Sunday, May 29, 2016

Australians stop looking down for VOR/DME, look up for GNSS

Performance Based Navigation 2014 Booklet v4.pdf
Australia begins decommissioning navaids; moves to satellite navigation | Air Traffic Management content from ATWOnline
Australia has begun the process of decommissioning a number of ground-based navigation aids, meaning that associated non-precision approach procedures will be withdrawn from service this week. On May 26, the process was initiated to switch off 179 navigation aids, including non-directional beacons (NDBs), VHF omni-directional radio ranges (VORs) and distance measuring equipment (DMEs) as part of the Airservices Navigation Rationalization Project

Aviation Business: Editor's Insights
Starting today, Airservices Australia will begin switching off 179 ground based navigation aids such as Distance Measuring Equipment (DME), Non Directional Beaons (NDBs) and VHF Omnidirectional Range (VOR) beacons.
From now on aircraft will look up at Global Navigation Satellite System (GNSS) satellites for Instrument Flight Rules (IFR) guidance, not down at ground based aids. Airservices will no longer need to maintain the mechanical devices across Australia, some of which entered service in 1962.

Related/Background:

Saturday, May 21, 2016

Google’s Project Soli demo's mmw micro-radar wearable HMI


Google built a tiny radar system into a smartwatch for gesture controls | The Verge
"If you can put something in a smartwatch, you can put it anywhere," Poupyrev says. So ATAP redesigned the Soli chip to make it smaller and draw less power. And then it redesigned it to do the same thing again. And again. Finally, according to Hakim Raja, Soli's lead hardware and production engineer, the team created the tiniest of the chips you see above. It's a tiny sliver you could balance on your pinky toenail, with four antennas that provide full duplex communication for sending and receiving radar pings. The first iteration of Soli, which shipped to in a development kit, drew 1.2w of power. This one draws 0.054w, a 22x reduction.
But making a chip that tiny has drawbacks. Radar was designed to detect massive flying metal objects from miles away, not tiny millimeter movement from your fingers inches away. Until very recently, nobody bothered worrying about the power draw at this scale and nobody had to deal with figuring out what the signal would even look like when it was shrunk down this small.
Jaime Lien is the lead research engineer for Soli, and it's her job to tune the machine learning algorithms which ultimately get hardwired into the chip. Her first realization was that it made sense to convert the spatial signal radar provides into a temporal one that makes more sense on a computer. But that was nothing compared to noise problems you run into at these tiny scales. She showed me the "glitch zoo," a huge set of screenshots of every kind of impenetrable noise that her algorithms have to find signal in. At these scales, it's impossible to do any sort of beam forming and the very electrons running through the chip have to be accounted for.

Related/Background:

Wednesday, May 18, 2016

LinkedIn Passwords Posted Online

BREAKING: 100M LinkedIn Emails, Passwords From 2012 Hack Posted Online - Law360
By Allison Grande
Law360, New York (May 18, 2016, 12:33 PM ET) -- LinkedIn said Wednesday that more than 100 million email and password combinations believed to have been compromised in a 2012 data breach have recently been posted online, expanding the fallout from a data theft that resulted in a separate set of 6.5 million passwords being publicly released four years ago.

The data breach first grabbed headlines in 2012, when LinkedIn Corp. revealed that a file containing more than 6.46 million hashed passwords that allegedly belonged to LinkedIn users were posted to a Russian “hacker website.”... 

LinkedIn Data Breach: 117 Million Emails and Passwords Leaked - Fortune

Much more than the 6.5 million originally thought.

Remember LinkedIn’s 2012 data breach?
A hacker stole 6.5 million encrypted passwords from the site and posted them to a Russian crime forum. Now it appears that data theft was just the tip of the iceberg.
A Russian hacker, who goes by “Peace,” is selling 117 million email and password combinations on a dark web marketplace, Vice Motherboard reports. The going rate for the loot is five Bitcoins, or about $2,300.




Monday, May 16, 2016

Army seeks small counter UAV&bullet radar concepts for CROWS

CROWS
Small Form Factor, Tactical Fire Control Radar - Federal Business Opportunities: Opportunities
Synopsis:
Added: May 12, 2016 8:54 am

INTRODUCTION:

The U.S. Army Contracting Command (ACC) - New Jersey, in support of the Armament Research, Development, and Engineering Center (ARDEC), is conducting a market survey to understand industry capability to provide a radar capable of generating fire-control quality data, enabling the kinetic defeat of small aerial targets. This requires tracking small Radar Cross Section (RCS) aerial targets and kinetic rounds (e.g. bullets). The radar would be vehicle mounted, small, lightweight, affordable, and be suitable for stationary and on-the-move operations.

As a result of issuing this Request for Information (RFI), the Government expects to receive white papers describing proposed concepts and technologies. The RFI responses should identify radar designs that will support the ARDEC system concept and include a credible development path, with estimates provided on costs and timeline.

