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Archive for August, 2017

Royal Air Force JTACs Integrate with US Counterparts

Monday, August 14th, 2017

MOODY AIR FORCE BASE, Ga. – Members of England’s Royal Air Force recently spent time immersed with the 93rd Air Ground Operations Wing at Moody Air Force Base, Georgia.


An A-10C Thunderbolt II conducts a show of force maneuver during training, July 26, 2017, at Grand Bay Bombing and Gunnery Range, Ga. The range features a moving target system, which is on a 1,000 foot long track that is remotely controlled by the control tower and can move back and forth to assist in training. (U.S. Air Force photo/Andrea Jenkins)

The NATO allies visiting were Joint Terminal Attack Controllers tasked with building stronger ties with the 93rd AGOW in hopes of future integration opportunities.

“All the missions overseas aren’t integrating just the U.S. Armed Forces, but also our NATO forces,” said Master Sgt. Francisco Corona, the 93rd AGOW NCO in-charge of weapons and tactics. “So all the NATO forces are trying to train with us. I’d rather integrate in (training) where we can make mistakes and learn from them instead of making mistakes in a deployed location.”

Since 2001, U.S. and foreign JTACs have been in high demand as liaisons between Army ground commanders and Air Force assets.


U.S. Air Force and Royal Air Force joint terminal attack controllers communicate with 23rd Fighter Group A-10C Thunderbolt IIs during a close air support training exercise, July 26, 2017, in Lakeland, Ga. Two Royal Air Force members recently spent time with the 93rd Air Ground Operations Wing to compare and contrast how each entity conducts business and to plan future coalition training events. (U.S. Air Force photo/Airman 1st Class Daniel Snider)

“As air-to-ground experts, we advise, assist and control for the ground commander to meet his intent, whether its kinetic effects, like bombs on targets, or getting smarter at cyberspace,” said Corona.

Both groups of JTACs said they’re no stranger to operating in coalition settings while deployed.

“While I was a JTAC in Afghanistan, the vast majority of our aircraft were U.S. aircraft,” said Squadron Leader Neil Beeston, the officer commanding Air Land Integration Cell. “It was great working with the U.S. Armed Forces, especially with the A-10s; it’s a fantastic aircraft. The troops on the ground know that when you’ve got a pair of them above you, you’re in pretty safe hands.”

While the JTACs and U.S. aircraft are skilled professionals, sometimes communication barriers exists between countries. Beeston’s colleague stressed the importance of hashing out common issues.

“The whole worldwide JTAC community has the same struggles,” said Flight Sergeant Simon Ballard, the chief instructor from the ALIC. “Since we’re going to be working together, we need to practice together before we go do that in the real world.”

Not having the allied JTAC community in sync and on par with each other could potentially lead to less-than-optimal situations, which in turn risks lives.

“We don’t want to learn how to work together in a war area of operations,” said Corona. “We’re flexible though, whether it’s [English] JTACs or whatever joint force JTACs, we make things happen and we’ll make it work.”


MSgt Francisco Corona, the 93rd Air Ground Operations Wing NCO in charge of weapons and tactics, communicates with a fellow Joint Terminal Attack Controller during a close air support training exercise, July 26, 2017, in Lakeland, Ga. Two Royal Air Force members recently spent time immersing with the 93rd Air Ground Operations Wing to compare and contrast how each entity conducts business and plan future coalition training events. (U.S. Air Force photo/Airman 1st Class Daniel Snider)

After the gathering, troops returned to their leadership with proposals and plans to further integrate training scenarios, whether it be academic courses or mixing into each country’s exercises to further synchronization.

“The bonus for them is they’d be integrating with different Army divisions because the 93rd AGOW is spread over at least six Army divisions,” said Corona. “They’d get that opportunity, where there’s not many divisions they work with over in [England].”

While Corona is confident in U.S. JTACs, he said it’s all about continuing to get better, to maintain leading from the front.

“We’re figuring out how we go to the next level to continue to be the best JTACs in the world,” said Corona. “We’re going forward with a proficiency mindset, of ‘how do we get better,’ because at the end of the day, the better trained individuals are going to be the winners.”

