General Dynamics Mission Systems introduced the new Badger software-defined radio today at the Navy League’s Sea-Air-Space Symposium in National Harbor, Maryland. Produced at the company’s Scottsdale, Arizona facility, the Badger is a compact, 2-channel software-defined radio that provides Multiple Independent Levels of Security (MILS) for ship-to-ship and ship-to-shore voice and data communications. It is the only radio available that provides High Frequency (HF), Very High Frequency (VHF), Ultra High Frequency (UHF) and SATCOM Mobile User Objective System (MUOS) waveform capability. The integration of MUOS significantly enhances beyond line-of-sight, or satellite voice and data communications.
General Dynamics Mission Systems Introduces Badger Software-Defined Radio
Badger’s software-defined, flexible open architecture enables future next-generation communications including waveforms, encryption algorithms and advanced network connectivity to be easily incorporated without redesign. Similar to a commercial smartphone, this approach simplifies the incorporation of new features and functions by enabling the radio to be upgraded in the field without having to take it out of service, resulting in significant time and cost savings. In addition, the Badger’s Voice over IP (VoIP) audio capability modernizes and simplifies platform audio distribution using network connectivity.
The Badger is based on the long history of General Dynamics’ Digital Modular Radio (DMR). With over 900 radios delivered, DMR provides secure communications aboard U.S. Navy surface and sub surface vessels, as well as fixed sites. At a quarter of the size of DMR, Badger provides the waveforms and flexibility of the DMR in a compact platform.
«The Badger was developed in collaboration with our customer to meet their requirements for smaller ships and platforms», said Stan Kordana, Vice President of Surface Systems at General Dynamics Mission Systems. «Badger offers many of the same capabilities that have made DMR a communications standard for the U.S. Navy, in a much smaller form factor. The reduced size, weight and power make it ideal for smaller platforms across multiple domains that only require two channels, and at the same time simplifies logistics and reduces costs».
The Badger has programmable embedded NSA certified Type 1 encryption that secures communications and simplifies the system architecture. It has MILS capability which enables it to communicate simultaneously at multiple levels of security, on each of the radio’s two channels.
Badger Datasheet
Frequency Range
2 MHz – 512MHz contiguous
Size: H × D × W
11.23”/285 mm × 22.09”/561 mm × 8.82”/224 mm
Weight
45 lbs./20.4 kg (approximately)
Input Power
100-140 VAC, (47-63 Hz)
Operating Temperature
0° to 55° C
Vibration
MIL-STD-167
Shock
MIL-S-901
EMI
MIL-STD-461, and MIL-STD-1399
General Dynamics Unveils Badger Software-Defined Radio at Sea Air Space 2021
The U.S. Navy christened its newest Freedom-variant Littoral Combat Ship (LCS), the future USS Nantucket (LCS-27), during a 10 a.m. CDT ceremony Saturday, August 7, in Marinette, Wisconsin.
Navy christened Littoral Combat Ship USS Nantucket (LCS-27)
The principal speaker was Representative Mike Gallagher, U.S. Representative for Wisconsin’s 8th District. In a time-honored Navy tradition, the ship’s sponsor, Ms. Polly Spencer, broke a bottle of sparkling wine across the bow.
«The future USS Nantucket (LCS-27) will be the third U.S. Navy ship commissioned to honor the maritime history and spirit of Nantucket», said Acting Secretary of the U.S. Navy Thomas Harker. «I have no doubt the Sailors of USS Nantucket (LCS-27) will carry on the proud legacy from generations past in preserving sea lanes, countering instability, and maintaining our maritime superiority».
LCS is a fast, agile, mission-focused platform designed to operate in near-shore environments, winning against 21st-century coastal threats. The platform is capable of supporting forward presence, maritime security, sea control, and deterrence.
The LCS class consists of two variants, the Freedom-variant and the Independence-variant, designed and built by two industry teams. The Freedom-variant team is led by Lockheed Martin in Marinette, Wisconsin (for the odd-numbered hulls). The Independence-variant team is led by Austal USA in Mobile, Alabama, (for LCS-6 and the subsequent even-numbered hulls).
