Last summer at the Space and Missile Defense Symposium, GEO Huntsville held its annual GEOINT workshop including a keynote by NGA (National Geospatial-intelligence Agency) Deputy Director Sue Gordon. One of the sessions, presented by Mike Botts, focused on the OpenSensorHub and related information published on GitHub.
His topic: clearing the path for use of geospatial-capable devices via the Internet, thus preventing a geospatial Tower of Babel.
In the mid-80s, I purchased my first personal computer from Sharper Image, a 286 with a monochrome monitor. The PC was not bad for its time, and I learned a lot about personal computing, but hooking up a dot-matrix printer at the time was a nightmare. There were numerous types of printer cables — 25-pin parallel, 36-pin Centronics, 15-pin, etc. Additionally, some printers needed changes to the pin configurations, so nothing about the process was easy.
Then, after the mechanical connections were made, proper drivers had to be loaded, not to mention operating system and software configuration. Today, you simply plug in a USB cable or go wireless and are off and running thanks to “plug and play.” However, plug and play is only common in popular mass-market devices such as printers, scanners and cameras. Most other devices, even commercial consumer devices, can still present maddening connection challenges.
One example: About five months ago, I tested more than a dozen different Internet video security cameras for a special project. All the cameras I tested touted quick and easy connection. Some were quite nice, while others were installation torture — I returned those after a few days.
One well-known consumer brand was especially bad. I spent more than three hours with hard-to-understand tech support in India, and after countless different IP configurations and tests, I gave up. I decided that my remaining life is too short to waste that much time on a poorly designed camera system.
(By the way, the FLIR FX and Netgear Arlo were my top choices. Both connected fast and easy, both have especially nice cloud applications and both are wireless, including power. The FLIR is rechargeable, but the battery life of the Arlo seems remarkable, although some reviewers differ, especially outdoors and in freezing weather. In my test, after three months of flawless operation indoors, the Arlo is still on the original set of batteries at 60 percent, so it gets my top nod.)
OpenSensorHub
What is OpenSensorHub, and what are they doing to help achieve universal plug and play? By their own definition:
“OpenSensorHub is a license free, open source software platform for geospatial (FOSS4G) sensors that allows you to easily, rapidly and affordably network sensors into a seamless SensorWeb of real-time, location-aware, interoperable, web accessible services. With OpenSensorHub, these OGC compliant SensorWebs can be enabled across all manner of space-based, airborne, mobile, in situ and terrestrial remote sensors — including your basic mobile device. OpenSensorHub finally makes it possible to integrate location-aware sensors into the geospatial mainstream.”
(FOSS4G — Free and Open Source Software for Geospatial — is an annual recurring global event hosted by OSGeo growing out of the GRASS and MapServer communities. OSGeo — Open Source Geospatial Foundation — promotes open source software and resources. OGC — Open Geospatial Consortium — promotes open geospatial standards for both open source and proprietary software.)
The OpenSensorHub evolved from the early work of Mike Botts of Botts Innovative Research and Alex Robin of Sensia Software for NASA. They very laboriously designed and developed systems and software to connect sensors and actuators into an interoperable and integrated environment. They also realized that this connectivity and integration process had to become streamlined and not a custom programming effort every time for every device. Thus was born the idea of Sensor Model Language (SensorML) and, thanks to NASA funding in 1999, it became a reality.
Over the years, many scientists and engineers worked to develop connectivity for devices that could be queried and controlled through the Internet, called the Internet of Things (IoT). However, a key missing element of IoT was location awareness, so in 2000, SensorML was brought to the Open Geospatial Consortium (OGC) and served as a catalyst for the creation of a suite of open standards to support location-enabled discovery, access and tasking of sensors through web services and XML encodings. They named it the OGC Sensor Web Enablement (SWE) standards, or SWE for short.
The SWE standards, now in version 2.0, have been adopted worldwide supporting scientists, emergency responders and the military. Although SWE opened the door to geospatial integration, much work still remains to achieve true plug-and-play connectivity of thousands of devices. In my mind, SWE is standardizing communication protocols between sensor and actuator devices, much like USB standardized interactions between disparate devices.
However, what really enables us to plug in a USB cable and have instant and effortless communication between various devices, is the software and hardware that implement the USB standard protocols. This, in essence, is the focus of the OpenSensorHub community, to provide open software and hardware that fully implement the SWE vision and enable us to have effortless interaction between IoT devices.
This is also where the OpenSensorHub community needs your help. In addition to helping improve the significant capabilities of the OpenSensorHub Core, the OpenSensorHub community is looking for those interested in deploying sensors and in developing adaptors and adaptor technologies for adding new sensors, actuators, and processes.
If you’d like to learn more about the technology and ways that you can contribute, check out the OpenSensorHub website or contact the team at [email protected].
The global commercial UAV market is expected to reach $2.07 billion by 2022, according to a new study by Grand View Research Inc.
Increasing applications in agriculture and law enforcement are expected to drive commercial UAV industry growth over the forecast period. Commercial drones are finding applications across various industry verticals globally. Every industrialized country in the world is making investments in drones, thus driving the scope and technological developments for applications in the commercial UAV market.
Drones are contemporary alternatives for activities where human life cannot be risked. Such drones find applications in various industrial verticals including military, homeland security, retail and agriculture. The demand is significantly higher for military applications, although commercial applications are progressively catching up.
Aviation regulatory bodies such as the Federal Aviation Administration (FAA) have imposed restrictions on the use of such drones taking into consideration the difficulties in managing such huge air traffic and the safety of the citizens. However, the FAA is known to be undertaking an initiative to accelerate the UAV approval process for public safety agencies and broaden access to civilian organizations for a variety of commercial, industrial and other applications.
Further key findings from the report suggest:
Rotary blade drones accounted for more than 70 percent of the global market share owing to their easy maneuverability and compact design. Moreover, such single and multi-rotor drones equipped with rotary blades have Vertical Take-Off and Landing (VTOL) abilities for applications, where there is limitation of space for fixed blade drones to take off. The development of advanced hybrid UAVs that operate on non-conventional sources of energy and nano, small miniature drones serve multiple applications across various industry verticals.
Government applications dominated the global commercial UAV industry constituting more than 40 percent of the market share in 2014. Increasing applications in law enforcement, security and surveillance, R&D activities, infrastructure, disaster management, and environmental studies have led to an increased demand for such unmanned aerial vehicles from the concerned government agencies. Innovative applications across agricultural sector have made it the fastest growing application segment, which is projected to grow at a CAGR of more than 18 percent from 2015 to 2022. Special agricultural drones can take snapshots of fields and help in analyzing crops. In addition, fix winged drones can be used for applications such as watering, spreading seeds, fertilizers, and pesticides over large farm fields that drastically reduce the time required and increase the efficiency.
North America is expected to grow at a CAGR of more than 16 percent over the forecast period on account of concentration of major drone manufacturers and increasing applications in the commercial sectors in the region. Governments and technology giants across the world are striving hard to provide internet to the people as a basic necessity. Facebook Inc. recently acquired Ascenta, a drone manufacturer for its pilot project to provide internet in remote areas using drones as movable wireless access points. Relaxation in regulations and increasing use of drones in law enforcement activities in Europe have led to the regional industry growth.
Major industry participants include AeroVironment Inc., BAE Systems, DJI, Elbit Systems, Parrot SA, Israel Aerospace Industries, The Boeing Company, and Textron Inc. Manufacturers resort to mergers and acquisitions as their key growth strategy to make their presence felt in the industry. Augmented funding, technological collaborations, and government agencies are expected to emerge as critical success factors for industry growth.