By Airman 1st Class Daniel Snider, 23rd Wing Public Affairs

AFCEA TechNet Augusta 2017: Panasonic Toughbook and Tablet

Monday, August 14th, 2017

Panasonic’s Toughbook lineup is ubiquitous on the battlefield, dating back to the CF-27 series laptop.  The venerable CF-31 and CF-19 laptops are subcomponents of numerous C4ISR systems fielded by DoD and allied forces.

The new CF-33 and CF-20 are the replacements for the CF-31 and CF-19 and feature detachable screens for use as tablets.  The screens have proprietary Panasonic technology to allow use with almost any sort of glove to include NBC and cold weather gloves.

The FZ-X1 Tough Tablet is a 5″ Android tablet that’s rated to 30 minutes submersion, 10 foot drops, and operation down to -4F.    Both touchscreen and programmable hardware hot-keys allow access to any application. Of particular note is the user replaceable battery, allowing for a long service life.  Business card for scale.

Front

tablet1f

Side

tab_side

Rear.  Of note, the camera module can be replaced with a bar code scanner.

tab_rear

The CF-20 and CF-33 are 10.1″ and 12″ laptops with detachable screens.  The keyboard base functions as a docking and port base as well as home for additional battery power.  The signature front mount carry handle of the Toughbook line has been moved the rear to serve as a stabilizer when the screen is tilted back now that most of the “guts” have been moved into the detachable screen section.

CF_20_33

The CF-31 will remain in legacy production for the near-term to fulfill existing requirements but expect it to be phased out after another hardware refresh cycle.

Finally, the Toughpad FZ-M1 7″ Windows tablet is available along with the larger Toughpad FZ-G1  10″ tablet.  A matching pair of Android based tablets are also available.  The devices are fully ruggedized and targeted at medical and maintenance applications.

FZm1_Tablet

A full line of Windows and Linux drivers and APIs are available directly from Panasonic to allow customized application from a single vendor with the complete TDP.

Panasonic Business Solutions

 

AFCEA TechNet Augusta 2017: Samsung and Juggernaut

Monday, August 14th, 2017

SamsungBig

Spotted in the Samsung suite at AFCEA TechNet 2017 were these mounts and cases by Juggernaut for the new ruggedized Samsung lineup.

 

Wrist Mount

The Wrist Mount can hold most Juggernaut cases and uses a BOA fastener to quickly adjust tension.

Wrist1

Chest Mount

The chest mount uses a hinged polymer PALS panel that allows the device’s viewing angle to be adjusted or fully stowed and closed.  Of note is  that the hinge uses a blackened stainless steel pin for durability.

ChestOpen  ChestClosed

Knee/Thigh Mount

Finally, Juggernaut offers a thigh mount case for tablets.  Here is the ruggedized case for Galaxy Tab series Android tablet.  This would be particularly useful for forward observers, communicators, and during vehicular insertion in low-profile vehicles.

KneeBoard

Juggernaut Case

Samsung Knox

 

 

Ask SSD – How Do I Write A White Paper?

Monday, August 14th, 2017

We are often asked by various vendors for government solicitations, how they should format a white paper. USSOCOM offers this fictional white paper for its potential vendors as an example.

Entitled, “DUAL-MODE AUGMENTED CANINE TRANSPORT SYSTEM – PROJECT DUCTS”, it is referred to as “Rocket Dog”.

Feel free to use it as a template for white paper development, particularly if you’re submitting one to SOCOM. Download your copy here.

2017 Special Operations Forces Warrior Industry Collaboration & JSOC Capabilities and Technology Expo Solutions Event

Monday, August 14th, 2017

The Program Executive Office Special Operations Forces Warrior (PEO-SW) and Joint Special Operations Command (JSOC) have announced the 2017 iteration of their “Industry Collaboration Days” on 15-16 November 2017. The purpose of this event is to provide industry with an opportunity for a focused engagement with members of PEO-SW and JSOC to share ideas that facilitate the delivery of innovative capabilities to Special Operations Forces (SOF).