The first Nantucket, a Passaic class coastal monitor, commissioned on February 26, 1863. Assigned to the South Atlantic Blockading Squadron, Nantucket participated in the attack on Confederate forts in Charleston Harbor on April 7, 1863. Struck 51 times during the valiant yet unsuccessful assault on the vital Southern port, the single-turreted monitor was repaired at Port Royal and returned to Charleston to support Army operations on Morris Island. The second Nantucket, a wooden light ship built in 1907 for the Lighthouse Service, was transferred to the Navy by executive order on April 11, 1917. During World War I, the ship continued its duties of warning vessels away from Nantucket Shoals and aided in guarding nearby waters against U-boats.
Ship Design Specifications
Hull
Advanced semiplaning steel monohull
Length Overall
389 feet/118.6 m
Beam Overall
57 feet/17.5 m
Draft
13.5 feet/4.1 m
Full Load Displacement
Approximately 3,200 metric tons
Top Speed
Greater than 40 knots/46 mph/74 km/h
Range at top speed
1,000 NM/1,151 miles/1,852 km
Range at cruise speed
4,000 NM/4,603 miles/7,408 km
Watercraft Launch and Recovery
Up to Sea State 4
Aircraft Launch and Recovery
Up to Sea State 5
Propulsion
Combined diesel and gas turbine with steerable water jet propulsion
Power
85 MW/113,600 horsepower
Hangar Space
Two MH-60 Romeo Helicopters
One MH-60 Romeo Helicopter and three Vertical Take-off and Land Tactical Unmanned Air Vehicles (VTUAVs)
Core Crew
Less than 50
Accommodations for 75 sailors provide higher sailor quality of life than current fleet
Integrated Bridge System
Fully digital nautical charts are interfaced to ship sensors to support safe ship operation
Core Self-Defense Suite
Includes 3D air search radar
Electro-Optical/Infrared (EO/IR) gunfire control system
Rolling-Airframe Missile Launching System
57-mm Main Gun
Mine, Torpedo Detection
Decoy Launching System
Freedom-class
Ship
Laid down
Launched
Commissioned
Homeport
USS Freedom (LCS-1)
06-02-2005
09-23-2006
11-08-2008
San Diego, California
USS Fort Worth (LCS-3)
07-11-2009
12-07-2010
09-22-2012
San Diego, California
USS Milwaukee (LCS-5)
10-27-2011
12-18-2013
11-21-2015
San Diego, California
USS Detroit (LCS-7)
08-11-2012
10-18-2014
10-22-2016
San Diego, California
USS Little Rock (LCS-9)
06-27-2013
07-18-2015
12-16-2017
San Diego, California
USS Sioux City (LCS-11)
02-19-2014
01-30-2016
11-17-2018
Mayport, Florida
USS Wichita (LCS-13)
02-09-2015
09-17-2016
01-12-2019
Mayport, Florida
USS Billings (LCS-15)
11-02-2015
07-01-2017
08-03-2019
Mayport, Florida
USS Indianapolis (LCS-17)
07-18-2016
04-18-2018
10-26-2019
Mayport, Florida
USS St. Louis (LCS-19)
05-17-2017
12-15-2018
08-08-2020
Mayport, Florida
USS Minneapolis/St. Paul (LCS-21)
02-22-2018
06-15-2019
USS Cooperstown (LCS-23)
08-14-2018
01-19-2020
USS Marinette (LCS-25)
03-27-2019
10-31-2020
USS Nantucket (LCS-27)
10-09-2019
USS Beloit (LCS-29)
07-22-2020
USS Cleveland (LCS-31)
06-20-2021
Freedom Variant Littoral Combat Ships enter the water in a pretty unique way
The U.S. Navy and Raytheon Missiles & Defense, a Raytheon Technologies business, completed a series of tests on the Enterprise Air Surveillance Radar (EASR) at the Navy’s Wallops Island Test Facility in Virginia. The tests validated the performance of EASR’s two variants: the SPY-6(V)2 rotating and SPY-6(V)3 fixed-face radars.