SYSTEM OVERVIEW:

ARDEC has developed a system of systems concept to address low flying, small RCS aerial threats in support of maneuver forces. This system is comprised of Unmanned Aerial Systems (UAS) detection and tracking sensors being networked to defeat mechanisms such as the Common Remotely Operated Weapon Station (CROWS).

A component of this overarching concept, and the subject of this RFI, is a tactical fire control radar. Initially, ARDEC is seeking a tactical fire control radar capable of:
  • Detecting and tracking Group 1 UAS.
  • Capable of integration onto a vehicle-mounted CROWS.

Other UAS categories and other threats are of interest, but are not the focus of this RFI. The tactical fire control radar will provide target engagement data to an on-board fire control system for a weapon system, as well as track outgoing projectiles for purposes of increasing the accuracy of the on-board weapon. It is envisioned that the system will ultimately have a full, on-the-move capability. In the near-term, the system may operate in a stationary configuration.

REQUIREMENTS:

ARDEC envisions an incremental, evolutionary approach to system development, culminating in a system that has 360 degree azimuth coverage and on-the-move capability. Initial efforts will focus on a near-term demonstration of specific parameters. Requirements for the near-term demonstrator and the long-term capability are listed below.

Near-Term Demonstrator:

Threshold Requirements

  • Ability to simultaneously search to a range of 3km, track one or more hovering and/or maneuvering Group 1 UAS, and track outbound projectiles used for engagement.
  • Update rate and accuracy measurements in search mode should be sufficient to initiate track at 1.5km.
  • Track Group 1 UAS threat at range of 50m to 1.5km with accuracy requirements ≤750 microradian angular accuracy, ≤1m range accuracy, and ≥20Hz update rate.
  • Must be able to track an outbound .50 caliber round for the purpose of increasing accuracy. For modelling and performance prediction purposes, the .50 caliber munition can be treated as having the RCS of a 1.5cm conducting sphere.
  • Must detect and track both rotary and fixed wing Group 1 UAS. Group 1 is defined as <20lbs 100="" a="" above="" and="" are="" at="" class.="" feet="" ground="" in="" knots.="" level="" li="" lift-off="" of="" operating="" raven="" representative="" rq-11="" speed="" the="" this="" to="" u.s.="" uass="" up="" wasp="" with="">
  • Angular radar coverage should be +/- 45 degree azimuth (aligned on weapon boresight) with an elevation coverage of -20 to 60 degrees. Weapon boresight can be directed to any fixed azimuth position across 360 degrees, at the discretion of the operator.
  • Must be able to accept real-time search-quality external cues.
  • Must communicate target data to an external system in real-time.
  • System must be integrated onto a vehicle-mounted CROWS. The radar front-end receive and transmit antenna assembly must be integrated onto the CROWS, with or without the radar signal/data processor, which may be installed elsewhere in or on the vehicle. The CROWS common interface can support up to approximately 65lb weight and 29in maximum width.
  • Must be operable on Stryker power.
  • Must be air cooled.

Objective Requirements (Objectives exceeding thresholds noted in Bold font)


  • Ability to simultaneously search to a range of 5.5km, track 10 Group 1 UAS, and track outbound projectiles used for engagement.
  • Track Group 1 UAS threat at a range of 50m to 2.5km with accuracy requirements ≤400 microradian angular accuracy, ≤1m range accuracy, and ≥20Hz update rate.
  • Angular radar coverage should be +/- 45 degree azimuth (aligned on weapon boresight) with an elevation coverage of -20 to 90 degrees.
  • Demonstrate ability for the system to operate on-the-move. This capability can be demonstrated in a tiered approach, initially search on the move, and ultimately track-while-search.

Related/Background:

Saturday, May 14, 2016

First US Navy Zumwalt Destroyer to call San Diego Home when trials complete

Futuristic US Navy Zumwalt Destroyers to be Deployed to the Pacific Facing China : Science : Chinatopix
The first ship of this class, the USS Zumwalt (DDG-1000), successfully underwent a series of hull, mechanical and engineering (HM&E) trials to uncover bugs in its first-of-its-kind Integrated Propulsion System. This system generates 80,000 megawatts, more than enough power to fire an electromagnetic railgun.

Once other sea trials are successfully completed, the USS Zumwalt will head for the Pacific Ocean to complete the activation of its combat systems. The destroyer will be home-ported at Naval Base San Diego in California, principal homeport of the United States Pacific Fleet consisting of 50 ships.
The Pacific Fleet has command over the U.S. Navy Third Fleet defending the West Coast and the Seventh Fleet in Asia.

