NextGen encompassed many technologies, policies, and procedures. Changes to communications, navigation, surveillance, automation, information management, weather, and other areas were implemented after thorough safety testing.
Communications Data Comm (Controller-Pilot Data Link Communications) uses digital text messages to supplement voice communications between pilots and air traffic controllers. Unlike voice messages, Data Comm messages sent by controllers are delivered only to the intended aircraft, which eliminates the chance of another pilot acting on instructions for another aircraft with a similar call sign. It avoids the chance of misunderstood messages because of busy radio chatter or variations in the way people speak, and it can be a backup if a microphone malfunctions. It also preserves radio bandwidth when voice communication is necessary or preferred. Using Data Comm, tower air traffic controllers can send pilots of equipped aircraft departure clearance instructions to read, accept, and load into their
flight management system with the push of a button. Messages also are sent to
flight dispatchers, giving everyone a shared awareness for faster reactions to changing circumstances, such as approaching thunderstorms. Data Comm saves aircraft time waiting to take off, particularly when routes change, which reduces fuel use and engine exhaust emissions. It lowers the chances of delays or cancellations when weather affects the flight route. Pilots and controllers also can spend more time on other critical tasks, which enhances safety. The first part of the program, tower service, for 55 airports finished in 2016 more than two years ahead of schedule. Based on the initial success, airlines requested and the FAA approved in 2017 seven more airports to receive tower service to be completed by 2019. The first of these airports completed was
Joint Base Andrews in November 2017. The final airport was Van Nuys, which was completed in August 2018. In 2020, Cincinnati, Jacksonville, and Palm Beach were authorized to become the next three airports approved to operate Data Comm. Cincinnati started operating in 2021, and Jacksonville and Palm Beach began in 2022. Data Comm provides more benefits to airlines and passengers when aircraft are in flight. Various air traffic controller messages are available, including the ability to reroute multiple aircraft. Initial Data Comm services for high-altitude flight started in November 2019. As of 2025, it has scaled to 65 airports, connecting over 11,000 equipped aircraft, 23 U.S. air carriers, 106 non-U.S. air carriers, and more than 5,000 general and business aviation aircraft. And, as of 2025, Data Comm En Route services operate continuously across all 20 Air Route Traffic Control Centers, supporting 68 commercial operators and more than 8,000 equipped aircraft.Full en route services, which bring a wider array of messages than initial services, are scheduled to be complete at all centers in 2027. Enhanced services are planned after full en route services. These will include tools to support trajectory management, such as traffic management coordinator-initiated reroutes. Voice communication will always be part of air traffic control. In critical situations, it continues to be the primary form of controller-pilot interaction. However, for routine communications between pilots and controllers, Data Comm is preferred as it increases efficiency and airspace capacity. Data Comm is expected to save operators more than $10 billion over the 30-year life cycle of the program and the FAA about $1 billion in future operating costs. These consist of RNAV
standard instrument departures, T-Routes (1,200 feet above the surface to 18,000 feet of altitude), Q-Routes (18,000–45,000 feet of altitude), RNAV
standard terminal arrivals (STAR), RNAV (GPS) approaches, and RNP approaches. The FAA has published RNAV STAR procedures at 128 airports with this capability that enable aircraft to fly closer to the airport at a more fuel-efficient altitude before descending. From the top of the descent to landing, the aircraft has minimal level-off segments, and pilots can avoid using speed brakes and frequently adjusting the thrust lever, which also save fuel. These procedures can be flown when available and when pilots are allowed to use them. Using the
Wide Area Augmentation System, instrument-rated pilots can land using
GPS at airports where it was previously impossible. WAAS enhances the accuracy and integrity of position estimates. At an airport where a ground-based
Instrument Landing System (ILS) may be out of service, PBN approach procedures serve as a backup. The FAA will seldom, if ever, install a new ILS, opting instead for PBN approach procedures, which save money. More than 150,000 aircraft in the NAS are equipped with WAAS, and more than 4,900 published WAAS procedures serve approximately 2,500 airports. But even as PBN reshaped the navigational structure of the NAS, NextGen worked to ensure resilience. Recognizing that GPS signals can be vulnerable to interference or degradation, the FAA developed the NextGen
distance measuring equipment (DME) Program, a targeted effort to reinforce navigation infrastructure with strategically placed and upgraded Distance Measuring Equipment. En route and terminal DMEs are undergoing significant upgrades, including frequency changes and enhancements to Standard Service Volume (SSV). Several new DMEs have/will be installed to address gaps in signal coverage, and provide redundancy in areas where satellite signals may be unreliable. These upgrades ensure that aircraft with DME capabilities can continue flying PBN routes in the event of satellite disruptions, preserving system performance while easing pilot and controller workload. The goal was not to return to legacy dependence, but to build a layered, resilient architecture: one where satellite precision is primary, but terrestrial systems provide vital support when needed. While some DMEs will be decommissioned, deployment and upgrades of all stations is scheduled to be completed in 2035. In response to recommendations from the aviation community through RTCA's