SPY-6 radar under test at Wallops Flight Facility, Virginia
The two EASR radars are the newest sensors in the SPY-6 family. SPY-6(V)2 and SPY-6(V)3 provide simultaneous anti-air and anti-surface warfare capabilities, including detecting and tracking uncrewed aerial vehicles, electronic protection, and air traffic control for aircraft carriers and amphibious warfare ships.
«EASR development is progressing rapidly because our engineers are applying knowledge they’ve gained from the SPY-6 family», said Kim Ernzen, vice president of Naval Power at Raytheon Missiles & Defense. «SPY-6’s common architecture saves time and money, and it streamlines training and logistics across software and hardware systems».
The recent tests concentrated on anti-air warfare, air traffic control operations and power system modeling for SPY-6(V)2 and SPY-6(V)3 radars. EASR will replace single-function legacy radars, improving range and performance.
«EASR has proven it performs in high-clutter and dense tracking environments», said Captain Jason Hall, Above-Water Sensors program manager at the Navy’s Program Executive Office for Integrated Warfare Systems. «Teams continue to improve and enhance the system, and will integrate the radar with the combat management system using land-based testing».
The AN/SPY-6(V)2 will be installed on amphibious assault ships and Nimitz class carriers. The AN/SPY-6(V)3 will be incorporated on Ford class aircraft carriers and is compatible with frigates for international navies. AN/SPY-6(V)3 will be a centerpiece of the U.S. Navy’s new Constellation class frigates (FFG 62).
Raytheon Missiles & Defense and the U.S. Navy completed engineering and manufacturing developmental testing for EASR in March 2020. In July 2020, the Navy awarded the company a $126 million contract to produce four SPY-6(V)2 rotators and two SPY-6(V)3 fixed-faced radars.
Huntington Ingalls Industries (HII) announced today that it is making significant progress in the compartment and systems construction of the aircraft carrier USS John F. Kennedy (CVN-79).
Newport News Shipbuilding division is progressing through construction of the aircraft carrier USS John F. Kennedy (CVN-79) turning over more than 500 of the total 2,615 compartments, including the machine room which is one of the larger spaces. The completed spaces allow sailors to begin training on the ship while final outfitting and testing continues
Newport News Shipbuilding division recently eclipsed the 20% mark on compartment completion, turning over to the ship’s crew more than 500 of the total 2,615 spaces. It also has installed more than 8 million feet/2,438,400 m of cable – or more than 1,500 miles/2,414 km – of the approximately 10.5 million feet/3,200,400 m of cable on Kennedy.
The most recently completed spaces include berthing, machinery and electrical. This allows sailors assigned to the pre-commissioning unit to continue training on the ship while final outfitting and testing progresses.
«We are pleased with the progress being made on Kennedy», said Lucas Hicks, vice president of the USS Gerald R. Ford (CVN-78) and USS John F. Kennedy (CVN-79) aircraft carrier programs. «We are in the very early stages of systems testing, and look forward to successfully executing our work on equipment, systems and compartments that brings us closer to delivering the ship to the fleet».
Kennedy is more than 80% complete overall, and is scheduled to be delivered to the U.S. Navy in 2024.
General Characteristics
Builder
Huntington Ingalls Industries Newport News Shipbuilding, Newport News, Virginia
According to Naval News, India’s Indigenous Aircraft Carrier 1 (IAC 1) INS Vikrant sails for her maiden sea trials on August 4, 2021. She will be India’s second aircraft carrier joining the Russian built INS Vikramaditya.
India’s New Aircraft Carrier INS Vikrant Starts Sea Trials
Indigenous Aircraft Carrier (IAC) ‘Vikrant’ designed by Indian Navy’s Directorate of Naval Design (DND) is being built at Cochin Shipyard Limited (CSL), a Public Sector Shipyard under Ministry of Shipping (MoS). IAC is a leading example of the nation’s quest for «Atma Nirbhar Bharat» with more than 76% indigenous content. This is the maiden attempt of the Indian Navy and Cochin Shipyard to indigenously design and build an Aircraft Carrier.