Grand View Research has segmented the global commercial UAV market on the basis of product, application, and region:
Commercial UAV Product Outlook (revenue, USD billion, 2012-2022)
Fixed wing
Rotary blade
Nano
Hybrid
Commercial UAV Application Outlook (revenue, USD billion, 2012-2022)
Agriculture
Energy
Government
Media & Entertainment
Others
Commercial UAV Regional Outlook (revenue, USD billion, 2012-2022)
The latest variant of the Excalibur precision-guided projectile will be used by armies and be available for naval ships.
The Netherlands Ministry of Defense is adding Raytheon Company’s Excalibur Ib artillery rounds to its arsenal under a previously announced foreign military sales agreement, underscoring growing international interest in the precision-guided projectile.
The Netherlands is the second Excalibur lb customer in Europe after Sweden, the U.S. government’s development partner for the 155-mm round. Deliveries are expected to begin later this year.
“The Netherlands joins a growing list of nations acquiring this highly sophisticated artillery munition, which uses GPS guidance to provide accurate, first-round effects capability at extended ranges,” said Mark Hokeness, Raytheon’s Excalibur program director. “When fired from the Dutch PzH 2000 artillery system, Excalibur can fly up to 50 kilometers, score a direct hit and deliver lethal effects in all types of weather and battlefield conditions.”
A Dutch Panzerhaubitze 2000 (PzH 2000) fires a round in Afghanistan. (Image courtesy Dutch Ministry of Defense)
The U.S. Army has determined Excalibur Ib is fully compatible with the PzH 2000, a self-propelled howitzer produced in Germany and fielded by several nations.
The Excalibur precision-guided, extended-range projectile uses GPS guidance to provide accurate, first-round-effects capability in any environment. Excalibur’s level of precision delivers a major reduction in the time, cost and logistical burden associated with using other artillery munitions. Excalibur has been fielded by the U.S. Army, Marines and several international military forces.
Excalibur Facts
Combat-proven: Nearly 770 Excalibur rounds have been fired in combat with exceptional accuracy and lethality.
Precise: Excalibur consistently strikes less than two meters from a precisely-located target, Raytheon said.
Safe: Excalibur’s precision avoids collateral damage and has been employed within 75 meters of supported troops.
Affordable: With its first round effects, Excalibur reduces total mission cost and time and the user’s logistics burden, according to Raytheon.
Evolving: Raytheon has demonstrated a dual-mode GPS/semi-active laser seeker Excalibur variant to compensate for target location error, maintain precision in GPS denied or degraded environments, and enable engagement of relocated or moving targets.
Navies: With Excalibur N5, navies will be able to deliver extended range, precision naval surface fires from existing 5-inch/127-mm guns.
Technology Advancement Group (TAG) will be showcasing precision, navigation and timing technology integration solutions at the ION GNSS+ conference, which will be held Sept. 14-15 in Tampa, Fla.
In particular, TAG will display a custom-designed military GNSS survey system that is the U.S. Army program of record for geodetic, construction and airfield surveying.
TAG’s Precise Positioning Service Global Positioning System Survey (PPS GPS-S) system was designed specifically for use by survey teams to have access to centimeter-level GPS survey accuracy with the added benefits of a fully-certified military GPS receiver that is supplemented with a GNSS receiver for real-time kinematic surveying with multi-constellation operations.
The PPS GPS-S system has been specifically designed to address the stringent requirements of military survey missions including geodetic, construction, airfield, and field artillery survey. It gives the military surveyor the tools they need to complete their missions with minimum time-on-station even in the face of GPS signal interference, attempted spoofing, or electronic warfare, the company said.
TAG was recently awarded a $24 million contract by the U.S. Army Geospatial Center for its AN/GSN-16 military survey system.
Core components of the PPS GPS-S system include a base station and two rovers, each integrated with a GNSS antenna with protection against jamming or spoofing, a custom-designed rugged tablet with an internal RF radio that has a 20-km range, and GPS-S accessories for additional functionality. Designed for continuous operation, the PPS GPS-S system includes multiple power options such as dual hot-swappable Li-Ion batteries, 12V battery, DC/DC converter, NATO adapter, and 4-slot Li-Ion charging station.
Powered by Carlson Surv-PC, TAG’s PPS GPS-S system is tailored for military environments that require tactical computer-aided design (CAD) operations. With an intuitive graphical user interface, surveying operations can be conducted in the field allowing for work to be completed in real-time. Accurate geospatial information system (GIS) data capture and a full suite of CAD functions allows survey teams to remain in the field to complete the drawings without the need to return to base.
For ION GNSS+, TAG will be in booth #102 of the exhibit hall in the Tampa Convention Center.
On Aug. 24, David W. Madden joined Lockheed Martin’s Military Space Line of Business, where he will be responsible for international military satellite communications (MILSATCOM), based in Denver.
Madden served as the GPS Wing Commander at the Space & Missile Systems Center (SMC) in Los Angeles, Calif., before retiring from the U.S. Air Force in May 2010. From June 2010 until his new appointment, Madden served as director of the Military Satellite Communications Systems Directorate at SMC.
In his new role, Madden will oversee Lockheed Martin’s efforts to further enhance the company’s relationships with international allies and customers, and to grow the MILSATCOM portfolio.
At the Military Satellite Communications Systems Directorate at SMC, Madden was responsible for acquiring, deploying and sustaining the $42 billion MILSATCOM portfolio of programs which consists of ACAT I and II programs including the Defense Satellite Communications System, Milstar, Global Broadcast Service (GBS), the Wideband Global SATCOM, the Advanced EHF program, the Enhanced Polar System, the Command and Control System-Consolidated and associated Terminals programs.
Madden entered the Air Force in 1980 after graduating from the Virginia Military Institute. He gained experience in systems engineering, technical intelligence, and command and control and space systems requirements, development, fielding and operations. In addition, he has commanded a Space Operations Squadron and a Material Acquisition Group before the GPS Wing.
Dr. Todd Bacastow, PSU, talked with me about geointelligence in the broader business community. See the full interview below.
Time for a Revolution — or Evolution
In July at GEOINT 2015 I was talking with long-time colleague Dr. Todd Bacastow. Many of you may know him as the retired Army Lieutenant Colonel and Penn State professor heavily involved in the Geospatial Intelligence Certificate program and the lead for the GEOINT Massive Open Online Course (MOOC) series focused on GEOINT. He proposed a topic for my column that struck a nerve with me since I and others had danced around the potentially heretical issue — is it time to open and expand the GEOINT community to a larger audience?
As retired military officers, Todd and I share a common overarching loyalty and desire to do what we can to make life better and more survivable for our colleagues on active duty. GEOINT has certainly helped by providing detailed and timely actionable intelligence for those at the tip of the spear. However, can we do even better? Most assuredly yes!
The most advanced tip of the spear is our Special Operations community. Manycivilians picture Special Operations members as knuckle-dragging Rambos shooting up the countryside, but nothing could be further from the truth. In fact, they are without doubt the most intelligent, observant and capable people on our DOD team. They’ve learned over decades of experience that they can complete their missions and accomplish far more by winning the hearts and minds of individuals they deal with. Doing that requires hours, days and weeks of due diligence reviewing intelligence and any crumb of information that will make a difference.
Gone are the days of just looking at aerial photography. Now we have countless sources and types of imagery, analytics, tracking, social media, signals and human intelligence. Putting that complex slurry of information together into solid actionable intelligence is everyone’s goal, and the business community is no exception.
Looking around the GEOINT Expo, I saw countless three-letter agency reps, military and homeland security personnel. There were an equal number of defense contractors and related business personnel, but everything was focused on military/security applications. Other than Pitney Bowes showing MapInfo, primarily a business-focused GIS, there were few exhibitors showing technology not aimed at the traditional GEOINT community.