NAVAIR RFI for Radar algorithm source alternative to Compass Systems

Aircraft and Laboratory Systems Sensor Development and Integration - Federal Business Opportunities: Opportunities

THIS IS A REQUEST FOR INFORMATION ONLY. THERE IS NO SOLICITATION PACKAGE
AVAILABLE. The following information is provided to assist the Naval Air Warfare Center Aircraft Division (NAVAIR) Lakehurst, NJ in conducting market research of industry to identify if there are alternate options to meet USN needs for applied research development and testing of new radar algorithms for the APY-10 and APG-79 radars. This effort includes research of emerging technologies related to the radar technologies including correlation with other sensor systems to improve identification confidence and aide in classification of targets. This contracting effort will result in the delivery of an integrated control and test system with multiple node access. In addition, integration of the systems onboard the test aircraft is required.
 

At this time, pending market research results, NAVAIR Lakehurst, NJ intends to negotiate on a non-competitive basis with Compass Systems Inc. of Lexington Park, Md for the required research and development.   Compass Systems is the sole designer, developer and provider of key components of the software system which is crucial to the continued development of several radar systems the Navy already is using  operationally.

Friday, May 13, 2016

Forward Homeporting of IAMD Naval Muscle - Maintain and Use it or Lose It, it's not cheap

The Arleigh-Burke class guided-missile destroyer, USS Benfold (DDG 65) returns to homeport San Diego after completing a seven-month, independent deployment to the 7th Fleet Area of Responsibility. (U.S. Navy photo by Mass Communication Specialist 2nd Class Rosalie Garcia/Released)
Navy Matters: You Can't Surge A Modern Navy
In recent years, in response to budget constraints, there has been discussion of homeporting major elements of the Navy and simply surging them, if needed. The claimed benefits include reduced physical wear on the ships since they would remain docked most of the time, reduced manpower requirements since the ships would need nothing more than a caretaker crew, and reduced operating costs due to the reduced crew and curtailed deployments.
This was simply an examination of the concept of homeporting/surging a fleet. Properly done, it has some advantages but it also comes with disadvantages. However, done as the Navy and many supporters would have it, a modern Navy cannot be surged and the Navy is unintentionally proving it right now. 

U.S. Navy’s Overseas Force Structure Changes
Navy Moving Two Additional BMD Destroyers To Japan - USNI News
The U.S. Navy announced today that the ballistic missile defense (BMD)-capable guided missile destroyer USS Benfold (DDG 65) and USS Milius (DDG 69) will become part of the Forward Deployed Naval Forces (FDNF) based at Commander Fleet Activities Yokosuka, Japan.
As part of the U.S. Navy’s long-range plan to put the most advanced and capable units forward, Benfold and Milius will leave their current homeport of San Diego and forward deploy to Yokosuka in the summers of 2015 and 2017, respectively. The move directly supports the announcement made by Secretary of Defense Chuck Hagel in April of this year that the Navy would commit to sending two additional BMD-capable ships to the defense of Japan by 2017.

The Next Act for Aegis - USNI News
Aside from the success of the BMD missions, the Aegis program made the most headlines due to problems in the force.
The 2010 final report of the Fleet Review Panel of Surface Force Readiness (short-handed as the Balisle Report, after panel leader, retired Vice Adm. Philip Balisle) found the condition of the Aegis systems fleet wide suffering due to lack of parts, training and lack of qualified personnel.
“That was the biggest klaxon at the time and that brought everyone’s focus to bear,” Kilby said.
In 2011, the Navy kicked off the Aegis wholeness project and four years after the Balisle report, the Navy claims the day-to-day Aegis woes are largely behind them.
What remains to be seen is how well the Navy can integrate the new surface capabilities into the fleet.
“We are entering for the first time into the world of integrated air and missile defense,” Kilby said.
“Let’s get good at it.”

U.S. GAO - Navy Force Structure: Sustainable Plan and Comprehensive Assessment Needed to Mitigate Long-Term Risks to Ships Assigned to Overseas Homeports
Homeporting ships overseas considerably increases the forward presence— U.S. naval forces in overseas operating areas—that the Navy's existing fleet provides and has other near-term benefits such as rapid crisis response, but incurs higher operations and support costs when compared to U.S.-homeported ships. GAO found that casualty reports—incidents of degraded or out-of-service equipment—have doubled over the past 5 years and that the material condition of overseas-homeported ships has decreased slightly faster than that of U.S.-homeported ships (see figure below). In addition, the Navy has spent hundreds of millions of dollars on overseas infrastructure and base operating costs since 2009, while moving large numbers of sailors, dependents, and ship repair work overseas. GAO also found that the high pace of operations the Navy uses for overseas-homeported ships limits dedicated training and maintenance periods, which has resulted in difficulty keeping crews fully trained and ships maintained.

Assessment of Surface Ship Maintenance Requirements | RAND

A comparison between the cumulative maintenance levels for the DDG-51 and the levels specified in the Navy's technical foundation papers showed that the Navy is not in general funding to the level as stated in the technical foundation papers. This casts doubt on the validity of the technical foundation papers' requirements and the Navy's commitment to carrying out the maintenance stated in these published papers. Given this, the Navy will need to consider alternatives to the technical foundation papers' process as it formulates requirements and source plans.