The Indigenous Aircraft Carrier is 262 m/860 feet long, 62 m/203 feet at the widest part and height of 59 m/194 feet including the superstructure. There are 14 decks in all, including five in the superstructure. The ship has over 2,300 compartments, designed for a crew of around 1700 people, including specialised cabins to accommodate women officers. The ship has been designed with a very high degree of automation for machinery operation, ship navigation and survivability, ‘Vikrant’ has a top speed of around 28 knots/32 mph/52 km/h and cruising speed of 18 knots/21 mph/33 km/h with an endurance of about 7,500 nautical miles/8,631 miles/13,890 rm. The ship can accommodate an assortment of fixed wing and rotary aircraft.
Most of the ship construction activities have been completed and the ship has entered the trials phase. Readiness of ship’s Propulsion and Power Generation equipment/systems was tested in harbour as part of Basin Trials in November 2020. Progress of construction of the Carrier was reviewed by Hon’ble Raksha Mantri during his visit to the ship on 25 June 2021. Though the commencement of Sea Trials was delayed due to the 2nd wave of COVID, with concentrated and dedicated efforts of large number of workmen, OEMs, engineers, overseers, inspectors, designers and the ship’s crew, who had put their heart and soul towards the ship’s readiness for sea trials. This is a major milestone activity and historical event. Reaching this milestone is significant as they have been achieved barring the current pandemic challenges and imponderables. During the maiden sailing, ship’s performance, including hull, main propulsion, PGD and auxiliary equipment would be closely watched.
With the delivery of IAC, India would join a select group of nations with the capability to indigenously design and build an Aircraft Carrier, which will be a real testimony to the ‘Make in India’ thrust of the Indian Government.
The Indigenous construction of Aircraft Carrier is a shining example in the Nation’s quest for ‘Atma Nirbhar Bharat’ and ‘Make in India Initiative’. This has led to growth in indigenous design and construction capabilities besides development of large number of ancillary industries, with employment opportunities for 2000 CSL personnel and about 12 000 employees in ancillary industries. Over 76% indigenous content towards procurement of equipment, besides work by CSL and their subcontractors is being directly invested back into the Indian economy. Around 550 Indian firms including about 100 MSMEs are registered with CSL, who are providing various services for construction of IAC.
Indian Navy’s ship building programme is rightly poised to provide requisite ‘Economic Stimulus’, with 44 ships & submarines on order being built indigenously.
Bell Textron Inc., a Textron Inc. company, announced on August 2, 2021 the unveiling of design concepts for new aircraft systems for military applications which would use Bell’s High-Speed Vertical Take-Off and Landing (HSVTOL) technology as the company continues its innovation of next generation vertical lift aircraft. HSVTOL technology blends the hover capability of a helicopter with the speed, range and survivability features of a fighter aircraft.
Bell Unveils New High-Speed Vertical Take-Off and Landing Design Concepts for Military Application
«Bell’s HSVTOL technology is a step change improvement in rotorcraft capabilities», said Jason Hurst, vice president, Innovation. «Our technology investments have reduced risk and prepared us for rapid development of HSVTOL in a digital engineering environment, leveraging experience from a robust past of technology exploration and close partnerships with the Department of Defense and Research Laboratories».
Bell’s HSVTOL design concepts include the following features:
Low downwash hover capability;
Jet-like cruise speeds over 400 kts/460 mph/741 km/h;
True runway independence and hover endurance;
Scalability to the range of missions from unmanned personnel recovery to tactical mobility;
Aircraft gross weights range from 4,000 lbs./1,814 kg to over 100,000 lbs./45,359 kg
Bell’s HSVTOL capability is critical to future mission needs offering a range of aircraft systems with enhanced runway independence, aircraft survivability, mission flexibility and enhanced performance over legacy platforms. With the convergence of tiltrotor aircraft capabilities, digital flight control advancements and emerging propulsion technologies, Bell is primed to evolve HSVTOL technology for modern military missions to serve the next generation of warfighters.
Bell has explored high-speed vertical lift aircraft technology for more than 85 years, pioneering innovative VTOL configurations like the X-14, X-22, XV-3 and XV-15 for NASA, the U.S Army and U.S. Air Force. The lessons learned from the XV-3 and XV-15 supported the development of the Bell-Boeing V-22 Osprey tiltrotor, an invaluable platform that changed the way the U.S. military conducts amphibious assault, long range infiltration and exfiltration and resupply with a cruise speed and range twice that of helicopters it replaced.