The Day 1 (SOFWIC) General Session on November 15th will be open to all interested vendors. The General Session will consist of introductory presentations by Special Operations Forces Acquisition, Technology & Logistics (SOF AT&L) leadership, an overview of PEO-SW war fighting commodity areas, and forecasted contracting opportunities for FY18 and beyond. Following the General Session, the remainder of the day will consist of 60 minute, invitation-only sessions for selected vendors to discuss their White Paper and/or Cooperative Research and Development Agreement (CRADA) Proposal submissions addressing SOCOM’s Capability Needs (see below).

Day 2 (JCTE Solutions Event) on November 16th will be invitation only sessions with selected JSOC industry partners who have reviewed the unclassified or classified Capability and Technology Interest Items list released in conjunction with the PEO-SW sessions at the Special Operations Forces Industry Conference (SOFIC) in May 2017 and have submitted CRADA Proposals addressing those interest items.

This is the the most up to date listing of Capability Needs, listed in priority order by commodity area:

(1) Ground Mobility
a. Drivetrain and locking differentials Ground Mobility Vehicle (GMV 1.1) – Technology that will allow for transaxle replacement to increase reliability.
b. Suspension technology (GMV 1.1) – Suspension upgrades/replacement to increase performance, durability, and reliability. Semi-active seating that ties into the upgraded suspension working together to isolate occupants from terrain induced shock loading.
c. Cost reduction solutions for brakes, suspensions, C4ISR, etc. for Light Tactical All-Terrain Vehicle (LTATV), Non-Standard Commercial Vehicle (NSCV), GMV 1.0 and GMV 1.1 – Novel approaches to reduce the lifecycle costs (namely production and sustainment) associated with braking, suspension, and other vehicular systems. Current C4ISR components (antennas, mounts, cables, etc.) are expensive and long lead in nature. We are targeting reduced costs, improved lead times, and equivalent capability to our current SOF suite of C4ISR (LoS, SATCOM, ECMS).
d. Low Cost, lightweight, rapidly attached/utilized tow bars (10k-20k lbs.) (GMV 1.1, GMV 1.0) – Quality built, sustainable tow bars that are lightweight, low cost, and rapidly attached for use on the medium family of vehicles (10k-20k lbs.)
e. Shock Mitigating seating (LTATV, GMV 1.1) – Novel approaches for LTATV seating and/or seating material(s) that will mitigate the shocks associated with off road vehicle driving.
f. Brake technology (GMV 1.1) – Brake upgrades/replacement to increase performance, durability, and reliability.
g. Visual, Audible, and Thermal Signature Reduction (LTATV, GMV 1.1) – Novel reduction approaches in addressing visual (camouflage), audible (mufflers, sound suppression), and thermal (heat dissipation/reduction) signatures.
h. Low profile Common Remotely Operated Weapon System (GMV 1.1) -Looking for small and light solutions that can utilize a wide range of weapons for a smaller tactical vehicle.
i. Mature 12 Volt battery technology for cold temp start and/or reduced size without degrading Cold Cranking Amperage or AMP hours (NSCV, GMV 1.1) – Mature battery technologies that can withstand cold start scenarios down to -50 F and also extend the timeline for silent watch. Reducing size but not performance is ideal as well.
j. Purpose Built NSCVs (Modular Purpose Built Chassis or common purpose built drivetrain for SUVs and Trucks) – Cost effective solutions for reduced logistics or to allow vehicles that are commercial in appearance to be reset at the end of the lifecycle instead of disposed of and re-procured. This would also allow different bodies to be interchanged on a common chassis to reduce logistical costs. The concept of Purpose Built is governed by the fact that vehicles are not modified commercial vehicles, but rather purpose built vehicles with little to no reliance on commercial vehicles. Vehicles are anticipated to be designed to mimic late model vehicles typically found in central Asia (e.g., Toyota Hilux, Toyota Land Cruiser 200, and Toyota Surf); armored against ballistic threats; 10 year vehicle life (minimum); vehicle designed for one or more resets; 4 wheel drive with heavy duty brakes and suspension to accommodate gross vehicle weight; full skid plates and running boards; diesel engines; and left hand drive.
k. Tire technology and non-pneumatic efforts (GMV 1.1, LTATV) – Novel approaches addressing wheel/tire assemblies to allow for better suitability in soft soils and terrains. Tire technologies to allow for a broader range of environmental terrains (sand, mud, and rock), to include non-pneumatic types.
l. Low Profile Antennas for Line of Sight, SATCOM, and ECMS (NSCV) – Antennas that can be hidden on/in/around the vehicle to appear almost non-existent while still effectively transmitting desired frequencies at specific power levels.
m. Light Vehicle Safety Improvements and Accessories (LTATV) – Improvements to general safety items to include (but not limited to): seating, roll cages, stability control, driver assist functions, etc.
n. Low Visibility Transferable Armor for commercial vehicles (NSCV) – Armor materials/panels, etc., that can be transferred and integrated from one commercial vehicle to another with minimal manpower and in a minimal timeframe.
o. Lightweight Transparent Armor (NSCV, GMV 1.1) – Novel lightweight and cost effective technologies that can replace current heavy transparent armor solutions on vehicle platforms.
p. OEM Electronic Control Unit (ECU) defeat (NSCV) – Solutions for bypasses the inherent safety controls built into OEM ECUs on FOSOV NSCVs to allow permanent disabling of features such as stability control and traction control which impedes use in a SOF environment.
q. Low Cost, High Output Alternators for NSCVs – Targeting both 12V and 28V dual alternator combinations, along with high output single 12V and dual 12V solutions. The 28VDC alternator shall have a minimum of 130A (at 28VDC) output (80A at idle) and shall fit within the current engine compartment. Any single high-output alternator shall have a minimum 260 Amp (12 Volt DC) output rating at idle and engine operating temperature of 220 degrees F. The purpose of this RFI is to determine the availability of solutions to replace the existing package within NSCVs, allowing flexibility for future growth, and to clear real estate in the engine compartment if we can achieve our requirements with a lower cost and smaller solution.