Ships of similar age and operating histories whose major difference is basing histories, e.g., foreign homeporting — with the attendant effects on maintenance — can show dramatic differences between the overall costs to maintain. Maintenance deferrals exact an extremely high premium that drives ship cost up in ways inconsistent with the need to contain costs. Any maintenance construct needs to understand and budget for the high cost of deferral or devise mitigations for cases where deferral is inevitable.

Related/Background:

Thursday, May 12, 2016

GA-ASI team provides Iraqi Air Force King Air 350ER ISR with SAR/GMTI and EO/IR Sensors

صورة
General Atomics Aeronautical Systems Awarded Iraqi Air Force Intelligence Surveillance and Reconnaissance Contract
$53 Million Order Received For Manned ISR Aircraft and Ground Stations
SAN DIEGO – 11 June 2007 – General Atomics Aeronautical Systems, Inc. (GA ASI), a leading manufacturer of unmanned aircraft systems (UAS) and tactical reconnaissance radars, today announced that it has received notification of an award of a $53 million ceiling price order from Raytheon Aircraft Company of Wichita, Kan., to provide an initial lot of five integrated Intelligence Surveillance and Reconnaissance (ISR) suites for the company’s Beechcraft King Air 350ER (Extended Range) aircraft and related ground stations to be supplied to the Iraqi Air Force under the U.S. Government’s Foreign Military Sales (FMS) program.
Under the terms of the contract, the GA-ASI team – which consists of L-3 Communications West, L-3 EO/IR Inc., and Exclusive Charter Services – will provide airborne payloads and operator workstations (which run CLAW® sensor control and analysis software), as well as fixed, mobile and man-transportable data linked ground stations, support equipment, and training and logistics support.
“This program for Iraq represents a total end-to-end airborne ISR solution,” said Linden P. Blue, president, Reconnaissance Systems Group, General Atomics Aeronautical Systems, Inc. “It integrates the airborne payload package with an operator console station that collects, formats, and displays sensor data for optimum exploitation. Imagery and exploitation products can then be sent via an airborne data link to ground stations for further analysis. This equipment will increase current Iraqi Air Force airborne reconnaissance and intelligence collection capabilities significantly.”
The GA-ASI team will equip modified Beechcraft King Air 350ER aircraft that will be used by the Iraqi Air Force as it assumes greater control of the ISR mission within the country. Each ISR aircraft will include a Lynx® IIE SAR/GMTI radar, MX-15i Electro-Optical/Infrared (EO/IR) camera system, CLAW software, and a high-bandwidth data link system.
GA-ASI Successfully Passes ATP Testing of First Iraqi Air Force ISR Aircraft and Ground Station
The IqAF ISR ATP consisted of a series of test flights demonstrating the sensor and communications equipment aboard the modified Beechcraft King Air 350 Extended Range (ER) aircraft, including the L-3 Communications Wescam MX-15i electro-optical/infrared (EO/IR) turret, L-3 Communications West mini-T series airborne data link, Exclusive Charter Services tailored sensor operator consoles, and GA-ASI CLAW® integrated sensor software.  The GA-ASI Lynx® II synthetic aperture radar/ground moving target indicator (SAR/GMTI) was demonstrated and will be delivered this month after program modifications are made.
On the ground side, multiple man-transportable laptop video receivers and a fixed ground station (FGS) received real-time ISR data via data link communications from the aircraft from a considerable distance.  The first ground station was shipped to Iraq immediately after testing, and the first aircraft departed for Iraq in late June.
Representing a total end-to-end airborne ISR solution, the equipment will increase current IqAF airborne reconnaissance and intelligence collection capabilities significantly.  GA-ASI assembled and integrated the sensor and communications equipment onto the aircraft operator console station and the fixed ground station at its facilities in San Diego, Calif.  The company recently completed sensor operator and maintenance training for U.S. and Iraqi Air Force operators and contract logistics support (CLS) personnel.

Iraqi Armed Forces Forums منتدى القوات المسلحة العراقية :: مشاهدة الموضوع - KingAir 350ISR
Iraq to get another King Air
Iraq is to get another Hawker Beechcraft King Air 350ER aircraft under a USD7.85 million contract announced by the US Department of Defense (DoD) on 30 June. The contract is expected to be completed by 30 March 2015.

The Iraqi Air Force already operates King Air 350ERs that have been modified into intelligence, surveillance, and reconnaissance (ISR) platforms and one King Air 350 light transport aircraft. The six aircraft were delivered under a USD10.5 million contract announced by the DoD in September 2008 and are based at Baghdad's New al-Muthana Airbase.