The Air Force Research Laboratory’s (AFRL) Directed Energy Directorate is seeking partners to build a new counter electronics weapon system, to defend against the ever increasing threat of adversarial drone activity.
An artist’s rendering of the Air Force Research Laboratory’s THOR, a drone killer, capable of downing many adversarial drones in fractions of a second. A follow-on system named Mjolnir, the hammer belonging to the mythical Norse God, Thor will soon be under development at AFRL (Courtesy illustration)
Building upon the success of the Tactical High-Power Operational Responder (THOR) technology demonstrator, AFRL is building an advanced High-Power Microwave (HPM) weapon system to bring their newest technology to bear against the growing threat from unmanned aircraft.
«The new prototype will be called Mjolnir, after the mythical Norse god, Thor’s hammer», said Amber Anderson, THOR program manager. «Because THOR was so successful, we wanted to keep the new system’s name in the THOR family».
The AFRL team working from Kirtland Air Force Base are experts in High-Power Electromagnetics technology. The THOR demonstrator used bursts of intense radio waves to disable small Unmanned Aircraft Systems (sUAS) instantly.
«After a successful 2-year testing campaign, the AFRL team has learned a lot about the benefits of the technology and how it can be improved», Anderson said.
The Mjolnir prototype will use the same technology, but will add important advances in capability, reliability, and manufacturing readiness.
«We are releasing an opportunity for businesses in the directed energy field, to help us build the follow-on system», said Adrian Lucero, THOR deputy program manager. «AFRL’s goal is to create a blueprint for our partners so these systems can be economically produced in large quantities, and to grow a fledgling industry that will become critically important as the U.S. strives to maintain our electromagnetic spectrum superiority».
AFRL is working closely with cross-service partners in the Joint Counter sUAS Office and the Army’s Rapid Capability and Critical Technologies Office.
«As the danger from drone swarms evolves, all services are working closely to ensure emerging technologies like Mjolnir, will be ready to support the needs of warfighters already engaged against these threats. The program will begin this fall with a delivery of the prototype weapon in 2023», said Lucero.
A request for proposal from companies interested in working with AFRL to develop this prototype will be posted on SAM.gov, an official site for companies seeking federal contract opportunities.
The U.S. Navy has successfully completed the first live fire of the Northrop Grumman Corporation AGM-88G Advanced Anti-Radiation Guided Missile Extended Range (AARGM-ER) from a U.S. Navy F/A-18 Super Hornet. The test was conducted on July 19 at the Point Mugu Sea Range off the coast of southern California. The missile successfully demonstrated the long range capability of the new missile design.
Northrop Grumman’s Advanced Anti-Radiation Guided Missile Extended Range Completes First Successful Missile Live Fire
«The AARGM-ER was successfully launched from the F/A-18 Super Hornet aircraft and met the key test objectives of a first missile live fire event. The government and industry team had great focus and was able to conduct this test event three months earlier than originally envisioned», said Captain A.C. «Count» Dutko, Navy Program Manager for Direct Time Sensitive Strike (PMA-242).
AARGM-ER leverages AARGM with significant improvements in some technology areas.
«Throughout the Engineering and Manufacturing Development phase, Northrop Grumman has demonstrated the ability to deliver this affordable, time-critical capability that will protect and enhance the capability of our U.S. Navy aircrew», said Gordon Turner, vice president, advanced weapons, Northrop Grumman. «Congratulations to the collective Government-Industry team for another successful milestone bringing AARGM-ER one step closer to operational fielding».
AARGM-ER is being integrated on the Navy F/A-18E/F Super Hornet and EA-18G Growler aircraft as well as the Air Force F-35A Lightning II, Marine Corps F-35B Lightning II, and Navy and Marine Corps F-35C Lightning II aircraft.
But if remotely piloted aircraft have made themselves irreplaceable, they also can’t stop evolving.