NextGen Mid-Term Implementation Task Force, the FAA began integrating PBN procedures to improve air traffic flow for 11 metroplexes, which are metropolitan areas where crowded airspace serve the needs of multiple airports. Through collaboration with the NextGen Advisory Committee, the FAA completed its projects at Atlanta, Charlotte, Cleveland-Detroit, Denver, Houston, Las Vegas, Northern California, North Texas, South Central Florida, Southern California, and Washington, D.C. Additionally, the FAA redesigned airspace incorporating PBN for 29 busy airports not meeting Metroplex program criteria. and an equivalent lateral spacing operations standard enabled through PBN gives flexibility at some airports to handle more departures. A rule change in 2015 allowed pilots to use a PBN approach procedure to take a shorter path to the runway more frequently. Aircraft can safely and efficiently land during simultaneous operations at certain airports with parallel runways without receiving directions from air traffic controllers monitoring them on
radar. The FAA implemented a national standard in 2016 for this capability, which is known as Established on RNP. EoR is in use at
Denver International Airport,
George Bush Intercontinental Airport in Houston, and
Los Angeles International Airport. Multiple Airport Route Separation (MARS) is a related multi-airport project as it extends the EoR concept from runways at a single airport to runways at airports close to each other. MARS will enable expanded use of RNP and new access to airports and runway configurations. It is expected to provide similar benefits and increase the airports’ throughput. In 2026, the FAA plans on beginning operations at the first site after validating the concept and determining that it is safe. The FAA aims for PBN to be used as a basis for daily operations throughout the National Airspace System, employing the appropriate procedure to meet the need. In some cases — as with metroplexes — this will include a highly structured, yet flexible, navigation pattern.
Surveillance Automatic Dependent Surveillance–Broadcast (ADS-B) is a technology that brings a major change to flight tracking. Instead of using ground-based radar to receive aircraft position, speed, and direction every five to 12 seconds, aircraft equipped with newer
GPS transponders determine this information and automatically send it once per second to air traffic control. ADS-B depends on an accurate satellite signal for position data. It is always broadcasting and requires no operator intervention. For the first time, pilots and air traffic controllers can see the same real-time display of air traffic, which improves situational awareness for improved safety. The FAA completed installation of new ground radio infrastructure in 2014, and coverage is available in all 50 states, Guam, Puerto Rico, the
Gulf of Mexico, and area off both coasts. Integration of ADS-B into en route and terminal automation platforms was completed in 2019. Aircraft flying in a large portion of controlled airspace have been required to be equipped for ADS-B Out since January 1, 2020. Even with the capabilities offered by ADS-B through satellite technology, surveillance radar is still relevant and will be used as a supplement and ultimately as backup to ADS-B in the event of service disruption. As of 2025, ADS-B infrastructure and equipage are mature and operational throughout the majority of controlled airspace. However, NextGen’s surveillance modernization did not end with deployment of controller tools. The program also set out to evaluate how this new data environment could enable next-generation flight deck surveillance and spacing capabilities; capabilities that go beyond pilot vision to enable tactical decision-making in the cockpit. Through the ADS-B IN RETROFIT SPACING INITIATIVE (AIRS), the FAA began operational evaluation of three advanced cockpit applications: Cockpit Display of Traffic Information (CDTI)-Assisted Visual Separation (CAVS), CDTI-Assisted Separation on Approach (CAS-A), and Initial Interval Management (I-IM). These applications are designed to improve spacing precision and increase throughput on arrival and approach, especially in congested airspace. In partnership with American Airlines and Aviation Communications & Surveillance Systems, the FAA launched operational trials beginning in 2021. The CAVS benefit report was completed in 2022, and the capability continues to be used operationally.
ADS-B Out With ADS-B Out, surveillance coverage increases because ground stations can be placed where obstructions or physical limitations don't allow radar. Future intended time and position of aircraft are more accurate for optimal flight and traffic flow. Airlines that fly routes over the Gulf of Mexico or offshore routes without radar coverage can use ADS-B to follow more-efficient routes and be diverted less often due to weather. At the nation's busiest airports, ADS-B Out is part of
Airport Surface Detection Equipment–Model X at 35 sites and Airport Surface Surveillance Capability at nine sites. Controllers can track the surface movement of aircraft and airport ground vehicles, which helps reduce the risk of taxiway conflicts and runway incursions. A software enhancement for these two capabilities called Airport Taxi Arrival Prediction was added to warn air traffic controllers when pilots are lined up to land on a taxiway instead of their assigned runway. To further expand surface surveillance using ADS-B Out, 18 airports without either of these systems are getting the Surface Awareness Initiative system. Another ground-based surveillance system that uses ADS-B is
Wide Area Multilateration (WAM), which can be installed in locations where radar is limited or can't be used. It operates at many airports in the Colorado mountains;
Juneau, Alaska;
Charlotte, N.C.; and Southern California Terminal Radar Approach Control facility. Additional WAM services are planned for the Atlanta and New York metropolitan areas. Because of the more frequent position update and coverage in areas without radar, ADS-B Out helps in performing life-saving search and rescue missions.