(2) Visual Augmentation Systems
a. Signature Reduction technologies for Targeting Laser (Out of Band and Notional Laser) – Laser designation technologies that are able to be perceived through typical and widely fielded Image Intensification technologies. Notional laser could exist only in virtual reality and be perceived through an integrated augmented reality display inside an eyepiece of NVG.
b. Head-mounted Devices- Looking for weight saving technologies or novel methods to move weight off of the head.
c. Hand Held Devices- Seeking size, weight, and power enhancements on handheld VAS commodities.
d. Weapon Mounted Devices Seeking size, weight, and power enhancements on weapon mounted VAS commodities.

(3) Weapon Systems:
a. Intermediate Caliber- Long Range Machine Gun 2000m- We are seeking a machine gun that has long range (2000m or greater) with weight comparable to the current medium machine gun (24lbs or less).
b. Suppressed Upper Receiver Group (SURG) – Seeking next-generation, modular upper receiver group that is interoperable with current lower receivers and is optimized for full time suppressed operation. Must have advanced heat mitigation technology to counter mirage effect.
c. Signature reduction for Small Arms- Sound, Flash mitigation technologies that are light weight and effective.
d. Advanced/Precision Sniper Rifle- We are seeking a multi-caliber platform that can shoot 7.62x51mm, .300NM, and .338NM. to sub minute of angle.

(4) Ammunition/Demolition:
a. Domestic sources of production for non-standard ammo and weapons- Seeking domestic production for weapons and ammo in the 7.62×39, 7.62x54R, and 12.7×108 categories.
b. Lightweight Ammunition- Seeking ammunition that can reduce weight by at least 30% of the current inventory of common ammunition from 5.56 up to 12.7×99.
c. Toxin Free Ammo- Seeking both lead free and reduced toxin alternative to the current inventory of training munitions- Polymer Short Range training ammo, Blank fire ammunition, man- marking rounds, and short range training ammunition.