Artist rendering of GA-ASI’s new Sparrowhawk Small UAS (SUAS), launched from an MQ-9B SkyGuardian in the distance. The Sparrowhawk is one of many GA-ASI investments in SUAS
One reason is that not every combat environment will be as friendly as the skies over Afghanistan and Iraq, where U.S. and allied aircraft enjoyed supremacy. For another, the jobs that commanders need done grow more complex by the year.
The good news is that GA-ASI is keeping ahead of those needs. Our newest technologies enable capabilities that no remotely piloted aircraft ever had before. They’re joining the hunt for hostile submarines under the ocean’s surface and releasing defensive countermeasures to protect themselves from enemy fire, just like a human-crewed fighter.
The MQ-9B SkyGuardian and variants also can integrate into a nation’s civil airspace in a way no remotely operated aircraft ever could before, vastly improving the way users can add these aircraft to their surveillance or other operations. The ability to fly the MQ-9B in and among normal British air traffic was one reason why it was selected to be the new platform of choice by the Royal Air Force: The Protector.
Our remotely piloted aircraft can even accommodate their own, small unmanned aerial systems, often known simply as SUAS. If the past 20 years has brought the golden age of large UAS, the coming 20 years will represent the evolution of their little brothers.
For example, GA-ASI has developed one game-changing SUAS known as Sparrowhawk, which an aircraft such as the MQ-9 can carry under its wing as it might a traditional payload like a sensor pod or a fuel tank. But when the MQ-9 reaches an area of interest on a mission, it can do something few remotely operated aircraft have ever done – launch the smaller UAS and then recover it in mid-flight.
The smaller, nimbler, swifter Sparrowhawk is difficult for an adversary to spot as it sprints low along its route. It does, via connection to its big brother, what remotely operated aircraft have been doing all along: Sends back vital information about what’s taking place, without the cost and risk of involving a human aircrew.
The Sparrowhawk might surveil an area and turn back to rendezvous with the aircraft that launched it. In a safe area, well away from hostile warplanes or anti-air systems, the larger UAS can snatch the Sparrowhawk out of the sky and continue its mission.
Once Sparrowhawk is secure, the larger aircraft can return to base – or, relying on its ability to stay aloft for many hours, continue its patrol and even launch another Sparrowhawk elsewhere later from its other wing station.
Integrating smaller aircraft with larger unmanned aircraft is possible in part thanks to advances in autonomy and multi-aircraft control pioneered by GA-ASI. As ever, the absence of human pilots on these aircraft means commanders can consider using them in ways they would never employ traditional fighters.
A SkyGuardian could release a Sparrowhawk with the intention of searching for hostile anti-air systems without needing to worry about the safety of the pilot. Indeed, an air commander’s goal might be to send Sparrowhawk to probe a denied environment so that it could report back about the radar or other systems that powered on or detected it – where they were, what type, and how many.
Sparrowhawk could respond with an electronic attack of its own to clear the way for other aircraft coming in behind it, jamming an enemy radar to deny its ability to sense a strike package passing through the area. Or the small aircraft could support missions focused on the suppression of enemy air defenses.
Small UAS will take the concept of unmanned aerial combat to new levels, with new capabilities like our Sparrowhawk and others leading the way in distributed aerial networking and joint, all-domain command and control. But SUAS won’t only help friendly forces deal with threats on the ground.
Artist’s rendering of a new SUAS prototype from GA-ASI, shown here operating from an MQ-1C Gray Eagle and teaming with U.S. Army rotorcraft to support stand-in jamming, suppression of enemy air defenses, artillery missions and more
Another small system in the works by GA-ASI will help clear the way through the skies. LongShot, being developed under a contract from DARPA, will launch from larger UAS or human-crewed aircraft and charge into hostile airspace armed with its own air-to-air missiles, able to fire on enemy targets if it were so commanded.
LongShot gives commanders options, just as all remotely operated systems always have. It could initiate a fighter sweep ahead of a strike wave without putting a human crew in danger, or it could join an attack alongside the vanguard with human-crewed warplanes.
Artist rendering of GA-ASI’s new LongShot SUAS, currently in development with DARPA
LongShot also could give legacy aircraft such as bombers a potent new anti-air capability. Imagine if a friendly bomber were en route during a combat mission and allied battle networks detected the approach of hostile fighters. LongShot would let the bomber crew go on offense against the threat without the need for its own escorts or the retasking of friendly fighters, preserving its ability to service its targets as planned.
Airpower, naval and ground warfighters doubtlessly will find other new ways to incorporate these new systems into their missions, as troops always have with novel weapons that give them more options and flexibility.
Those pilots, air crews, squadrons and other units are the latest links in a chain that goes back decades. From unpowered contraptions of wood and fabric to sophisticated warplanes that can launch and recover their own smaller squadrons, remotely piloted aircraft have made incredible progress since the days of William Eddy and his camera kites. And with stealthier and advanced new programs in the works, including some in support of the Air Force’s MQ-Next concept, there’s a great deal more to come.
What won’t change is their utility and indispensability from today’s and tomorrow’s military, security, governance and environmental protection operations, with an ever-growing suite of missions beyond those for which they were originally designed.
That, too, is something Eddy himself discovered following his return to New Jersey, when he found that thieves had stolen a batch of ice cream from his back porch.
As one local history records, Eddy reeled out his aerial surveillance kite and captured some images of the area: «One shot showed two men eating ice cream under a tree near Newark Bay. Eddy said he later found his ice cream box under the tree».
The U.S. Navy conducted its first test flight of the MQ-4C Triton in its upgraded hardware and software configuration July 29 at Naval Air Station (NAS) Patuxent River, beginning the next phase of the unmanned aircraft’s development.
U.S. Navy Conducts First MQ-4C Triton Test Flight with Multi-Intelligence Upgrade
The MQ-4C Triton flew in its new configuration, known as Integrated Functional Capability (IFC)-4, which will bring an enhanced multi-mission sensor capability as part of the Navy’s Maritime Intelligence, Surveillance, Reconnaissance and Targeting (MISR&T) transition plan.
Triton’s Integrated Test Team (ITT) comprised of the U.S. Navy, Australian cooperative partners, and government/industry teams completed a functional check flight and initial aeromechanical test points, demonstrating stability and control of the MQ-4C after a 30-month modification period.
«Today’s flight is a significant milestone for the program and a testament to the resolve of the entire ITT, their hard work, and passion for test execution and program success», said Captain Dan Mackin, Persistent Maritime Unmanned Aircraft Systems program manager. «This flight proves that the program is making significant progress toward Triton’s advanced multi-intelligence upgrade and it brings us closer to achieving the Initial Operational Capability (IOC) milestone».
Multiple Triton assets have been modified into the IFC-4 configuration in support of IOC in 2023. A single test asset is in the current IFC-3 configuration to support sustainment of deployed systems as well as risk reduction for IFC-4.
Currently, two MQ-4C Triton aircraft in the baseline configuration known as IFC-3 are forward deployed to 7th Fleet in support of Early Operational Capability (EOC) and Commander Task Force (CTF)-72 tasking. Unmanned Patrol Squadron 19 (VUP-19) will operate Triton to further develop the concept of operations and fleet learning associated with operating a high-altitude, long-endurance system in the maritime domain.
«The MQ-4C Triton has already had a tremendous positive impact on operations in United States Indo-Pacific Command (USINDOPACOM) and will continue to provide unprecedented maritime intelligence, surveillance and reconnaissance capabilities which are especially critical to national interests with the increased focus in the Pacific», Mackin said.
Triton is the first high altitude, long endurance aircraft that can conduct persistent Intelligence, Surveillance and Reconnaissance (ISR) missions to complement the P-8 in the maritime domain. The Navy plans to deploy Triton to five orbits worldwide.
General Characteristics
Primary Function
Persistent Maritime ISR
Builder
Northrop Grumman
Propulsion
Rolls-Royce AE3007H
Endurance
24 + hours
Length
47.6 feet/14.5 meters
Wingspan
130.9 feet/39.9 meters
Height
15.4 feet/4.7 meters
Speed
320 knots/368 mph/593 km/h
Crew
Five per ground station (Air Vehicle Operator, Tactical Coordinator, 2 Mission Payload Operators, SIGINT coordinator)