ADS-B In Operators who choose to equip their aircraft to receive ADS-B signals for ADS-B In can gain many other benefits and is where the industry gains the most value for investing in ADS-B Out. Traffic Information Services-Broadcast is a free service for pilots sending relevant traffic position reports to appropriately equipped aircraft to enhance safety. Flight Information Services-Broadcast is another free service delivering aeronautical and weather information to pilots to increase safety and efficiency. ADS-B Traffic Awareness System offers general aviation aircraft a low-cost alerting capability to prevent aircraft collisions. The more advanced
Airborne Collision Avoidance System X will support access to closely spaced runways in almost all weather conditions, flight deck interval management (IM), and separation similar to traditional visual operations with fewer nuisance alerts. The FAA anticipates ACAS X will replace the
Traffic Alert and Collision Avoidance System. In-Trail Procedures (ITP) reduce separation between aircraft during oceanic flights and is allowed for ITP-equipped aircraft in all oceanic airspace managed by Anchorage, New York, and Oakland en route centers. ADS-B-equipped aircraft with ITP software can fly more often at more fuel-efficient or less-turbulent flight levels. Equipment standards are complete and ready for manufacturers to produce the necessary avionics. The FAA is developing IM applications that use ADS-B In to sequence and space aircraft pairs. IM's precise spacing enables more-efficient flight paths in congested airspace and maximizes airspace and airport use. Enhanced air traffic control capabilities for closely spaced parallel runway approach operations may also be assisted by ADS-B In that is integrated with the terminal automation system. The first ground-based phase began operating at the
Albuquerque Air Route Traffic Control Center in 2014. In 2017, the FAA supported a NASA evaluation of prototype avionics and procedures. The FAA sponsored a demonstration of IM operations using prototype avionics on closely spaced parallel runways at San Francisco International Airport in 2019. These flight demonstrations showed precise spacing is possible in real-world environments. The FAA completed the IM standards, and manufacturers can produce the necessary avionics. The FAA worked with American Airlines and ACSS to install ADS-B In avionics that enable IM on the airline's fleet of Airbus A321 aircraft. The avionics enabled initial IM operations in Albuquerque en route airspace starting in 2022. Operations will be used to gather benefits data to share with the aviation community to motivate other air carriers to equip for ADS-B In. Another application is Cockpit Display of Traffic Information (CDTI) Assisted Visual Separation (CAVS), which is used by air carriers to enhance traffic situational awareness. It allows a flight crew to continue a visual landing procedure using the electronic display to maintain separation if the pilot loses sight of traffic because of reduced visibility. It is expected to reduce go-arounds due to traffic flying too close on the final approach, which saves time and distance flown. Standards are complete and ready for manufacturers to produce the necessary avionics. CDTI-Assisted Separation on Approach (CAS-A) is third type of application that uses ADS-B In. It is similar to CAVS except that pilots don't need to see the aircraft ahead through the window. Pilots also can continue flying at lower ceiling thresholds and with reduced spacing along the approach path during certain weather conditions to enable higher throughput. As with IM, CAVS and CAS-A were installed on the American Airlines fleet of Airbus A321 aircraft, and the airline plans on sharing its data with the aviation community. The airline started operating CAVS in May 2021. A fourth application the airline has tested will help to avoid wake turbulence. The vertical path indicator gives in-trail pilots the lead aircraft’s vertical path via an ADS-B guidance display. Through the testing of ADS-B In capabilities, American Airlines is interested in equipping more of its aircraft for ADS-B In. Although it can be used without it, a NASA-developed application called Traffic Aware Strategic Aircrew Requests (TASAR) could benefit from aircraft equipped with ADS-B In. TASAR suggests a new route or altitude change to save time or fuel, and ADS-B In can assist by enabling the software to determine what requests will likely be approved by air traffic control due to nearby traffic. A NASA study of
Alaska Airlines flights projected that the airline would save more than 1 million gallons of fuel, more than 110,000 minutes of flight time, and $5.2 million annually.