Our military and other first responders have tasks and responsibilities that are serious, complex and becoming more challenging. Limiting the talent pool and body of knowledge to only the narrow GEOINT community is not something we can afford to do. The creative talent found in the broader business community is too valuable to neglect.
Watch the video interview I shot at GEOINT 2015 with Bacastow and Dennis Bellafiore, Ph.D., both of Pennsylvania State University.
My chief concern is bringing the business community in with the understanding that this would be an open and sharing environment. My first real use of GIS after retiring from the Navy in 1993 were some business applications, mostly site studies and trade area analysis. In those early days, GIS grew rapidly within the business community. There were trade shows aimed at business applications of GIS, and even a publication called Business Geographics. Much to my surprise, Business Geographics and associated trade shows died out after only a few years. Some said that everyone learned all there was to learn! I don’t think so. A more likely reason was that the geospatial technology gave businesses a competitive edg.e so there was little incentive to expose trade secrets. Everyone wanted to learn about GIS, but few wanted to open their own kimono.
Would an all-inclusive GEOINT organization run into the same fate? Perhaps if we promote it as “we are all in the same boat” and this is your opportunity to help those at the “tip of the spear.” In this age of cyber warfare and corporate espionage, perhaps we might be able to make this happen by promoting mutual aid and security. I think USGIF and most geospatial industry partners would be interested and very supportive of the idea. But most important, can you imagine the explosion of ideas and the benefits to all geospatial users.
Todd, Dennis and I would really appreciate your opinion. Please leave comments below.
The ION Joint Navigation Conference, sponsored by the ION’s Military Division, is the largest U.S. military positioning, navigation and timing (PNT) conference of the year with joint service and government participation, ION said. The event will focus on technical advances in guidance, navigation and control (GN&C), with emphasis on joint development, test and support of affordable GN&C systems, logistics and integration.
From an operational perspective, the conference will also focus on advances in battlefield applications of GPS; critical strengths and weaknesses of fielded navigation devices; warfighter PNT requirements and solutions; and navigation warfare.
For Official Use Only (FOUO), United States only, sessions will be held June 22-24 at the Renaissance Orlando at SeaWorld, Orlando. The U.S. only classified sessions will be held June 25 at Shades of Green Walt Disney World.
The ION JNC features more than 200 operational presentations on a diverse array of topics. Abstracts are being accepted through March 4.
GPS Source has released a new GNSS antenna that is robust, lightweight, and suitable for harsh environments. It is designed for long-term, high-precision applications worldwide, the company said.
The antenna was engineered for the demanding aviation environment, in both commercial and military applications. Built to military standards (MIL-STD), it is impact resistant, tolerant of exposure to dust, chemicals and jet fuels, and has the ability to withstand shock and vibration.
Signal reception is unaffected by antenna placement. Designed to operate in the most extreme and demanding applications, it gives outstanding results, enabling maximum satellite reception, with ultra-low Dilution of Precision (DOP), GPS Source said.
“We are very excited about the new GNSS antenna,” said Robert Horton, CEO of GPS Source. “Our advanced technology provides superior performance in both GPS L1/L2 and GLONASS L1/L2. This is the best solution for technically demanding users.”
The antenna is available in multiple colors and with multiple connector options.
Handheld’s Algiz 10X rugged tablet now has Windows 8, a faster processor.
Handheld Group is upgrading its Algiz 10X tablet. With the upgrade, the rugged tablet for field professionals now features the Windows 8.1 Pro operating system, which is downgradable to Windows 7. Windows 8.1 Pro offers enhanced features to help users connect to company networks, access one PC from another, encrypt data and more.
The upgraded Algiz 10X also has a more powerful processor that speeds startup and operation, increases software compatibility and doubles processor performance. Its has an integrated u-blox GPS receiver with WAAS/EGNOS/MSAS capability.
Like all of Handheld’s rugged PDAs, smartphones and mobile computers, the Algiz 10X is specifically developed for field workers in industries such as geomatics, logistics, forestry, public transportation, utilities, construction, maintenance, mining, military and security. It is IP65-rated and meets stringent MIL-STD-810G military standards — protected against dust, water, vibrations, drops and extreme temperatures. It has a 10.1-inch touchscreen, weighs 1.3 kilograms (2.9 pounds) and is 32 millimeters (1.2 inches) thick.
“By using the very latest operating system available from Microsoft, customers can now enjoy quicker startup and operation, increased software compatibility and improved support for touchscreen-based tablets, among other benefits,” said Johan Hed, Handheld’s director of product management.
The new Algiz 10X also has the powerful Intel quad-core N2930 1.83 GHz processor with 2.16 GHz boost. This processor allows for both higher performance and cooler running temperatures. Compared to the Algiz 10X’s previous processor, the N2930 more than doubles performance benchmarking, RAM support, number of cores and performance per watt.
“We have dramatically increased performance levels without sacrificing operating time or mechanical design,” Hed concludes. “We have also improved our wireless communication support. Besides 802.11 b/g/n on 2.4 GHz, we now support both 802.11ac and 802.11a on 5 GHz. The upgraded Algiz 10X also supports LTE, which provides substantially faster data speeds, both up- and downstream, and increased overall network coverage.”
Key features of the Algiz 10X version 2:
Powerful Intel quad-core N2930 1.83 GHz processor
128 GB SSD, expandable via microSD
4 GB of DDR3 RAM
Windows 8.1 Industry Pro (downgradeable to Windows 7)
10.1-inch touchscreen with high-brightness MaxView screen technology
IP65 rating and conformity to stringent MIL-STD-810G test standards
LTE capability with a fully integrated modem and antennas
Integrated u-blox GPS receiver and WAAS/EGNOS/MSAS capability
Antenna pass-through connectors for both GSM and GPS
Several connectivity options, including WLAN and BT, USB 2.0 and USB 3.0, VGA and RS232 ports
The upgraded Algiz 10X is available now and orders can be placed immediately.
Handheld Group, a manufacturer of rugged mobile computers, has launched the Nautiz X8 rugged PDA. The Nautiz X8 is a handheld computer with superior processing power, screen performance and battery life, the company said. It is built for tough field conditions primarily in GIS, land surveying, public safety, forestry and the military.
The Nautiz X8 is built to enable efficient and reliable data collection in tough environments. It has an IP67 ingress protection rating, which means it offers complete protection against dust and sand and can withstand immersion in water. It also meets stringent MIL-STD-810G military test standards for overall durability and resistance to humidity, shock, vibration, drops, salt and extreme temperatures.
The Nautiz X8 features a high-performance Texas Instruments 4470 dual-core 1.5 GHz processor. It has 1 GB of RAM, 4 GB of iNAND Flash and a 5200 mAh Li-ion battery that lasts up to 12 hours on a single charge. It comes with a choice of operating systems — Android 4.2.2 or Windows Embedded Handheld 6.5.3.
The device has a large 4.7-inch ultra-bright capacitive multi-touch screen with chemically strengthened Asahi Dragontrail glass, offering users brightness and protection in any field condition. The unit has an ergonomic design and weighs 490 grams (17.3 ounces).
The Nautiz X8 has a dedicated u-blox GPS receiver, Bluetooth 2.0 and 802.11b/g/n WLAN functionality, as well as connectivity through GSM/UMTS or CDMA phone data transmission. A built-in 8-megapixel camera with autofocus and an LED flash lets users capture visual data quickly and easily. This handheld also features an open architecture and an extension cap system that allows for additional hardware connections such as sensors, radios and other add-ons.
Orders for the new Nautiz X8 can be placed immediately. First deliveries will begin in November.