Iraq's 350ER-ISR version carries an L-3 Wescam MX-15i electro-optical turret and a GA-ASI Lynx Block 30E synthetic aperture radar/ground moving target indicator.


http://www.janes.com/article/40215/iraq ... r-king-air
http://www.ga-asi.com/products/sensor_s ... ynxsar.php

Lynx® Multi-mode Radar

GA-ASI’s Lynx is a state-of-the-art, lightweight, high-performance, multi-function radar that operates in Synthetic Aperture Radar (SAR) and Ground Moving Target Indicator (GMTI) modes. An all-weather sensor, Lynx provides photographic-quality images through clouds, rain, dust, smoke, and fog, in daylight or total darkness. As a result, Lynx detects time-sensitive targets and changes on the ground that may be undetectable by Electro-optical/Infrared (EO/IR) sensors. Additionally, Lynx’s long-range, wide-area surveillance capability provides high-resolution SAR imagery slant ranges well beyond effective EO/IR range.

Lynx’s broad area GMTI scanning capability detects and tracks moving targets in real-time and cues aircraft EO/IR payloads or ground units for target acquisition and prosecution.

The Lynx Multi-mode Radar sensor continues to be in deployment on manned and Unmanned Aircraft Systems throughout the world. Lynx is utilized by the U.S. Army aboard its Sky Warrior® Alpha and Gray Eagle® UAS, and on a variety of manned aircraft, including the C-12, U-21 and DH-7. Lynx is also utilized by the U.S. Air Force and the Royal Air Force on their MQ-9 Reaper™ UAS; by the U.S. Department of Homeland Security aboard its Predator Bs; and the Italian Air Force on its MQ-9s. Additionally, Lynx is utilized by the Iraqi Air Force aboard its Peace Dragon manned Intelligence, Surveillance, and Reconnaissance (ISR) aircraft.

The Lynx product family currently consists of the AN/APY-8 Block 20 radar (system weight 120 lbs) and the AN/DPY-1 Block 30 radar (system weight < 85 lbs).

Features/Benefits:

  • High-resolution imagery          
  • Long-range, up to 80 km
  • High reliability, enclosed chassis
  • Low weight and volume
  • Real-time detection of vehicular movement
  • Automatic cross-cue to EO/IR
  • Available as a Commercial-Off-The-Shelf (COTS) sensor
  • Designed for use in UAS and manned platforms

Related/Background:

Saturday, May 7, 2016

GA-ASI and NRL add ISAR imaging to Lynx SAR/GMTI Radar on Reaper

GA-ASI Lynx Block 20A Radar Antenna
USAF MQ-9 Reaper UAV by GA-ASI
Polar Reformatting for ISAR Imaging - U.S. Naval Research Laboratory
NRL Invokes Cost Effective Approach to Improve Joint ISR Missions - U.S. Naval Research Laboratory


The U.S. Naval Research Laboratory(NRL) Radar Division has teamed with San Diego-based General Atomics Aeronautical Systems Inc. (GA-ASI) to integrate maritime mode inverse synthetic aperture radar (maritime-ISAR) imaging capability with GA-ASI’s Lynx Multi-Mode Radar deployed on its Unmanned Aerial Systems (UAS).
Intelligence, Surveillance and Reconnaissance (ISR) communities around the world are exploring ways in which different services can collaborate on naval missions. These communities envision UAS capabilities supporting joint warfighter missions over land, and littoral and blue water regions. To achieve this, GA-ASI Mission Systems has expressed interest in adding an ISAR mode to the Lynx Multi-Mode Radar, a standard payload for the USAF MQ-9 Reaper and Predator XP systems.
“Because ships and small watercraft at sea are usually in motion — having both forward velocity and other linear and angular motions, for example, pitch and roll and heave and sway — this creates a problem for typical ISAR platforms,” said Thomas Pizzillo, head, NRL Radar Analysis Branch. “The addition of a maritime-ISAR mode to the General Atomics Lynx radar, as a software only upgrade, is the most cost effective alternative to introduce this capability to the MQ-9 fleet.”
Synthetic Aperture Radar (SAR) is a radar imaging method using multiple pulses transmitted from a moving platform. The received signals are combined to form a high quality two-dimensional (2D) image of the ground-terrain of interest. Classical SAR algorithms assume the target scene (background) is stationary and any motion in the scene shows up as a smear or streak in the image. ISAR algorithms assume the target itself is moving, and through a set of complex algorithms, calculates enhanced angular or cross-range resolution by analyzing subtle differences in range-rates caused by the target motion. The net effect is to focus the image of a moving target without smearing.
“Often with unknown velocities, both linear and angular, it is a much more difficult problem because the motions are not known as in typical ISAR,” Pizzillo says. “NRL has successfully adapted the necessary changes to ISAR image formation in which the rotational motion of the target is not known beforehand. This provides the end-user with an imaging software tool that can produce high-quality imagery in conditions with significantly complex target motion.”