Automation Air Traffic Control Computer Stations En route automation drives display screens used by air traffic controllers to safely manage and separate aircraft at cruising altitudes. Terminal automation is for controllers to manage air traffic immediately around major airports. It is used for separating and sequencing of aircraft, conflict and terrain avoidance alerts, weather advisories, and radar vectoring for departing and arriving traffic. The FAA's
En Route Automation Modernization (ERAM) platform replaced the legacy Host system for en route air traffic control in 2015. A sustainment and enhancement program is in progress and scheduled to be completed in 2026. En route controllers can now track as many as 1,900 aircraft at a time, up from the previous 1,100 limit. Coverage extends beyond facility boundaries, enabling controllers to handle traffic more efficiently. This coverage is possible because ERAM can process data from 64 radars versus 24. For pilots, ERAM increases flexible routing around congestion, weather, and other restrictions. Real-time air traffic management and information sharing on flight restrictions improves airlines' ability to plan flights with minimal changes. Reduced
vectoring and increased radar coverage leads to smoother, faster, and more cost-efficient flights. Trajectory modeling is more accurate, allowing maximum airspace use, better conflict detection, and improved decision-making. Two functionally identical channels with dual redundancy eliminate a single point of failure. ERAM also provides a user-friendly interface with customizable displays. It revolutionizes controller training with a realistic, high-fidelity system that challenges developmental practices with complex approaches, maneuvers, and simulated pilot scenarios that were unavailable with Host. The Terminal Automation Modernization and Replacement program's
Standard Terminal Automation Replacement System (STARS) replaced the legacy Automated Radar Terminal System. Installation was completed in 2021, and it is operating at more than 200 FAA and Department of Defense (DoD) terminal radar approach control facilities, and more than 600 FAA and DoD air traffic control tower facilities. STARS maintains safety while increasing cost-effectiveness at terminal facilities across the National Airspace System. It provides advanced features and functionalities for controllers, such as a state-of-the-art flat-panel LED display and the ability to save controller workstation preferences. It is also easier for technicians to maintain. Approach Runway Verification is a STARS function giving air traffic controllers visual and audible alerts if an aircraft on arrival is lined up with the wrong runway, a closed runway, a taxiway, or wrong airport. At 50 facilities as of 2025, the FAA intends to bring this capability to every facility with STARS. Although ERAM and STARS are not NextGen programs themselves, they lay the foundation to enable critical NextGen capabilities in terminal and en route airspace.
Traffic Flow Decision Support Systems These FAA
Decision Support Systems (DSS) are used by air traffic controllers to optimize traffic flow across the National Airspace System (NAS) and are central to the FAA's goal of trajectory-based operations: • Traffic Flow Management System (TFMS) • Time Based Flow Management (TBFM) • Terminal Flight Data Manager (TFDM) TFMS is the primary automation system used by the
Air Traffic Control System Command Center and nationwide traffic management units to regulate air traffic flow, manage throughput, and plan for future air traffic demand. TFMS's 31 tools exchange information and support other DSS through
System Wide Information Management (SWIM). The FAA deployed a TFMS software refresh to 82 sites in 2016 and completed a hardware refresh at those sites in 2018. The FAA continues to develop future concepts for TFMS modeling and predicting capabilities. Flow Management and Data Services (FMDS) is the planned to fully replace TFMS in 2031. FMDS is expected to improve data integration, increase data sharing, and manage the larger volume of continually produced NAS data. TBFM allows traffic management units to schedule and optimize the arrival load for major airports. It is operational at 20 en route centers, 28 terminal radar approach control facilities (TRACON), and 54 airport towers. Its tools, such as extended metering and integrated departure arrival capability, help controllers sequence traffic with time instead of distance. Performance Based Navigation route and procedure data help improve predicted arrival times. The integrated departure arrival capability tool deployed to the sixth and final site in June 2022. One future TBFM tool, terminal sequencing and spacing, will lengthen metering capability into terminal airspace. It was developed by NASA and delivered to the FAA in 2014. Another capability in development is machine learning trajectory prediction used to project aircraft location by using aircraft performance models. Through 2027, TBFM will be upgraded to meet security requirements. A sustainment project is underway to upgrade the hardware and software. In 2016, the FAA awarded Lockheed Martin a $344 million contract to develop and deploy TFDM, which is a new system for surface management. It supports decision-making on the airport ground by integrating flight, surface surveillance, and traffic management information using SWIM. TFDM tools consist of electronic
flight progress strips, departure queue management, surface management, and surface situational awareness. Implementation of electronic flight data and the integration of TBFM and TFMS through SWIM will enable TFDM to consolidate some previously independent systems. The FAA and NASA in 2021 finished research and testing on a surface scheduling capability that calculates gate pushbacks at busy hub airports so that each airplane can roll directly to the runway and take off. TFDM will be deployed in two configurations. Configuration A has full functionality, and Charlotte began operating in May 2024, the first of 27 large, high-density airports. Configuration B has improved electronic flight data and electronic flight strips. Cleveland began operating with these capabilities in October 2022. Another 21 sites are scheduled to receive this configuration. Deployment at all locations is planned for completion in July 2029.
Advanced Technologies and Oceanic Procedures Advanced Technologies and Oceanic Procedures (ATOP) replaced existing oceanic air traffic control systems and procedures. ATOP fully integrates flight and radar data processing, detects conflicts between aircraft, provides satellite data link communications and surveillance, eliminates paper flight strips, and automates manual processes. ATOP fully modernizes oceanic air traffic control automation and allows flight operators to take further advantage of investments in cockpit digital communications. The FAA reduces intensive manual processes that limit controllers' ability to safely handle airline requests for more efficient tracks or altitudes over long oceanic routes. The FAA can meet international commitments of reducing aircraft separation standards, which increase flight capacity and efficiency. ATOP is used at all three oceanic en route traffic control centers, which are in Anchorage, New York, and Oakland. After the first technology refresh in 2009, ATOP's second refresh was completed at these centers in 2020, which is intended to support the system through 2028. An enhancement program started in 2018 comprises five large-scale capabilities. Deployment began in 2021 and is set to be complete in 2025. These changes are intended to optimize flight trajectories, decrease controller workload, reduce costs, and improve system safety.
Information Management System Wide Information Management The FAA traditionally shared information using a variety of technologies, including radio, telephone, Internet, and dedicated virtual private network connections. However, the agency leveraged new information management technologies to improve information delivery and content. In 2007, the FAA established the
SWIM program to implement a set of information technology principles in the National Airspace System (NAS) and provide users with relevant and commonly understandable information. SWIM facilitates NextGen's data-sharing requirements, serving as the digital data-sharing backbone of the NAS. This platform offers a single point of access for aeronautical, flight, surveillance, and weather data. Producers can publish data once, and approved consumers can access needed information through a single connection instead of linking two systems with fixed network connections and custom point-to-point application-level data interfaces. The format supports collaboration within domestic and international aviation communities. In 2015, the SWIM program completed its first segment, which established a common infrastructure and connection points at all en route traffic control centers. The program's second segment started in 2016. It established a service-oriented architecture — composed of producers, consumers, and a registry — and connected NAS programs, such as the Traffic Flow Management System, to provide large data sources for consumers. Several enhancements were later deployed—enterprise service monitoring, identity and access management, NAS common reference service, SWIM Terminal Data Distribution System, and SWIM Flight Data Publication Service—and SWIM continues to add NAS air traffic management content providers and consumers. The FAA is working on software and hardware enhancements as well as technology refreshments to keep up with an expanding information environment. As of 2024, 51 FAA programs and external organizations, including airlines, produce data for more than 200 services via the SWIM network. Of the more than 800 registered consumers, about 400 are regular users. The SWIM Cloud Distribution Service (SCDS) was established in 2019 to simplify how users can gain access to non-sensitive NAS information. In 2021, the SWIM Industry-FAA Team (SWIFT) portal started, which updates and enhances the SCDS. SWIFT and a user forum are two resources where individuals and organizations can learn more about SWIM. SWIM reduces costs, can increase operational efficiency, and opens the possibility of creating new services for the aviation community. Data sharing among pilots, flight operations personnel, controllers, and air traffic managers is essential to achieving a NextGen objective of trajectory-based operations. Airlines and airports have reported using FAA data to improve operations. The most extensive use of SWIM data was supporting improved awareness of operating conditions and flight status, especially on the airport surface and in situations when aircraft transition from contact with one air traffic control center to the next. Connected aircraft is a concept to deliver high-performance communications in future operations by using commercial broadband internet services instead of aviation-specific infrastructure. Aircraft will be able to access SWIM data for improved decision-making. The most dynamic use of real-time surveillance data outside the FAA may be providing flight-tracking services to the flying public and aviation businesses. Through web browsers and mobile apps, service subscribers can access current information about flight and airport status and delays. Besides improved capacity, aging airport communications infrastructure requires more extensive and expensive monitoring, maintenance, repair, or replacement. Airport construction and unexpected equipment outages also require temporary communications alternatives, and AeroMACS also could serve as a backup. The system was implemented in 2017 under the FAA Airport Surface Surveillance Capability program. As of December 2020, more than 50 airports in nearly 15 countries are using AeroMACS. It could take up to 20 years to deploy the technology to more than 40,000 airports worldwide.
Weather The FAA's NextGen Weather program provides aviation weather products that support air traffic management during weather events, helping to improve aviation safety and minimize passenger delays. The largest cause of National Airspace System (NAS) air traffic delays is weather, which was responsible for 75 percent of system-impacting delays of more than 15 minutes from June 2017 to May 2023. With more accurate and timely weather predictions, airports and airlines could prevent as many as two-thirds of weather-related delays and cancellations. Aviation weather is composed of information observation, processing, and dissemination. NextGen weather systems consist of the NextGen Weather Processor (NWP) to generate advanced aviation-specific weather products and Common Support Services– Weather (CSS-Wx) for dissemination of these products. Both started operating at the national enterprise management centers in Atlanta and Salt Lake City in 2024, and full deployment is scheduled to be completed in 2025. Five en route centers and the Potomac TRACON are getting the NWP. Aviation weather displays will be located at the Air Traffic Control System Command Center, 21 en route centers, three center radar approach control (CERAP) facilities, and 45 TRACONs. The William J. Hughes Technical Center will receive a NWP external web server via the internet for non-FAA users of the aviation weather display. CSS-Wx will be available at 21 en route centers and three CERAPs. The NWP program established a common weather processing platform to replace the legacy FAA weather processor systems and offers new capabilities. The fully automated NWP identifies safety hazards around airports and in cruising altitude airspace. It supports strategic traffic flow management, including the translated weather information needed to predict route blockage and airspace capacity constraints up to 8 hours in advance. NWP uses advanced algorithms to create current and predicted aviation-specific weather information with data from the FAA and
National Oceanic and Atmospheric Administration (NOAA) radar and sensors, and NOAA forecast models. Part of the NWP, the Aviation Weather Display consolidates the current Weather and Radar Processor, Integrated Terminal Weather System, and the Corridor Integrated Weather System displays. The Aviation Weather Display provides consistent weather information at a glance for en route and terminal controllers, and includes NWP and NOAA weather products. CSS-Wx is the single producer of weather data, products, and imagery within the NAS, using standards-based weather dissemination via SWIM. It consolidates and enables the decommissioning of legacy weather dissemination systems. It also offers NWP and NOAA weather products, and other weather sources for integration into air traffic decision support systems, improving the quality of traffic management decisions and enhancing controller productivity during severe weather. CSS-Wx information consumers include air traffic controllers and managers, commercial and general aviation operators, and the flying public. The FAA's Weather Technology in the Cockpit team of researchers are experts on the pitfalls of how weather is displayed in
general aviation cockpits. Their main research goal is to encourage improvements in how meteorological information is shown to pilots so they can consistently and accurately interpret that information, understand its limitations, and use it to avoid bad weather.
Multiple Runway Operations and Separation Management Efficiency of multiple runway operations (MRO), particularly those that are closely spaced, has been limited by safety risks, including collisions and
wake turbulence with nearby aircraft. MRO advancements improve access to closely spaced parallel runways to enable more departure and arrival operations during
instrument meteorological conditions, which increase efficiency and capacity while reducing flight delays. The advancements enable the use of
simultaneous approaches in low-visibility conditions, decrease separation for approaches to runways with stricter spacing requirements, and reduce the effects of wake turbulence that leads to increased separation. Revised wake separation standards, known as wake recategorization or wake recat, have been reduced at terminal radar approach control (TRACON) facilities and airports across the United States. Phase 1 of wake recat replaced a weight-based standard with new size categories more optimally based on aircraft wake turbulence characteristics. Phase 1.5 refined Phase 1 with further reductions to separation. These phases were implemented at 31 airports. Phase 2 defined pairwise wake turbulence separation standards among 123 aircraft types that make up 99 percent of global operations at 32 U.S. airports. Air traffic control operations then can implement customized wake turbulence categories optimized to maximize the benefit for an airport fleet. With these changes, airports experienced as high as an average 10 percent increase in throughput, enabling more aircraft to take off and land with shorter wait times on taxiways and runways. At Indianapolis, airlines save more than $2 million per year in operational costs with wake recat. At Philadelphia, airlines save about $800,000 per year. The final phase is to develop dynamic wake separation enhancements for decision support systems taking wind into account. A total wind dynamic wake separation enhancement will give terminal area controllers a suite of decision support tools expected to increase airport throughput by an estimated 5 percent to 10 percent beyond what was already accomplished by the Phase II-based static wake separation standards. The FAA continues to evaluate procedures at airports with closely spaced parallel runways with simultaneous approaches and departures. With independent runways, aircraft can pass aircraft approaching the parallel runway next to them while dependent runways require pilots to maintain a diagonal separation. After determining that lateral runway separation can be safely reduced, the FAA revised the separation standard from 4,300 feet to 3,600 feet for independent arrivals in August 2013. Dual independent parallel operations started operating in Atlanta in 2014. Dual independent parallel operations with offset started operating in Detroit in 2015 and at Chicago-O'Hare in 2016. Triple independent parallel operations started in Atlanta and Washington-Dulles in 2017. Further revisions to closely spaced parallel operations were included in the November 2015 update to
FAA Order 7110.65, Air Traffic Control. The revisions reduce lateral separation requirements to as close as 3,900 feet for triple independent approaches, and 3,000 feet for offset dual independent approaches without requiring high-update-rate radar or Automatic Dependent Surveillance–Broadcast. Dependent parallel operations at 1 nm for runways less than 2,500 feet to 3,600 feet apart began operations at Dallas-Love Field, Memphis, Minneapolis-St. Paul, New York-JFK, Portland, Raleigh-Durham, and Seattle in 2016, and in San Francisco in 2017. Dependent parallel operations for runways more than 3,600 feet apart started operating at Cincinnati/Northern Kentucky, Louisville, Memphis, and Phoenix in 2017. For dual-dependent approaches, the runway spacing requirement remains 2,500 feet, but the diagonal spacing was reduced from 1.5 nautical miles (nm) to 1 nm. In 2018, FAA Order 7110.308C identified specific airports — Boston, Cleveland, Memphis, Newark, Philadelphia, Seattle, San Francisco, and St. Louis — with runways spaced less than 2,500 feet apart that can reduce diagonal spacing between aircraft on parallel approaches from 1.5 nm to 1 nm. The Converging Runway Display Aid is an automation tool used by air traffic controllers to manage the sequence of arrival flows on converging or intersecting runways. It is operational at Boston, Chicago O'Hare, Denver, Las Vegas, Memphis, Minneapolis-St. Paul, Newark, Phoenix, and Philadelphia, and enhances an airport's throughput under certain conditions. A separation efficiency tool called Automated Terminal Proximity Alert was first implemented at Minneapolis-St. Paul in May 2011 and now is deployed at 14 TRACON facilities across the country. It better informs air traffic controllers of gaps so they can tell pilots to adjust their speed or direct them to a shorter path to the runway. During its first year of use, the number of
go-arounds declined by 23 percent for flights headed to Minneapolis-St. Paul. Excess flight time due to a go-around decreased by 19 percent.
Improved Approaches and Low-Visibility Operations The FAA supports several optional capabilities for operators who need to access an airport when the cloud ceiling is less than 200 feet above the runway or visibility is less than a half mile. They help to achieve NextGen goals of safely increasing access, efficiency, and throughput at many airports when low visibility is the limiting factor. For instance, after a reduction of minimum visual runway range requirements, an FAA assessment showed airport access during low-visibility conditions improved in two ways: almost 6 percent fewer periods with no access and 17 percent more flights could land. EFVS uses sensor technologies to give pilots a clear, real-time virtual image of the view outside the aircraft, regardless of the cloud cover and visibility conditions. Pilots can identify required visual references that would be impossible without it. It provides access that otherwise would be denied because of low visibility. A
synthetic vision guidance system combines flight guidance display technology with high-precision position assurance monitors to continuously and correctly depict the external scene and runway. It can assist a pilot's transition to natural vision references. Enhanced Low Visibility Operations (ELVO) was a low-cost infrastructure program to reduce minimum ceilings and
runway visual range through a combination of ground equipment and navigation procedures. Most ELVO improvements resulted from FAA Order 8400.13. The Ground Based Augmentation System Landing System (GBAS) uses GPS navigation to support all precision-approach categories. Newark Liberty International Airport and Houston's George Bush Intercontinental Airport operate non-federal GBAS systems approved for operations to as low as 200 feet above the runway.
Remote Towers Remote tower technology may enable controlled air traffic for small airports without a physical tower or that need to replace an aging tower. Controllers from the remote site may monitor and separate traffic by viewing the scene at the airport equipped with a panoramic color video cameras with pan-tilt-zoom and night vision features. Automated identification and relevant aircraft information may also be displayed on video monitors. At Leesburg Executive Airport in Virginia, the FAA had authorized air traffic control services to use this system as a test site until the vendor decided to end the project in 2023. Testing at the other tower at the Northern Colorado Regional Airport near Fort Collins/Loveland has been paused. The FAA continues to evaluate
remote tower technology as a potentially cost-effective alternative to traditional federal contract towers. The agency completed construction of a test bed at the William J. Hughes Technical Center and Atlantic City International Airport in 2024 to better understand the full capabilities of a remote tower system.
Energy and Environment The FAA's environmental vision is to develop and operate a system that protects the environment while allowing for sustained aviation growth. The FAA Office of Environment and Energy Research and Development is working to reduce air and water pollution, carbon dioxide emissions that may affect climate, and noise that can disturb residents near airports.
Airframe and
aircraft engine technology,
alternative fuels, air traffic management modernization and operational improvements, improved scientific knowledge and integrated modeling, and policies, environmental standards, and market-based measures will contribute toward meeting almost all of these goals. Noise and emissions will be the main environmental problems for National Airspace System (NAS) capacity and flexibility unless they are effectively managed and mitigated. An FAA study conducted in 2015 showed that since 1975, the number of people flying in the United States increased from about 200 million to an estimated 800 million, yet the number of people exposed to significant aircraft noise had dropped from about 7 million to nearly 340,000. Even with this decrease, community concern regarding aircraft noise is climbing. The FAA aims to minimize the impact of noise on residential areas without compromising safety. The agency's goal was to reduce the number of people around airports exposed to a day-night average aircraft sound level of 65 decibels to less than 300,000 by 2018. One way the agency planned to achieve it was by adopting a new noise standard for certain newly certificated subsonic jet airplanes and subsonic transport category large airplanes. The FAA's neighborhood environment survey, the largest of its kind, about aircraft noise exposure and its effects on communities around airports was completed in 2016. The results showed that considerably more people are upset by aircraft noise regardless of the level. The FAA will use those results and other research underway to re-evaluate criteria to define significance under the
National Environmental Policy Act and federal land use guidelines. In addition, the FAA has researched other affected areas, such as sleep disturbance, cardiovascular health, and children's learning. The FAA also is examining the potential noise effects of new aircraft in the NAS, such as drones and supersonic jets. The Continuous Lower Energy, Emissions, and Noise (CLEEN) program is a public-private partnership under NextGen to accelerate development and commercial deployment of more-efficient technologies and sustainable alternative fuels. The first five-year agreement with manufacturers from 2010 to 2015 produced jet engine, wing, and aerodynamic technologies; automation and flight management systems; fuels; and materials. One result of this effort is
General Electric's Twin Annular Premixing Swirler II Combustor, which reduces nitrogen oxide emissions by more than 60 percent compared to the
International Civil Aviation Organization (ICAO)
