaround time. It’s been 17 months from inception to flight,” the company’s spokesperson remarked to Avionics this week. “We’re also the only eVTOL developer that has different aircraft designs—we’re really focusing on the ecosystem.”

The post Volocopter’s Third eVTOL Prototype VoloConnect Makes Its First Flight appeared first on Aviation Today.

Joby’s Avionyx Acquisition to Support eVTOL Software Testing and Verification Needs

Avionyx, an aerospace software engineering firm, has been acquired by Joby Aviation to support development of Joby’s electric vertical take-off and landing (eVTOL) aircraft. (Photo courtesy of Joby)

California-based Joby Aviation, an electric vertical take-off and landing (eVTOL) developer, recently acquired an aerospace software engineering firm called Avionyx. This acquisition will support Joby’s aircraft type certification program.

The two companies first collaborated in 2021 when Joby awarded Avionyx a contract for software testing and verification of the systems onboard their eVTOL aircraft. “Avionyx has been assisting us with software verification activities across a variety of aircraft systems,” a representative from Joby shared with Avionics. The Federal Aviation Administration’s regulations for flight software require extensive review, analysis, and testing of the onboard systems.

Joby completed its first FAA Compliance Review at the end of 2021 after undergoing evaluations of its approach to developing and verifying its software and airborne electronic hardware. In the coming months, the representative shared, “we’ll continue to use our Vehicle Software Integration Lab (VSIL) at our facility in Marina, CA, where we leverage flight simulation and hardware emulation capabilities to rapidly conduct thousands of pre-programmed tests to validate and verify the performance of aircraft software systems.”

An AS-9100D-certified company, Avionyx will provide the team at Joby Aviation with extensive experience in performing software verification services in accordance with both FAA and EASA (European Union Aviation Safety Agency) standards. Avionyx’s expertise includes ASTM F3153-15, DO-178C, and DO-254 compliance. The company has supported numerous avionics manufacturers with avionics software and hardware engineering services since its founding in 1989. Previous projects at Avionyx included flight displays, communication (SatCom, VHF, ACP), navigation, surveillance such as ADS-B, system monitoring, flight control, and electronic flight bag (EFB) applications.

Software verification is a key component of a commercial aerospace certification program, the spokesperson from Joby explained. ”While we have much of this expertise in-house, there’s a lot of work to do.”

Pre-programmed tests will be conducted at Joby’s Vehicle Software Integration Lab in Marina, California, and at a similar facility that will be located in San Jose, Costa Rica, where Avionyx is based. These tests will validate and verify system performance via Joby’s flight simulation and hardware emulation capabilities, according to the company’s announcement.

In its Letter to Shareholders published last month, along with financial results from the first quarter of 2022, Joby revealed that its first design-intent Electric Propulsion Unit (EPU) had been manufactured and is already undergoing durability and performance testing. As of June 1, the team has completed high-intensity testing that is equivalent to 600+ flight hours, the Joby representative told Avionics.

“We continue to move through flight testing objectives with our full-scale pre-production prototype aircraft, including both flight testing and on-ground taxi testing,” said the spokesperson.

Tom Ferrell, Joby’s Development Assurance Lead, commented that the acquisition of Avionyx positions Joby to meet the necessary regulatory requirements in order to bring their eVTOL aircraft to market. “Having worked alongside Avionyx for the last year, I’m continuously impressed by the wealth of experience they bring to our software verification activities,” he added.

Avionyx CEO Larry Allgood also remarked on the news of the acquisition, saying that the Avionyx team is excited to contribute to this work. “Joby’s aircraft is one of the most transformative projects that I have seen during my career,” Allgood said.

The post Joby’s Avionyx Acquisition to Support eVTOL Software Testing and Verification Needs appeared first on Aviation Today.

Cloud-Based Flight Management Systems for Next Generation Aircraft

GE Aviation, SmartSky Networks, and Mosaic ATM have collaborated since January to connect cloud-based flight management systems (FMS) with airborne FMS. Pictured above are Brit Wanick of SmartSky Networks, Todd Kilbourne of Mosaic ATM, and Gary Goz of GE Aviation sharing their progress at the Connected Aviation Intelligence Summit this week.

GE Aviation, SmartSky Networks, and Mosaic ATM have been working together since January to connect cloud-based flight management systems (FMS) with airborne FMS. At the Connected Aviation Intelligence Summit last week, representatives from each company revealed the progress made through this collaboration and what they expect to achieve in the coming months.

The teams from GE, SmartSky, and Mosaic are currently finishing the experimental plan and software development, which should be completed within the next two to three months, according to Todd Kilbourne, Senior Program Manager, Mosaic ATM. In August, they expect to begin simulations of the use cases for trajectory negotiation at SmartSky’s lab in Virginia. Following the successful completion of these simulations, a flight test will be conducted to validate the results.