The Nautiz X8 rugged handheld will be shown first at WEFTEC in New Orleans, followed by InterGeo in Berlin.
Presentation to the 11th Meeting of the PNT Advisory Board
The following is an abbreviated transcript of Don Jewell’s briefing to the PNT Advisory Board at its meeting on Tuesday, May 7. The slides from Jewell’s briefing and the other briefings to the board are available at pnt.gov under the heading 11th PNTAB meeting.
First, a prefatory note from Don Jewell:
Author Sets the Scene
The old adage “A picture is worth a thousand words” certainly applies to the atmosphere of a PNT Advisory Board meeting. And in this case, so does the oft repeated and entirely inadequate phrase “You had to be there.”
The atmosphere of an Advisory Board meeting is extremely dynamic. You have a very distinguished board of PNT subject-matter experts who are very passionate about their areas of expertise. Some, like Drs. Parkinson and Schlesinger, the co-chairs, have been involved with PNT and GPS matters for 45 years or more. Therefore, the danger of an abbreviated transcript of an emotion-filled briefing is always unsatisfactory at best, because you miss the give and take, the repartee of experts that have invested much of their lives in this arena. So it is important that the reader understand the context of the questions and answers and sidebar conversations that took place before, during, and after the briefing, to put it in context.
It would be easy after reading this transcript and others during the meeting to put the blame for antiquated PNT equipment on the manufacturers. But nothing could be farther from the truth. The truth is, the culprits here are numerous but identifiable. They are:
1. Outdated government regulations, directives and procurement/acquisition procedures that seriously hamper equipment manufacturers from doing their best and updating equipment as necessary.
2. Timelines that totally ignore the dynamics of Murphy’s Law — a law of ever-shrinking timelines battling a glacial process of ever-increasing requirements bounded by antiquated procurement procedures and fiscal indecision.
In the case of military user equipment (MUE), the warfighters, first responders, and government users are the unfortunate recipients of this morass of near-pandemonium and downright confusion. Dynamic and critical user requirements are sacrificed upon the altar of “the program of record” and an agonizingly glacial government bureaucracy. Be assured that the “program of record” delivered exactly what was asked for by the original RFP and subsequent contract award.
Take Rockwell Collins for instance. Rockwell is a great company, building rugged, reliable, precision instruments. I have flown with Rockwell communications and aviation equipment in various aircraft cockpits for the last 40 years, and they are indeed the gold standard in that arena. Rockwell has been delivering GPS military user equipment since 1978 and the company has always delivered exactly what was asked for. The problem is that the operational and refresh cycle for government user equipment needs is inside the acquisition cycle, and unfortunately exceeds it by a factor of ten — hence Murphy’s Law.
The Defense Advanced GPS Receiver (DAGR) was an excellent device when conceived and was the only game in town as regards jamming and spoofing environments. I am confident that Rockwell would have continuously updated the DAGR and made it relevant today, given the opportunity, which they were not.
In my opinion, government regulations in the area of user equipment, especially electronics and highly dynamic technological areas, need to be drastically altered to follow the aircraft procurement cycle. For example, there are probably 50 or more different block versions of the F-16 aircraft, that in truth are radically different. In some respects the “Block 1” F-16 resembles the capabilities of the “Block 50” version only in that it is an airborne vehicle with wings, engine, and a fuselage. Electronically and technically, it is a totally different aircraft. But the contracts for General Dynamics and now Lockheed Martin were not recompeted every time the user requirements, and hence the capabilities of the F-16 changed. I hope you all agree that would be ludicrous — and yet that is exactly the situation with MUE. When the scope changes, the contracts are painfully and laboriously recompeted, with lag times that make the process laughable — if indeed it were not so sad.
Then there is the government’s serious lack of information and training concerning MUE devices. I have been around GPS user equipment for 35 years and yet I am sure I still do not understand all the capabilities of the Precision Lightweight GPS Receiver (PLGR) and DAGR. Imagine how befuddled a young warfighter becomes when given the devices and only a cursory amount of training, that is not only inadequate but sadly many times misleading or just flat wrong.
In our interviews we founds trainers — those that taught warfighters how to use the PLGR and DAGR — who were not aware the unit could be “keyed” or encrypted for greater accuracy. Of course we also found excellent trainers, but they were the exception to the rule. Who trains the trainers?
Although it sounds trite and seems to be a copout, don’t blame the equipment manufacturers for the current state of MUE. Blame the system and then get involved and help us change it to what it should be.
Good morning, everyone.
A special thanks to Jim Miller, Dr. James Schlesinger and Dr. Bradford Parkinson for inviting me to speak this morning on the future trends of PNT user equipment, particularly as it pertains to warfighters and first responders — certainly a subject I have been passionate about for only…oh, let’s say about 35 years.
Why GPS World?
Ever since the agenda for the PNT Advisory Board meeting appeared online, I have been receiving emails and phone calls asking why I was speaking not as one of the IDA (Institute for Defense Analyses) subject-matter experts on GPS but as the Contributing Editor for Defense for GPS World. Frankly, the answer is simple. Wearing the GPS World hat gives me the freedom to say what needs to be said today, whereas the IDA think tank attribution and publication rules, which are absolutely necessary for an FFRDC (Federally Funded Research and Development Center) to operate effectively and efficiently, would unduly restrict my comments.
Plus, for 21 years GPS World magazine has been the publisher of the definitive GPS user equipment survey for global users. It’s free for everyone to use, and it covers PNT receiver information from 55 global manufacturers with data on all aspects of 502 PNT receivers. And it is a great boon for me personally, as I only receive on average about 50+ emails or letters per month from users simply wanting to know what GPS/PNT receiver they should purchase. It is wonderful to be able to point them to the GPS World Receiver Survey.
Also wearing my GPS World hat, I can easily refer to the several thousand warfighter and first responder inputs we have received over the last 10 years — generally expressing what they would like to see in a GPS/PNT receiver or sometimes specifically the Perfect Handheld PNT Transceiver (PHPNTT), which I first wrote about six years ago (and most recently in December) in GPS World magazine.
Top 10 Warfighter – First Responder Requirements for the PHPNTT
Adhering strictly to the latest fad in government briefing formats, it is now time for me to BLUF, or give you the Bottom Line Up Front. However, being a journalist, I also have to hold something back for the end. So here are the top 10 PHPNTT requirements, in order of preference, as submitted over the last 10 years by thousands of warfighters and first responders:
Mil-Spec rugged – solid state drive – no moving parts
Friendly, intuitive, familiar interface – easy to use
Multi-GNSS – All signals available – space and terrestrial
SWAP friendly, long battery life, with solar charger
Real-time 3D map data, NGA, Google, satellite imagery
Not a stand-alone PNT device
Embedded in a computer with multiple communication capabilities – one must be secure
Must be able to download, store and utilize new applications
Software-defined and expandable
Act as a sensor with automatic reporting
All these “user requirements” are closely related to what our warfighters and first responders don’t like about the current GPS MUE or Global Positioning System Military User Equipment. I state that specifically because, make no mistake about it, the current MUE is strictly GPS-based. However, the current MUE only receives two of the many signals available today on the GPS SVs, and certainly not any of the other numerous PNT (position, navigation and timing) signals also available, which of course is the crux of the issue for user equipment of the future.
Most of the top 10 requirements, and there were more than 50 requirements identifiable in all, are self-explanatory, and time does not permit me to cover them all in detail. But bear with me for a couple of quick explanations. Certainly the rugged requirement is readily understandable, and there are numerous manufacturers around the globe today that make excellent Mil-Spec rugged devices. However, the one I am most familiar with and have been extremely happy with are the rugged units from Trimble Navigation produced in Corvallis, Oregon. Trimble also happen to be a certified SAASM (Selective Availability and Anti-Spoofing Module) supplier as well. More on those units later.