(5) Soldier Protection, Survival, and Equipment Systems
a. Armor – Novel technologies and designs that decrease weight while increasing level of protection.
b. Helmets – Novel technologies and designs that decrease weight while increasing level of protection.
c. Special Operations Eye Protection – Laser protection (visible and IR); ability for a single lens to adapt to various lighting conditions near instantaneously.
d. Uniforms – Novel technologies and designs for heated clothing and gloves.
e. Logistics – Financial Improvement and Audit Readiness compliant internet accessible web application (certified mixed/feeder system) for the Special Operations Forces Personal Equipment Advanced Requirements (SPEAR) program capable of property accountability, warehouse management, logistics/supply functions, financial, and personnel management data to include the conversion of measurements to sizes using an approved algorithm for Special Operations Forces-Peculiar (SO-P) individual equipment. Integration with the United States Special Operations Command (USSOCOM) logistics enterprise is mandatory.

(6) Tactical Combat Casualty Care Medical Systems
Novel FDA approved technologies that apply to individual casualty care and casualty evacuation.

(7) Find, Fix, Finish, Exploitation, and Analyze Capabilities

For details on how to submit a white paper, visit www.fbo.gov.

Velocity Systems Trigger Glove

Monday, August 14th, 2017

The Velocity Systems Trigger Gloves have been redesigned to include connectivity panels on thumb and middle finger and are now being offered in black and coyote brown. The Trigger Gloves are a second skin fitting liner glove with abrasion resistant palm perfect for use as a liner, or dexterous light duty glove. They were designed to be used as a light weight and nimble shooting glove and are not intended for any other purpose.

Features:
-Palm made with premium Pittard WR100x for unparalleled grip and permanent water resistance. Maximizes weapon retention even in cold wet environments
-Merino Wool Blend
-Clean, No trigger seam on index finger
-No-Melt No-Drip fabrics and leather for use in combat environment
-Connectivity panel on thumb and middle finger, Not index finger for trigger feel
-Internal lash point to attach to ballistic vest
-Second Skin fit to reduce the potential incidental discharge of firearm
-Thumb wrap for wear out protection of the gloves thumb from weapon safety lever
-Imported

Size: XS-7 | S-8 | M-9 | L-10 | XL-11 | 2XL-12

Check out additional product details at www.velsyst.com/trigger-gloves

Aurora And MIT Celebrate Nine Years Of Student Robotics Program Success

Monday, August 14th, 2017

Zero Robotics MS Finals Summer 2017

Zero Robotics engages students in science, technology, engineering and math (STEM)
through computer programming and space research

Cambridge, MA, August 11, 2017 – Middle school students across the country today participated in a live interactive broadcast of NASA astronaut Jack Fischer operating satellites developed by Aurora and MIT aboard the International Space Station (ISS). The basketball-sized, battery operated satellites were controlled using computer code written by the students as part of the Zero Robotics summer learning program.

Founded by MIT’s Space Systems Laboratory and run in partnership with Aurora and the Innovation Learning Center, Zero Robotics is a robotic programming competition for middle and high school students. Students learn to write software to autonomously control the SPHERES satellites aboard the ISS. Each year, the Zero Robotics competition challenges students to address a real spaceflight operational scenario.

“Aurora is proud to partner with MIT on this innovative and engaging STEM-education program,” said John Langford, Aurora Chairman and CEO. “Zero Robotics has introduced thousands of students over the years to the wonders of spaceflight and robotics. With this next generation of scientists and engineers at the helm, the future of NASA’s space program looks exceptionally bright.”

Aurora built the SPHERES satellites and has partnered with MIT on the Zero Robotics program since its inception in 2008. Over the years, Aurora’s involvement has evolved to encompass competition coordination support, student mentoring, instructor education, and curriculum development.

This year’s middle school finals comprised of 13 teams hailing from 12 U.S. states and Russia. Zero Robotics is also open to high school students, with a tournament held each year between September to December for students grades 9-12. The Middle school competition is sponsored by the Center for the Advancement of Science in Space (CASIS), the Northrop Grumman Foundation, and NASA. To learn more about the Zero Robotics program, and to view results from today’s competition, visit www.zerorobotics.mit.edu. To learn more about Aurora’s SPHERES program, visit www.aurora.aero/SPHERES.

UF Pro – Defense Against Cold Weapons, Part 2

Sunday, August 13th, 2017

Here’s another installment of UF Pro’s Guide to Close Combat series with Defence Against Cold Weapons, Part 2, an instructor’s video.