“We’ve set it up so we can implement this digital twin on three aircraft in a simulated lab. We’ll have one aircraft for the flight test and two simulated aircraft that have this digital twin concept in the simulation lab, and we’ll see how all that works together,” Kilbourne said.

In 2023, the collaboration may begin exploring additional use cases beyond trajectory negotiation like conflict detection and continuous descent arrivals. With the digital twin concept, said SmartSky’s Britton Wanick, VP Marketing & Partnerships, “we’re able to take a cloud-based FMS and have information from the airborne FMS, but also have access to a lot more [data] and share it across the entire ecosystem to address a variety of different use cases.”

These efforts are part of a NASA Innovation Award. Phase I of the project included SmartSky and Mosaic; GE Aviation joined as a partner for Phase II, which will continue until the end of 2023.

“We brought in GE Aviation because they have a modular functional FMS that is very compatible for this project,” explained Kilbourne. “It had an onboard component but also a component that could be easily hosted on the cloud.”

Mosaic, an air traffic modernization and optimization company, is building extensions to the cloud that will add functionality and is also creating interfaces to simulations of an air traffic management (ATM) system and an airline operations system.

In joining Mosaic and SmartSky for Phase II of this project, GE Aviation’s team made it a priority to enable offboarding of capabilities and reduce reliance on the computer onboard the aircraft. One of the problems in the aviation industry is that computing power installed on an aircraft rapidly becomes outdated, remarked Gary Goz, Navigation Systems Product Director at GE Aviation. “We want to add new capability and new functionalities to the flight management system; we’re constantly adding new capabilities, [but] we run out of computing resources very quickly,” he said.

Addressing this issue involves considering what safety-critical pieces are required to be onboard. Goz mentioned flight planning as an example of an area where efficiency can be improved. Pilots carry electronic flight bags (EFBs) onboard to use for finding optimal flight plans, but the information they are using isn’t available to the avionics system. “We’re striving to connect data that’s available outside avionics into the avionics themselves, and being able to use that technology outside of the avionics system,” he explained.

GE already has the capability to simulate the FMS on the ground—a digital twin version, essentially—and their current focus is linking onboard systems with the simulated system.

There is aircraft data that is only available to the aircraft, including optimal trajectory models, Kilbourne added. Synchronizing that data with a cloud-based digital twin version would result in a more accurate model. The high-resolution weather data, air traffic constraints, and other information that is only available on the ground will enable automation systems to provide more accurate trajectory predictions.

“The ground automation systems involved in air traffic control, air traffic management, and flight operations all use different customized trajectory models for calculations. I’ve been working on these for over 25 years and constantly hear things like, ‘I wish we had more information from the aircraft,’” said Kilbourne.

Providing more information from the aircraft to air traffic control would improve the ability to deconflict routes, Gary Goz stated. This information includes fuel levels, aircraft weight, and performance characteristics, which are not currently available to air traffic control. By offboarding the ability to optimize routes and deconflict traffic, he added, aircraft will be able to avoid common problems like holding patterns and entering congested areas.

Goz noted that for the GE Aviation team, the concept of a cloud-based FMS is part of a larger envisioned ecosystem. Such an ecosystem includes connected flight management systems solutions like providing the pilot’s EFB with the same interaction and data that are provided to the digital twin on the ground or in the cloud. When you have these components stitched together, Goz said—”The cloud, connected FMS, ATC—you have all the same data at your fingertips to be able to make decisions about trajectories and deconfliction.”

There is the potential for increased risk when enabling such capabilities, he commented. Cybersecurity is a key issue that the team has taken into account from the start.

Advanced air mobility (AAM) is an emerging space of interest for GE’s Aviation division, Goz noted. “There’s a need there,” he said. “It’s still very fluid. Things are starting to solidify in some areas, especially around how we manage traffic. This technology could grow quickly once you’ve proven it out in that space you could advance it.”

Mosaic’s Kilbourne is also confident that the cloud FMS technology and architecture will transfer to AAM. Although the space is slightly different from commercial and business aviation, there is compatibility in AAM with the developments that Mosaic, GE, and SmartSky are working on.

“The FAA doesn’t necessarily control the traffic in some of these UAM corridors,” Kilbourne said. “They have regulatory oversight, but there will be centers where the service providers that oversee these UAM airspaces will handle operations for flights within their control.”

In addition to the progress made in collaboration with GE and SmartSky, Todd Kilbourne shared that Mosaic ATM has been awarded a new Small Business Technology Transfer (STTR) Phase I from NASA to collaborate with a university partner. The focus of this project is creation of a toolkit for urban air mobility (UAM) communications management. The first component of the toolkit is a path loss prediction tool using a machine learning (ML) model, which will be trained using data from ray tracing software.

“We’re also going to develop an architecture for UAM comm that would be a robust architecture, could combine satellite communication, ground communication, and even air-to-air communication. [Our] recommendations could move the industry forward in designing a useful, robust architecture for UAM,” he shared.

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