Related/Background:


Synthetic Aperture Radar (SAR) is a radar imaging method using multiple pulses transmitted from a moving platform. The received signals are combined to form a high quality two-dimensional (2D) image of the ground-terrain of interest. Classical SAR algorithms assume the target scene (background) is stationary and any motion in the scene shows up as a smear or streak in the image. ISAR algorithms assume the target itself is moving, and through a set of complex algorithms, calculates enhanced angular or cross-range resolution by analyzing subtle differences in range-rates caused by the target motion. The net effect is to focus the image of a moving target without smearing.
“Often with unknown velocities, both linear and angular, it is a much more difficult problem because the motions are not known as in typical ISAR,” Pizzillo says. “NRL has successfully adapted the necessary changes to ISAR image formation in which the rotational motion of the target is not known beforehand. This provides the end-user with an imaging software tool that can produce high-quality imagery in conditions with significantly complex target motion.”
- See more at: http://www.nrl.navy.mil/media/news-releases/2016/NRL-Invokes-Cost-Effective-Approach-to-Improve-Joint-ISR-Missions#sthash.EJyT6LbF.dpuf
The U.S. Naval Research Laboratory (NRL) Radar Division has teamed with San Diego-based General Atomics Aeronautical Systems Inc. (GA-ASI) to integrate maritime mode inverse synthetic aperture radar (maritime-ISAR) imaging capability with GA-ASI’s Lynx Multi-Mode Radar deployed on its Unmanned Aerial Systems (UAS).
USAF_Reapor_MQ9 Developed for the U.S. Air Force (USAF) through funding by General Atomics Aeronautical Systems Inc. (GA-ASI), the MQ-9 unmanned aerial vehicle (UAV) is designed to execute time-sensitive targets with persistence and precision, and destroy or disable those targets. To expand on its mission and improve joint-service ISR capability, GA-ASI has teamed with the U.S. Naval Research Laboratory to implement an Inverse Synthetic Aperture Radar (ISAR) imaging capability in the GA-ASI’s Lynx Multi Mode Radar currently deployed on UASAF MQ-9 UAVs. (Courtesy U.S. Air Force/Lt. Col. Leslie Pratt) Intelligence, Surveillance and Reconnaissance (ISR) communities around the world are exploring ways in which different services can collaborate on naval missions. These communities envision UAS capabilities supporting joint warfighter missions over land, and littoral and blue water regions. To achieve this, GA-ASI Mission Systems has expressed interest in adding an ISAR mode to the Lynx Multi-Mode Radar, a standard payload for the USAF MQ-9 Reaper and Predator XP systems.
“Because ships and small watercraft at sea are usually in motion — having both forward velocity and other linear and angular motions, for example, pitch and roll and heave and sway — this creates a problem for typical ISAR platforms,” said Thomas Pizzillo, head, NRL Radar Analysis Branch. “The addition of a maritime-ISAR mode to the General Atomics Lynx radar, as a software only upgrade, is the most cost effective alternative to introduce this capability to the MQ-9 fleet.”
Synthetic Aperture Radar (SAR) is a radar imaging method using multiple pulses transmitted from a moving platform. The received signals are combined to form a high quality two-dimensional (2D) image of the ground-terrain of interest. Classical SAR algorithms assume the target scene (background) is stationary and any motion in the scene shows up as a smear or streak in the image. ISAR algorithms assume the target itself is moving, and through a set of complex algorithms, calculates enhanced angular or cross-range resolution by analyzing subtle differences in range-rates caused by the target motion. The net effect is to focus the image of a moving target without smearing.
- See more at: http://www.nrl.navy.mil/media/news-releases/2016/NRL-Invokes-Cost-Effective-Approach-to-Improve-Joint-ISR-Missions#sthash.EJyT6LbF.dpuf
The U.S. Naval Research Laboratory (NRL) Radar Division has teamed with San Diego-based General Atomics Aeronautical Systems Inc. (GA-ASI) to integrate maritime mode inverse synthetic aperture radar (maritime-ISAR) imaging capability with GA-ASI’s Lynx Multi-Mode Radar deployed on its Unmanned Aerial Systems (UAS).
USAF_Reapor_MQ9 Developed for the U.S. Air Force (USAF) through funding by General Atomics Aeronautical Systems Inc. (GA-ASI), the MQ-9 unmanned aerial vehicle (UAV) is designed to execute time-sensitive targets with persistence and precision, and destroy or disable those targets. To expand on its mission and improve joint-service ISR capability, GA-ASI has teamed with the U.S. Naval Research Laboratory to implement an Inverse Synthetic Aperture Radar (ISAR) imaging capability in the GA-ASI’s Lynx Multi Mode Radar currently deployed on UASAF MQ-9 UAVs. (Courtesy U.S. Air Force/Lt. Col. Leslie Pratt) Intelligence, Surveillance and Reconnaissance (ISR) communities around the world are exploring ways in which different services can collaborate on naval missions. These communities envision UAS capabilities supporting joint warfighter missions over land, and littoral and blue water regions. To achieve this, GA-ASI Mission Systems has expressed interest in adding an ISAR mode to the Lynx Multi-Mode Radar, a standard payload for the USAF MQ-9 Reaper and Predator XP systems.
“Because ships and small watercraft at sea are usually in motion — having both forward velocity and other linear and angular motions, for example, pitch and roll and heave and sway — this creates a problem for typical ISAR platforms,” said Thomas Pizzillo, head, NRL Radar Analysis Branch. “The addition of a maritime-ISAR mode to the General Atomics Lynx radar, as a software only upgrade, is the most cost effective alternative to introduce this capability to the MQ-9 fleet.”
Synthetic Aperture Radar (SAR) is a radar imaging method using multiple pulses transmitted from a moving platform. The received signals are combined to form a high quality two-dimensional (2D) image of the ground-terrain of interest. Classical SAR algorithms assume the target scene (background) is stationary and any motion in the scene shows up as a smear or streak in the image. ISAR algorithms assume the target itself is moving, and through a set of complex algorithms, calculates enhanced angular or cross-range resolution by analyzing subtle differences in range-rates caused by the target motion. The net effect is to focus the image of a moving target without smearing.
- See more at: http://www.nrl.navy.mil/media/news-releases/2016/NRL-Invokes-Cost-Effective-Approach-to-Improve-Joint-ISR-Missions#sthash.EJyT6LbF.dpuf