The second bullet concerns the human-machine interface on the current MUE, which is so poor that a Marine three-star wrote me a few years ago to say that in his opinion, “If anyone wants an example of how not to design an operational equipment interface then they should refer to the PLGR or DAGR. Both are consistently and sufficiently horrendous, in my opinion.” I could not have said it better. The PLGR and DAGR use the gold standard for PNT as a signal, but the human-machine interface (HMI) is, in my opinion and in the opinion of thousands of warfighters, so antiquated and non-user friendly as to be almost unuseable. However, the units do work well and provide outstanding signals when embedded with other equipment. They just do not work well as a handheld device. The other items on the list we will cover as we proceed through the briefing.
GPS MUE Historical Perspective
I have been involved with GPS user equipment for the last 35 years, and this behemoth of a receiver was my first unforgettable encounter.
Yes, this huge device is GPS user equipment. Can you imagine? It weighs more than 300 pounds, without the two operators, and was the very first workable GPS receiver produced for the U.S. military by Rockwell Collins, who has been producing GPS MUEs ever since. Which is an example of the prodigious acquisition issues that also need to be addressed, or corrected, if you will. Our antiquated acquisition practices are to blame for many of the failings in MUE equipment today. While I feel it is critical to mention this as a major contributing factor to the state of MUE today, it is also a story for another time.
Other than being the first GPS MUE, the significance of this huge receiver is that in my estimation it is the first and last time the U.S. military possessed a purpose-built military GPS receiver clearly superior to the products being produced by commercial and civil manufacturers for global users.
First Significant Usable and Transportable GPS Civilian Receiver
Fortunately, a good friend and colleague, both at IDA and ION (Institute of Navigation), Philip Ward, came to the rescue of all GPS users in 1981 when he delivered the TI 4100 NAVSTAR Navigator Multiplex Receiver.
The TI 4100 was indeed the first commercially viable receiver that could be considered a transportable by anything other than an aircraft. To be historically correct, there were some backpack models that were very short-lived and not as significant as the TI 4100. The main unit and two antennas weighed approximately 50 pounds and showed promise in station wagons and helicopters. I can see a few folks in the audience smiling, so I will reiterate that the TI 4100 was a significant milestone, both in SWAP (size, weight and power), accuracy and TTFF (time to first fix). TTFF was 15-20 minutes in search mode, however; after the four SVs were located and the unit was initialized, it could consistently present a fix location in just a couple of minutes. Plus, the TI 4100 was immune from most jamming signals of the day — an impressive receiver and accomplishment for 1981.
Evolution of Commercial GPS/PNT UE
Fast-forward several years and the following picture presents a view of how quickly GPS UE developed.
The first unit on the right in the above photo is a Trimble unit that was about the same size as the TI 4100, but considerably more capable. As you follow the units around counter clockwise, you will see that they decrease in size and weight, but what you can’t see is that they also increase incredibly where acquisition and processing speed (TTFF), accuracy and capability are concerned. Note also that you start to see stand-alone units that appear to be antennas with separate handheld display units. This is a feature the commercial manufacturers incorporated over 20 years ago, and in some respects a feature the MUE manufacturers and services are just now considering.
Note also the Garmin GPS wrist receiver (right), which until 2005 was the most prevalent civil receiver in both of the wartime AORs (Area of Responsibility). Compare this Garmin wrist unit to the 300-pound Rockwell Collins unit I first showed you and consider that where SWAP and performance are concerned, the wrist unit is hundreds of times more capable and portable.
Current MUE – Program of Record and the Future
The pictures below depict the current MUE – Program of Record equipment, again both manufactured by, you guessed it, Rockwell Collins. First is the PLGR or the Precision Lightweight GPS Receiver. Second is the DAGR or Defense Advanced GPS Receiver. The third unit, known simply as the “Puck,” is what the U.S. Army would like to field in the next couple of years along with that separate display unit I spoke of earlier. Starting to sound very commercial, right? By the way, the Puck measures only 2 x 2 x 1/2 inches and weighs just a few ounces.
Between the PLGR, which was decertified by the Marine Corps in 2010, and the DAGR, there are approximately 500,000 of these MUE devices fielded today, and yet almost none of them are utilized as handhelds. Our research shows that indeed only 1 in 40 is used as a true stand-alone handheld. Most DAGRs are primarily used to interface with legacy communications equipment, primarily U.S. Army, that calls for fire support, read ordnance, and all the others are either stored or embedded with other equipment, which means the “horrendous user interface,” a common warfighter description, is not a major issue. The bottom line is the DAGR is very good at what it does, it is just that what it does (warfighter quote) “…stopped being functional, when compared with other more capable PNT equipment, almost the day is was delivered to the AOR in 2005.”
While the Puck is certainly a major improvement in SWAP and concept, it essentially provides the same two GPS signals and SAASM capability as provided by the DAGR, just in a smaller form factor, and it does away with the continuously vilified user interface. The Puck technology totally ignores current-day PNT, multi-GNSS platforms and the other 160 PNT signals available today. Review the GPS World 2013 Receiver Survey and you will only find a handful of receivers that are so incredibly limited, and they are invariably produced, you guessed it, for the U.S. government as part of a GPS program or alternate program of record.
MUE: How Not to Build a PNT Device, or Why Warfighters Use Garmins and iPhones
The list you are looking at now is comprised of the first 15 minutes of conversation with thousands of warfighters interviewed over the last 10 years — they just had to tell us what was wrong with the current MUE before they finally got around to telling us what, if they were king or queen for a day, they wanted to see in the PHPNTT. This is not my opinion but the actual words of the warfighters. First of all, understand that the PLGR is a single-frequency GPS-only receiver with a security module (PPS-SM) to access encrypted P(Y)-code for anti-jam purposes. It was initially fielded 1990-2004, replaced by the DAGR in 2005. There are approximately 165,000 PLGRs and 450,000 DAGRs fielded at a cost of more than $1 billion. Now the warfighter comments:
Both the PLGR and DAGR have an antiquated, proprietary OS and “extremely unfriendly — non-intuitive” user interface.
PLGR and DAGR are not functional as handheld units but function well as embedded devices — although typically not networked, and we are not even sure they can be networked.
Example: One STRYKER vehicle variant has nine separate DAGRs incorporated, each with its own antenna and operating totally independently of the others.
PLGR was decertified by U.S. Marine Corps in 2010 due to friendly-fire incidents.
DAGR used today primarily as embedded device only with a “ horrible user interface”:
Monochrome screen, no active maps, navigation direct waypoint only. Provides user with PNT information as coordinates — requires paper map to be an effective tool.
For other than straight-line navigation — time, distance and ETA are incorrect.
Programming/mission planning require special cables, software and a laptop computer.
Additional cables, radios and hardware are required for PLGR or DAGR to communicate.
Proprietary OS — no capability for additional programs to be added or utilize.
SWAP issues — large, heavy, limited battery life (multiple batteries) for typical missions.
TTFF — warm, approximately 2 minutes; cold with almanac download, 30+ minutes.
Position accuracy expressed as PDOP (1-6) on separate screen from PNT data. Nominal accuracy of a coded DAGR is typically about 1 meter or more.
Advantages: Anti-jam and legacy interface capabilities.
So, the bottom line as far as the warfighters are concerned is that if you want to operate legacy equipment that requires a GPS input, such as calling in “fires” or artillery or if you are in a jamming environment, then you need the DAGR or its capability. Our survey shows, however, that only 1 in 40 use the DAGR as a handheld, and yet every single one of our respondents — that’s 100 percent, a rarity in statistics — stated they had a backup unit, primarily a Garmin, until 2005, and then popular backup units were more than likely an iPhone, iPad or Trimble unit.
One of the Most Popular PNT Devices in Theater Today – More than 365M Sold to Date
Today there is no question concerning the most prevalent PNT unit in both AORs. It is, you guessed it, the Apple iPhone and/or the Apple iPad. Let’s take a brief look at the capabilities of this non-ruggedized but still amazing device, which can easily be made Mil-Spec rugged with aftermarket cases and enclosures such as those produced by Otterbox, which I have personally tested and reviewed numerous times.
The attributes you see listed here are for the iPhone and iPad, and are those that assist in some aspect of PNT and/or integrity and accuracy.
Assisted GPS SBAS — WAAS (PNT)
Assisted GLONASS — (SBAS) (PNT)
Digital compass (PN)
Wi-Fi (Communications-Data + PNT)
Cellular (Communications-Data + PNT)
Bluetooth (Communications-Data + PNT)
Skyhook Wireless (PNT)
Three-axis gyro (PN)
Accelerometer (PN)
Pedometer (PN) – Application
Internet (Communications-Data) Skype application (PNT)
Real-time accuracy and integrity representation (PN)
361+ navigation applications in the App Store ready for instant download and designed for iPhone and iPad. The majority of these applications are available at no cost to the user.
All this capability available in just four ounces — truly a SWAP and capability revolution.
Apple logo
Of course, what really makes the list of iPhone and iPad capabilities revealing is that the first two attributes alone more than double the number of PNT signals received and utilized by the iPhone versus the DAGR, and that number does not account for the GPS L2C (second civilian signal) and L5 (DOT safety of life signal) with CNAV, which when activated will be the strongest GPS signal broadcast to date. The CNAV data is an upgraded version of the original NAV or navigation message. It contains higher precision representation and nominally more accurate data than the nominal NAV data. There are 26 more PNT satellite signals available today in the iPhone and iPad, and they are comprised of multi-GNSS signals and augmentations. The kicker for me is that in addition to all the additional space signals are terrestrial signals, and almost any map or grid system the user desires. Plus there are apps (software applications) that translate between grid systems. And if you don’t like the interface of the navigation program you are using, then there are literally 360+ other choices. I also find the pedometer function interesting, in that firefighters now use this capability along with the Blue Force Tracking app in buildings when they are momentarily without GPS, GLONASS (Russian GNSS), WAAS (U.S. Wide Area Augmentation System), EGNOS (European Geostationary Navigation Overlay Service) or other SBAS (Satellite Based Augmentation System) signals.
Realistically, to defeat the current unencrypted MUE today, an adversary only has to jam one GPS signal, but to defeat the iPhone or iPad an adversary has to jam all the GPS signals, all the GLONASS signals, all the Wi-Fi signals, all the mobile 3G and 4G CDMA and GSM (read as different mobile telephone systems) signals and still the iPhone or iPad will use the accelerometer, gyro, compass and pedometer functions to determine position. Indeed, it will continue to function as a PNT device. All this in just four ounces at a cost about one-sixth of the DAGR displayed on a screen that has 100 times greater resolution and is in color. Remember, the DAGR has a monochrome screen. No contest. Plus try saying, “Take me home, Siri” to a DAGR and see what happens.
Garmin
What about Garmin, you ask? At the beginning of the current conflicts, Garmins were the prevailing additional PNT device. There are still thousands of them in theater, and they have saved many lives, as we will see. However, just look at this sales chart for smart PNT devices.
ProductsTotal Units Sold (approximate)
iPhone (since 2005) 250,600,000 (M)
iPad (since 2010) 115,000,000 (M)
Garmin Sales ~100,000,000 (M)
iPhone/iPad App Store (since 2008)
Downloads of the 361+ navigation apps 2,200,000,000+ (B)
(Note: Total App Store downloads will exceed 50 billion by the time this is published.)
The Future
The future of PNT devices globally, especially for warfighters and first responders, is clearly with rugged mobile devices capable of downloading, storing, updating and utilizing applications. The Garmin cannot do that, although it can be updated, and just look at the numbers. Garmin started business as a GPS device provider in 1989. In that time, while branching out into marine and aviation devices, some of the best in the world for those purposes, they are still primarily GPS only (with SBAS). They have sold approximately 100M devices in 24 years compared to Apple’s iPhone and iPad numbers, which total more than 365M devices in less than eight years. The iPad alone outsold all Garmin products in just three years. I confess that I happily own several Garmins, think that are fantastic PNT devices, and it is really tough to beat the $99 wrist Garmin. When all is said and done, the Garmin gives you better information in a non-jamming environment than the DAGR. And Garmin units are still saving lives. Take this vignette from SSG Kyle Dorsch:
“My name is SSG Kyle Dorsch…a Reconnaissance team leader in the 2-30 Infantry Battalion, 10th Mountain Division, deployed to the Logar province, Afghanistan. I have used my Garmin eTrex Vista H throughout my deployment…it has been a lifesaver in more than a literal sense. In fact, there isn’t a leader in our establishment without a Garmin product…my Garmin guided me and my four-man team seamlessly through some of the toughest areas of Afghanistan…it also literally saved my life.”
SSG Dorsch goes on to explain that the eTREX, which was placed strategically on his combat vest, actually stopped an enemy bullet meant for him, and just like Timex the eTREX kept on ticking.
My Obligatory Caveat
Note that SSG Dorsch has always had a Garmin with him in theater and indicates that his leadership has as well. There is no doubt the eTrex saved his life, literally. However, I would never tell a warfighter to not use their government-issued MUE. In a severe jamming environment, it may prove to be a lifesaver, and it may be the only equipment that interfaces with legacy communications and fire support equipment. Take that advice for what it is worth today, because hopefully this will not be the case much longer.
DARPA and Smart COTS Devices on the Battlefield Now
DARPA (the Defense Advanced Research Projects Agency, the real inventors of the Arpanet and the Internet), a much-storied DoD research arm, launched an effort recently called “Transformative Apps.” It developed a few dozen smart applications that work on a number of mobile devices. In addition to mapping, navigation and smart routes, the apps identify explosives and various weapons, and help navigate and locate parachute drops.
A screenshot of the DARPA Smart Routes application. The green routes are safe routes and the red are routes that have been traveled too many times or indicate where problems may exist.
DARPA builds prototypes that are transferred to the Services and become official applications used by hundreds of thousands of warfighters. The challenge is to rapidly adapt COTS (commercial off-the-shelf) technology to the unique circumstances of the military, which often operates over large, hostile areas with little to no formal communications infrastructure.
DARPA reports that more than 1,000 war fighters in Afghanistan now use the DARPA Transformative Apps technology as it continues to be rolled out to the Services.
The most interesting aspect of DARPA’s participation in PNT software is that it will definitely accelerate the multi-GNSS and all-signals-available scenario, because it is not constrained by woefully out-of-date DoD regulations. DARPA does what is smart, what cutting-edge technology will support, what makes sense, and ultimately what saves lives.
The U.S. Department of Defense expects in coming weeks to grant two separate security approvals for Samsung’s Galaxy smartphones, along with iPhones and iPads running Apple’s latest operating system — moves that would boost the number of U.S. government agencies [ed. legally] allowed to use those devices.
In my humble opinion, this announcement is simply outstanding…albeit about 10 years late to need. Indeed, Ms. Teri Takai, the current DoD CIO (Chief Information Officer) gest it and is trying hard, but she can’t do all the heavy lifting alone.