nitrogen oxide standard adopted in 2004. A second five-year agreement started in 2015 aimed to lower cumulative noise levels, reduce fuel consumption, cut nitrogen oxide emissions, and speed commercialization of alternative jet fuels. Both phases are estimated to lower the aviation industry consumption of fuel by 51.1 billion gallons through 2050, reducing airline costs by $200 billion, and cut carbon dioxide emissions by 500 million metric tons. Another potential benefit is a 10 percent reduction in the noise contour area by 2050. A third five-year phase of CLEEN started in 2021. The FAA awarded more than $100 million for six companies to help develop technologies that reduce fuel use, emissions, and noise. Goals are to reduce carbon dioxide emissions by improving fuel efficiency by at least 20 percent below the relevant ICAO standard, drop nitrogen oxide emissions by 70 percent relative to the most recent ICAO standard, lower particulate matter emissions below the ICAO standard, and slash noise by 25 dB cumulative relative to the FAA Stage 5 standard. Since 2009,
ASTM International approved five ways of producing sustainable alternative jet fuel that requires no modification to aircraft or engines, and more are being developed, tested, and evaluated. The FAA's efforts helped
United Airlines use an alternative jet fuel made from hydroprocessed esters and fatty acids for its daily operations at Los Angeles starting in 2016. The airline in 2021 flew a Boeing 737 Max 8 with one of its engines running on 100 percent alternative aviation fuel. The near-term goal is to produce 3 billion gallons of sustainable alternative aviation fuel by 2030, and the ultimate goal is nearly 35 billion gallons by 2050, enough to meet the entire industry need. More than 222,000 registered piston engine general aviation aircraft can operate with leaded
aviation gasoline, the only remaining transportation fuel in the United States that contains
lead. The FAA and Piston Aviation Fuels Initiative have been researching an acceptable unleaded fuel alternative. The FAA approved the first unleaded fuel that can be used for all piston engine aircraft September 1, 2022. The goal is to have only unleaded aviation fuel available by the end of 2030. The FAA uses the Aviation Environmental Design Tool to assess the environmental effect of federal actions at airports as well as on air traffic, airspace, and aviation procedures. Along with other federal agencies and
Transport Canada, the FAA funds the Aviation Sustainability Center, which is contributing to developing international aviation emission and noise standards. In 2016, the United States and 22 countries reached an agreement on a first-ever global aircraft carbon dioxide standard to encourage more fuel-efficient technologies to be integrated into aircraft designs. In 2020, the ICAO council adopted a new environmental measure of non-volatile particulate matter emissions. It replaces the 1970s-era "smoke number" — a figure that describes the visibility of emissions — with a much more accurate measure of emissions particles.
Safety The FAA's safety program is guided by its
Safety Management System — an agency-wide approach that directs the management of NextGen initiatives. NextGen capabilities must maintain safe operations in the National Airspace System (NAS), and the FAA has many processes to ensure that flying remains safe. The interconnected nature of NextGen presents complicated safety challenges that call for an integrated path to safety
risk management. Integrated safety risk management explores safety risk from a NAS enterprise framework to identify potential safety gaps inherent in NextGen capabilities. It identifies safety issues by assessing risk across organizational, system, and program boundaries, and relies on FAA-wide collaboration to capture the most relevant safety information to assist in decision-making. Aviation watchdogs once measured safety by the number of accidents. Commercial aviation accidents eventually became so rare that the FAA began to measure potential precursors to accidents. Loss of a safe margin of separation between aircraft became the risk measure that the FAA tracked and reported. Proximity is a valid indicator, but is an incomplete picture and provides no insight into accidents' causal factors. System Safety Management is a NextGen portfolio of initiatives to develop and implement policies, processes, and analytical tools that the FAA and industry uses to ensure the safety of the NAS. The goal is to be certain that changes introduced with NextGen capabilities maintain or enhance safety while delivering capacity and efficiency benefits to NAS users. Improved risk analysis processes and new safety intelligence tools help safety analysts go beyond examining past accident data to detecting risk and implementing strategies to prevent accidents. The System Safety Management Transformation program enables safety analyses to determine how NAS-wide operational improvements will affect safety and evaluate potential ways to reduce safety risk. It consists of three tools: Airport Surface Anomaly Investigation Capability, Integrated Safety Assessment Model, and Safety Information Toolkit for Analysis and Reporting. Aviation Safety Information Analysis and Sharing (ASIAS) provides a platform for improvements to the safety performance measurement infrastructure. More than 260 stakeholders organizations provide data for analysis, including 45 airlines. ASIAS has grown to involve other operators since its charter in 2007. The
Commercial Aviation Safety Team (CAST), composed of airlines, manufacturers, industry association regulators, labor unions, and air traffic controllers, helped reduce the fatality risk for commercial aviation in the United States by 83 percent from 1998 to 2007. With the help of these new initiatives, the team's latest goal is to further lower the U.S. commercial fatality risk by 50 percent from 2010 to 2025. The CAST plan comprises 96 enhancements aimed at improving safety across a wide variety of operations. == Stakeholder Collaboration ==