Reaper deploys live weapons on maritime training target

Reaper deploys live weapons on maritime training target > U.S. Air Force > Article Display
NELLIS AIR FORCE BASE, Nev. (AFNS) -- An MQ-9 Reaper successfully hit a sea-going target with an AGM-114 Hellfire missile during a joint service training exercise over the Gulf of Mexico on March 17.

This was the first time a remotely piloted aircraft (RPA) hit a maritime target.

"It was the first time we had put live weapons into boats and participated in maritime (exercises)," said Capt. Timothy Ford, a 26th Weapons Squadron flight commander. "For our (RPA) community it's a big step forward, it's a mission set we had looked at for a long time and training opportunities over water are not very prevalent (at Nellis)."

In addition to this being the first time an RPA squadron hit a maritime target; it was also a chance to integrate with other aircraft including A-10 Thunderbolt IIs, F-16 Fighting Falcons and F-35A Lightning IIs.

GA-ASI MQ-9 Reaper / Predator B
The Predator B multi-mission aircraft is highly modular and is easily configured with a variety of payloads to meet mission requirements.  Predator B is capable of carrying multiple mission payloads to include:
  • Electro-Optical/Infrared (EO/IR), 
  • Lynx® Multi-mode Radar, 
  • multi-mode maritime surveillance radar,
  • Electronic Support Measures (ESM),
  • laser designators, and 
  • various weapons packages.  
xxx

ONR seeks Comm Tech Concepts to support FORCEnet

FY 17 Communications and Networking Discovery and Investigation - Federal Business Opportunities: Opportunities

: N00014-16-S-BA11

: Presolicitation
:
Added: May 06, 2016 1:51 pm
Title: FY 17 Communications and Networking Discovery and Investigation 
 Sol. #:             N00014-16-S-BA11
 Agency:             Department of the Navy
 Office:             Office of Naval Research
 Location:           ONR
 Posted On:          May 06, 2016 1:51 pm
 Base Type:          Presolicitation
 Link:  https://www.fbo.gov/spg/DON/ONR/ONR/N00014-16-S-BA11/listing.html


United States Navy: Sea Power 21
Communications technology that can provide seamless, robust, connectivity is at the foundation of the Sea Power 21 and FORCEnet Vision "... to have the right information, at the right place, at the right time ..." The performance of Command and Control (C2) systems and decision making at all levels of command depend critically on reliable, interoperable, survivable, secure, and timely communications and networking, and the availability of high capacity multimedia (voice, data, imagery) communication networks is fundamental to nearly all Department of Navy missions.

The current evolution of naval warfighting from a platform-centric to a network-centric paradigm depends on successfully meeting the implied need for significantly enhanced communications and networking capabilities of C2, sensor and weapon systems. These systems are deployed on a variety of platforms and users, both manned and unmanned, operating under challenging battlefield conditions (lack of infrastructure, mobility, spectrum, interference, multipath, atmospherics, size/weight/power constraint, etc.) in different environments (space, terrestrial and undersea).

The goal of the Communications and Networking Program within the Office of Naval Research (ONR 311) is to support the FORCEnet vision by developing measurable advances in technology that can directly enable and enhance end-to-end connectivity and quality-of-service for mission-critical information exchange among such widely dispersed naval, joint, and coalition forces. The vision is to provide high throughput robust communications and networking to ensure all warfighters -- from the operational command to the tactical edge -- have access to information, knowledge, and decision-making necessary to perform their assigned tasks.