Old Adages Die Hard
I remember an old GPS adage that portentously proclaimed, “If it is not supported on the GPS satellite, it cannot be supported in the user equipment.” Unfortunately, there are those still holding to this totally fallacious belief. Today in the current budget environment, amazing capabilities are being implemented with user equipment that multiply the capabilities of the PNT satellite, other satellites and space signals, terrestrial signals and synergistic augmentations. Indeed, the total price of the PLGR and DAGR program combined would barely pay for some NRE (non-recurring engineering) costs and two launches of the GPS III satellites that should be ready for launch in 2014. Today we need to look even harder at what is doable with user equipment, especially in the military, because it is all we can afford. As Winston Churchill was once quoted as saying, “Gentlemen, we have run out of money; now we have to think.” However, having said that, let’s not forget that the multi-GNSS environment has multiplied many fold the number and capabilities of PNT signals on orbit today.
PNT User Equipment TRENDS — Space SIGNALS available
Jim Doherty, USCG Captain retired, and I are friends and colleagues at the Institute for Defense Analyses (IDA). We are both old retired navigators as well. We both still have the skills to successfully navigate an aircraft or ship, for that matter, from San Francisco to Tokyo using only a sextant. While we are proud of that talent or ability, one that very few possess today, we would much rather accomplish the feat with an exceptional multi-GNSS device, and they exist today like never before. These next lists show all the signals that are available today compared to what the GPS MUE can receive and use for PNT purposes. Plus, Jim and I both share a firm belief in another old navigators’ adage: Receive Everything – Trust Nothing!
Civil-commercial multi-GNSS UE receives more space and terrestrial signals than U.S. GPS MUE.
GPS MUE “officially” utilizes L1(CA), L2 P(Y) with SAASM.
There are NO commercially viable M-code receivers available today and there will not be for several years to come.
PNT civil UE philosophy: Track and use all PNT signals available.
GPS L1-CA/L2-codeless and ready for L2C, L5, L1C (GPS III & QZSS)
SBAS (WAAS, EGNOS, MSAS, GAGAN, SDCM) + NDGPS & many other augmentations
GLONASS L1/L2/L5
Galileo E1/E5 (CBOC & Alt BOC)
Compass B1/B2/B3 (carrier signals only- no full signal specifications)
And do not be deceived: there are plenty of PNT receivers available today to receive all these signals and they have existed for some time. Equipment manufacturers have been ready to receive, process and utilize all the GPS and multi-GNSS signals for years. For example, Trimble built and shipped an L2C receiver in 2003, and that signal has still not been activated on any U.S. GPS payloads although, as we heard from Major General Marty Whelan (USAF – AFSPC/A5) earlier today, General Shelton (USAF), the four-star commander at AFSPC (Air Force Space Command) has announced a six-week test of the L2C signal and full CNAV message in June of this year. A great step forward.
One of these days we might even catch-up with the Japanese – more on that in a moment.
Trimble built and shipped receivers for GLONASS signals in 2006, even though GLONASS did not reach FOC or Full Operational Capability until late in 2010. A designation it is having serious problems maintaining. Trimble also ships L5 receivers as well as commercial SBAS receivers that result in extremely accurate and reliable positions. Lest you think all these signals have gone to waste, remember that Japan’s QZSS-1 broadcasts both L2C and L5 with a full CNAV message today, and the Trimble receivers and others with the multi-GNSS capability work well with those signals, as we shall see.
Global Virtual Reference Stations
Trimble (VRS) and John Deere (StarFire) PNT receivers have the capability Trimble has designated as Global Virtual Reference Stations, which — along with real-time kinematic (RTK) processing — provide users with an unprecedented number of signals and a real-time processed signal with corrections. This results in centimeter-level accuracy for any of their receivers that have the capability to receive and process the signals. For both manufacturers, that will soon be almost all of their receivers. Sure, there will probably be a small monthly fee involved, but the accuracy difference between 1 meter (~3 feet) and 3 centimeters can mean life and death if you are unlucky enough to be in the collateral damage zone or in the sights of a Hellfire missile during war time.
Multi-GNSS SVs and Signals in View
To highlight this point, just glance at the following graphical log file generated by software in the latest Trimble Multi-GNSS PNT receiver. The chart depicts a log file from a receiver located in Singapore. The location is significant only because in that location the receiver is in full view of the Japanese QZSS-1 PNT SV and all its extra U.S. originated PNT signals (L2C & L5) mentioned earlier. This particular Trimble receiver is networked and reports results automatically and continuously to a web page, while receiving GVRS updates and corrections plus other PNT information, such as an updated almanac, over the same network. The question becomes, is it a PNT device with a computer and embedded communications? Or is it a computer with communications and an embedded PNT function? You be the judge. Regardless of which you choose, this is the future of PNT and MUE.
This civil receiver reports 40+ SVs with 169 separate signals in view and usable. This does not count the number of Wi-Fi and/or GVRS signals it is capable of receiving. Meanwhile, a GPS MUE receiver in the same location only observes a total of 10 SVs it can process for a total signal count of 20. However, one of the key points on this log depiction has to do with integrity. Notice the orange and red lines. They indicate that the receiver has labeled these signals as “suspect” and has automatically dropped them from the solution for any of a host of reasons — a failed integrity check, jamming, spoofing, wrong way path, a runaway clock, etc. You name it, and if it is suspicious, the receiver will drop that SV and its signals from its PNT calculations. Built-in integrity.
The obvious question becomes just how accurate is this Trimble receiver over a 24-hour period? The next graphical log file denotes that it is accurate within 3 centimeters.
Trimble multi-GNSS receiver web page log file denotes continuous availability of PNT signals with an average accuracy of 3 cms.
Assured PNT
When we asked warfighters what was more important to them in a combat zone — availability or accuracy of the PNT signals, the answer was, not surprisingly, both. But, of course, they need to receive the signal first, and then they can worry about accuracy.
So, if you were Ms. Teri Takai and you were worried about “assured PNT,” would you rather do that with 20 signals from 10 SVs or 169 signals from 49 SVs and some very strong, difficult to jam, terrestrial signals as well — adding up to, on average, 33 times more accuracy than the GPS-only signal? To me, the answer is obvious. And of course, all that is on the line with every mission the DoD performs, as is the safety of our critical national infrastructure as this next chart depicts.
Assured PNT or lack thereof impacts all missions, across all platforms and domains
Assured GPS MUE PNT today depends on:
L1(C/A), L2 P(Y), SAASM (Future M-Code)
Accuracy ~ 1m
Assured Multi-GNSS MUE PNT with all signals available depends on:
GPS L1/L2/L5/L1C/L2C/M-Code/SAASM
SBAS (WAAS, EGNOS, MSAS, GAGAN, SDCM+)
GLONASS L1/L2/L5
Galileo E1/E5 (CBOC & Alt BOC)
Compass B1/B2/B3
QZSS GEO – L1 CA/C/SAIF, L2C, L5, LEX Pilot
Two-way communications, Networking, PNT servers, each PNT device with unique IP address and each PNT device serves as a sensor
Software definable devices
Multiple software applications (Apps)
Accuracy ~ 3 cm
Army Making Strides
I spoke above about DARPA getting into the PNT business, and that is a good thing. But how about the largest military user of PNT, the United States Army? The U.S. Army is making some interesting changes as well. The Army announced a few months ago that there would be no more purchases of DAGRs, and that it was pursuing smartphones as a communications and small computing platform as well as an alternate PNT tool and display device. This is where the Puck comes into play.
While it is a wonderful idea I fully endorse, the problem with the Puck is that under the current design scheme it will still only transmit the current two GPS signals to a smartphone or other PNT display device. And warfighters lament that it is another device run by batteries for which our warfighters need to carry spares. Why not make the Puck a multi-GNSS device? we asked. The answer we received is that it would make it too power hungry and just require more batteries. So to misquote Shakespeare “…for want of a battery, the war was lost?” The Army is definitely on the right track, but they need to figure out how to make the Puck a multi-GNSS device. Can you say Lithium ION and solar charger – Hoorah!?
The Army Hub
The Puck is moving in the right direction. However, with the addition of another device, the Army is definitely on the right track. This device is designated the “Hub,” and while it is again GPS-oriented, it contains multiple terrestrial and internal signal augmentations and backups, as the image depicts.
With apologies to the U.S. Army, I unabashedly modified the chart, and I made it very obvious. The red text depicts my addition of a multi-GNSS card or module versus or in addition to the CGM (Common GPS Module) and GB-GRAM or Ground-Based GPS Receiver Application Module. The multi-GNSS card/module already exists today. Several PNT receiver manufacturers manufacture it with 28-nm technology versus the 95-nm technology — for the as-yet-unavailable for about four more years if the rumors are correct — GPS-only CGM. For me, the addition seems to be an easy fix, as there is lots of room in the Hub. But this fix or module (CGM) is years and millions of dollars down the road, versus a solution that exist today.
YUMA 2 or Hub or Both
The solution, frankly, is one of the smart tablets available today from numerous manufacturers — seven, actually, that have the wherewithal to produce a secure multi-GNSS device with a SAASM module.
The Trimble Yuma 2.
This is an example of the solution in the form of a Yuma 2 tablet computer from Trimble, which I am in the processing of reviewing for GPS World. The Yuma 2 has all the multi-GNSS features we have been discussing and more, plus it can in time accommodate all the modules scheduled to be incorporated into the Hub. Why build a whole new display device when the core already exists with many more capabilities than were imagined or real estate would ever allow for the Hub? Plus, it is available today as a rugged Mil-Spec device with a full color, high-resolution touch screen. And in the end it will provide a 3-cm solution versus a 1-meter solution. What more could you want? And it is available today with an outstanding and intuitive interface.
Conclusion – Services PNT UE Trends
I have been focusing on the Army today not simply because they are the biggest U.S. military user of PNT devices, but because they are moving in the right direction for the future of PNT and MUE devices. Of course, all the services and many agencies need a well-thought-out and secure PNT solution, and if we have learned anything it is that one size does not fit all. Indeed, our national security and our national infrastructure depend upon future PNT devices. For security purposes alone, they should have a certain degree of application and signal diversity.
Now let’s review:
Army has a way ahead with an assured PNT program.
Includes end of PLGR and DAGR and adding new networkable devices.
Plans for fourth-generation multi-GNSS and multi-function handheld devices and embedded PNT devices as sensors to include the Puck and Hub.
Marine Corps: Decertified PLGRs in 2009 and attempts to limit the use of DAGRs.
DAGRs used primarily as embedded devices.
Purchasing approved SAASM devices from commercial vendors.
USAF: Outfitted 70% of aircraft with modern, integrated, networkable and upgradeable PNT devices.
Navy: More than 60% of the fleet outfitted with modern PNT networked devices.
The Bottom Line is – One size does not fit all but one conclusion is clear – while GPS may and will always hopefully be the Gold Standard – multi-GNSS solutions are the future.
The Future of PNT Devices
This last list depicts the future of PNT as best as I can define it; indeed, as it has already been defined for us by our warfighters and first responders or, as Kirk Lewis would have me say, government users. The users are not waiting around, nor have they bothered to adhere to woefully out-of-date regulations. It is what they desire, and since their lives depend on it, it is what they should have.
Multi-GNSS — Utilize all PNT signals available.
Space and Terrestrial (GPS, GLONASS, eLORAN).
Traditional and non-traditional (Wi-Fi, GVRS, carrier signals).
Multi-function COTS devices with non-proprietary OS (operating System), intuitive interfaces and Mil-Spec ruggedized.
Multiple methods of communications: Wi-Fi, Skype, 4G, text, auto-text, satellite.
Software Downloads – Applications
COTS applications plus .mil apps store.
Networked devices for SA, updates and PNT,
Real-time satellite imagery and mission data injects.
Defense and intelligence LBS.
Each device will be a sensor on a network,
Automatically report jamming, interference and location data.
Utilize SAASM and anti-jam military signals only as required.
Thanks you for your time and kind attention today. And remember, Happy Navigating!
American Sentinel University reports that U.S. Army Sgt. Scott Fierro first fell in love with Geographic Information Systems (GIS) technology during the Army’s Advanced Individual Training at the National Geospatial Intelligence Agency. Since then, he has dedicated himself to learning as much about GIS as possible. That’s why Fierro, 30, from Tampa, Fla., decided to earn his online GIS degree from American Sentinel University using his military education benefits.
“I chose American Sentinel because it is an accredited school that offers a competitive and challenging Bachelor of Science Geographic Information Systems degree program. I love that it’s online because I move frequently and the flexible online format afforded me the ability to earn my degree and maintain a career,” says Fierro.
Despite working up to 45 hours a week and traveling around 160 days a year, American Sentinel says that Fierro found a way to finish his online class assignments.
“Time management is a big key to my success. Earning my degree and working full time has made for some long days, but it just requires being diligent in your time management and planning ahead for your course work,” he says.
At American Sentinel, Fierro learned skills in high-level digital mapping, data capture, visualization, analysis and geospatial literacy. The college-level knowledge enhanced his ability to analyze, interpret and effectively communicate spatial data sets to U.S. Army and civilian audiences.
Through Fierro’s course work, interaction with classmates and input from real-world faculty, he says that he learned how to prepare for a higher level of professional and team responsibility, while gaining a deeper understanding of how GIS data can be put to meaningful use in the military and for civilian contractors.
“As a GIS student at American Sentinel, Scott was exposed to geo-processing, integration of remote sensing date, spatial analysis, high-level systems and solving research problems,” says Devon Cancilla, Ph.D., dean, business and technology at American Sentinel University. “Our students learn how to manipulate and display geographic data, interpret and use geographic information in scientific contexts that are increasingly used in mainstream industries around the world.”
Using GIS in the Army
Fierro is assigned to the Army Geospatial Center (AGC) and works with the Buckeye program (high resolution aerial imagery and optical remote sensing technology).
At his post, he collects, processes and makes data usable. He also beta tested Socet GXP (digital software to determine the geometric properties of objects from photographic images) version 3.0, 3.1 and the latest release, version 3.2. The sergeant is currently working with geospatial imagery software solutions provider, ENVI to develop training software for the Department of Defense.
He says his biggest accomplishment came in March 2010 when he worked with major civilian contractors to get the Buckeye imagery placed onto the largest and most well-known imagery server in the intelligence community, Web-based Access and Retrieval Portal (WARP).
“This brought Buckeye into the eyes and fairly easy access of over one million users, where prior to this it was only well known and routinely used by maybe 200,000 people,” says Fierro.
The Value of GIS
As Fierro evaluates his future, he realizes GIS is a valuable career field.
“It is tied into everything now,” he says.
Police and fire departments use it to maximize efficiency in response times and target high-risk areas to implement action. State, county and city governments use it for planning roads, water and power. Commercial companies, from oil giants like Exxon to retail stores such as Wal-Mart and McDonalds, have GIS specialists working for them.
Fierro notes that thanks to smartphones and Google Maps that everyone is now using GIS. But no one knows what it is. He likes it that way.
“The fun part of that is they don’t have to know. They just have to understand and/or use simplistic level tools like MapQuest, a Garmin GPS or Google Earth,” adds Fierro.