Objective and Areas of Interest:

White papers for potential FY17 Exploratory Development/Applied Research (Budget category 6.2) projects are sought under the following focus areas:

  1. Compact and deployable circular polarization antenna in the UHF-, X-, or Ka-, band with high radiation efficiency and adaptive gain pattern for multi-U form factor cube-satellite communications.
  2. Near-capacity (Shannon) wideband communications mode operation over multi-channel AESA pulsed radar hardware chain (beamformer - T/R module - antenna array). Potential challenges for high bit rate communications include, amongst others, novel coding/modulation schemes resilient to saturated nonlinear power amplifier regimes, exploitation of pulse-to-pulse phase coherence and MIMO.
  3. Enhanced waveform and diversity techniques including innovative tracking for mobile troposcatter (C- to Ku- bands). S&T focus on solutions that can reuse existing apertures, minimally impact HW, and permit modular upgrade.
  4. Robust and (throughput) efficient wireless medium access mechanisms for mobile LPI/LPD network communications operating under high dynamic range, and high-interference rejection (e.g., spectral underlay), receive conditions.
  5. Mechanisms to guarantee delivery of traffic across a multi-hop ad-hoc network within a specified latency; optimization of traffic based on multiple parameters (e.g., priority, latency, jitter, etc.); multi-path TCP implementations that are cognizant of variations in path characteristics and traffic priority, and do not impact application performance; store/forward and disruption-tolerant network implementations across a cipher-text core.

Related/Background:

Sunday, May 1, 2016

UAS C4ISR architecture to fuse useful info out of sea of MULTI-INT data

Army researchers asking industry for ways to speed sensor-fusion intelligence to warfighters

A diagram showing how Multi-INT works. (Photo: Lockheed Martin)
spendergast: Army CERDEC seeks Multi-modal Signal and Fusion Processor Architectures

ABERDEEN PROVING GROUND, Md., 27 Feb. 2015. U.S. Army researchers are reaching out to industry for new ways to speed actionable intelligence to the field commanders and warfighters on the front-lines who need it most.

To do this, researchers are asking industry for ideas on creating a common electronic architecture for performing multi-modal fusion within signal processors, on the payload of sensor platforms, on maneuvering vehicles, and at fixed site locations.
Officials of the Army Communications-Electronics Research, Development and Engineering Center at Aberdeen Proving Ground, Md., have issued a request for information (W56KGU-15-R-A025) for the Multi-modal Signal and Fusion Processor project.
This initiative seeks new ideas for a common architecture that can fuse information from several different kinds of battlefield sensors. This common architecture for sensor fusion, furthermore, could function within signal processors, on sensor payloads, on maneuvering vehicles and aircraft, and at fixed-site locations.

Industry perspective: How GA-ASI is helping C4ISR take flight

[GA-ASI Chris] Pehrson: There are more platforms and more sensors collecting more data than at any time in history. The greatest challenge to C4ISR will be distilling this sea of data to produce accurate, reliable, timely, and actionable intelligence. General Atomics Aeronautical Systems (GA-ASI) Remotely Piloted Aircraft (RPA) systems compound this challenge because our Predator®/Gray Eagle-series aircraft are flying in greater numbers, with more endurance, and with sensor payloads that collect exponentially increasing amounts of data.
Our vision is to fuse Multi-INT data such as Full-motion Video, Synthetic Aperture Radar/Ground Moving Target Indicator radar, and SIGINT in order to reduce the workload of intelligence analysts on the ground. We also envision networked platforms working collaboratively in real-time to support ISR requirements.

Chris Pehrson
Chris Pehrson
Chris Pehrson serves as director of strategic development for General Atomics-Aeronautical Systems Inc., where he is responsible for business acquisition strategies to promote company’s unmanned aircraft systems, tactical reconnaissance radars and sensor systems in U.S. and international markets.
Pehrson joined the company in 2010 after service in the U.S. Air Force, where he commanded an operations group and two squadrons as well as completed staff tours at Air Force headquarters and the Office of the Secretary of Defense.

GA-ASI - build it and they will come: 

Pehrson: Because GA-ASI is a privately-held company, we are more agile than most aerospace defense companies. We can take a longer view of market opportunities and generally have more flexibility when investing Internal Research and Development (IRAD) resources. For example, when we introduced the U.S. Air Force to Predator B in 2001, and subsequently Predator C in 2009, there was no government funding for aircraft development. GA-ASI saw capability gaps, produced aircraft to fill those gaps, and introduced fully mission capable RPA to the U.S. government as an off-the-shelf solution. Both aircraft proved highly capable, which led to further procurement, but we assumed development risk and maintained an aggressive schedule because of our unique position in the marketplace. Incentivizing a long-term perspective with rapid acquisition processes is one way the government could stimulate innovation and improve the way it purchases C4ISR goods and services.

Related/Background: