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Abstracts for Joint Navigation Conference (JNC) 2023, “Enhancing Dominance and Resilience for Warfighting and Homeland Security PNT,” are due Feb. 3. JNC 2023 is the largest United States military positioning, navigation and timing (PNT) conference of the year with joint service and government participation.

The Institute of Navigation’s Military Division will host the conference June 12-15 at the Town and Country Hotel in San Diego. The event will be open to all conference participants, exhibitors, their employees and related organizations. All materials displayed in the exhibit hall will be publicly released after review.

The event will focus on advances in PNT with an emphasis on joint development, testing and support of affordable PNT systems, logistics and integration. Additionally, the conference will cover advances in battlefield applications of GPS, critical strengths and weaknesses of field navigation devices, warfighter PNT requirements and solutions and navigation warfare.

Abstracts must be written for public release with the intent to present in a Controlled Unclassified Information (CUI) U.S. only environment. Abstracts not approved for public release will not be accepted.

Interested parties may submit their abstracts at ion.org/jnc.

The Cybersecurity and Infrastructure Security Agency (CISA) at the Department of Homeland Security (DHS) recently released a three page “CISA Insights” document titled “Global Positioning System (GPS) Interference.” The January 2022 GPS jamming incident in Denver is discussed on the first page as an example of bad things that can happen and why GPS users should take precautions against interference.

Issued eleven months after the event, the report provides little new information, and leaves several important questions unanswered.

Delay in locating and ending interference

One of the most important questions is why it took so long to locate and end interference from a strong signal impacting such a large area.

The Federal Aviation Administration (FAA) was the first agency to become aware of the issue and the report credits the Enforcement Bureau of the Federal Communications Commission (FCC) with finding and terminating the spurious transmission.

Despite an “established national coordination process,” the interference was unabated for 33 hours.

While the report does not give details of the delay, likely reasons include the large number of agencies involved, diffuse authorities and responsibilities, the lack of a national interference detection system or a GPS/PNT “command center,” and several decades of funding and staffing reductions for FCC’s Enforcement Bureau.

How and why it happened

One of the primary reasons for doing an analysis of an accident like this is to prevent similar events in the future. Yet the CISA report provides no helpful information in this regard. It does not identify the source, nor the chain of events leading to the presumably accidental interference.

Those who might take steps to ensure that their operations don’t accidentally interfere with GPS signals learn nothing from the document.

A similar GPS jamming event occurred in October 2022 in the Dallas area. That one lasted 44 hours and the source was never identified. One wonders if this could have been prevented if the CISA report had been issued earlier and included more information.

Why the general public was not warned

The FAA issued a Notice to Airmen as soon as it became aware of the problem. The CISA report says surface (road and highway), rail, and telecommunications users were also impacted. Undoubtedly other types of users were also affected. Yet despite the outage lasting almost a day and a half, no public warning was issued to inform and protect non-aviation interests.

At a minimum, such a warning could have saved companies a lot of trouble and effort. A trouble report during the event from one public safety system operator provides an example of the unnecessary effort expended because a company did not know about the on-going disruption:

“Approximately 1530 on 21 DEC 22 two of our base transceiver systems began to lose sync. The GPS receivers, control cabling, and surge protectors were replaced with no change to loss of sync. There are no other BTS affected other than three sites in Aurora, Colorado … also problems with the local public safety P25 simulcast systems which have lost GPS lock in this area. Spok provides critical encrypted health care communications at these facilities.”

Warning the public could also help prevent more serious consequences, like the loss of life and property.

Troubling assertion

In this case, no losses of life or property have been connected to the disruption.

Yet the CISA report makes a more affirmative statement that “No accidents or injuries occurred because of the GPS interference incident.”

While we all certainly hope that was the case, and it may well be true, the CISA statement is troublingly certain.

A fairer and more accurate statement would be that “…none occurred, that we know of…” This would acknowledge that GPS is a safety of life system in many applications, and the seriousness of interference events.

Striving to do better

After its discussion of the Denver incident the report says improving GPS interference detection and mitigation is a CISA priority. And they are leading an interagency review to improve things.

This will be an uphill battle.

One challenge is DHS and other departments and agencies have limited authorities. The FCC is legally responsible for ensuring transmitters don’t trespass into unauthorized frequencies. However, its resources are limited and, as an independent agency not part of the administration, its participation in cross-governmental efforts is entirely voluntary.

Another is the lack of a clear, authoritative leader and champion for positioning, navigation, and timing (PNT) issues within the federal government.

Executive branch policy scatters PNT-related tasks thinly across the administration. These are to be coordinated by a senior level executive committee tasked to make recommendations “…to the President, through the Assistant to the President for National Security Affairs, or the Executive Secretary of the National Space Council…”

It is not hard to imagine that the details of PNT policy are rarely, if ever, brought to the attention of the President. This can lead to a stalemate between much more junior White House officials and greatly inhibit action.

Let’s hope the CISA report, limited as it is, highlights for leadership the many challenges faced by folks across government who care about GPS reception and national PNT issues. And that, as they collaborate on good solutions, they get the policy and budget support they deserve.

On Jan. 3, Hexagon and Dayou announced the availability of TerraStar-X Enterprise test beds in Beijing, Shanghai, Anqing and Shenzhen for OEMs in the automotive and micro-mobility industries. Terra-Star-X Enterprise precise-point positioning corrections provide lane-level accuracy with fast convergence for autonomous vehicles and mass-market use.

The availability of the test beds follows the initial announcement by Hexagon’s Autonomy & Positioning division and Dayou of their partnership aiming to deliver GNSS correction services to the Chinese market. Users of autonomous platforms will now have a single correction service that works in China, North America and Europe.

OEMs in China can now leverage the test beds with consumer and automotive-grade GNSS receivers to design advanced driver assistance systems (ADAS), and other products, such as mobile applications, safety-critical solutions and more.

On Jan. 5, DroneShield announced the completion of its Defense Innovation Hub project. This project resulted in improvements to its optical/thermal AI DroneOptID engine, as well as the development of a multi-sensor fusion artificial intelligence engine (SFAI).

DroneShield’s DroneOptID is AI powered and designed for autonomous optical detection, classification and tracking of UAVs. This engine can be integrated with command-and-control platforms, such as DroneShield’s DroneSentry-C2, which the new SFAI engine will become a core part this year.

The $800,000 project was first commissioned in November 2021 by the Australian Department of Defense, under phase two of the Defense Innovation Hub program. DroneShield was contracted to work on AI in multi-domain applications for the counter-unmanned aerial system space and more general military and government agency applications.

On Jan. 4, a Ukrainian intelligence assessment obtained by CNN reported an Iranian UAV, downed in Ukraine last fall, contained technology from companies in the United States and other western countries. The White House has since launched an investigation as to how the technology — including semiconductors, GPS modules and engines — were obtained by Iran.

The components removed from an Iranian Shahed-136 UAV totaled 52, 40 of which were manufactured by 13 different U.S. companies. The remaining components were manufactured by other western companies and companies based in Japan, Taiwan and China.

The United States monitors exports and imposed restrictions and sanctions to prevent Iran from obtaining components for UAVs. CNN reports officials are now looking to enhance enforcement of the sanctions and are encouraging companies to monitor their supply chain, as well as identify third-party distributors who may be re-selling the technology to Iran.

U.S. companies are not alone in having to closely monitor their supply chains. U-blox, a Swiss semiconductor company, made a statement reinforcing its company policy, which bans the use of its technology in weapons. This was after u-blox GNSS modules were reportedly found in Russian UAVs.

On Jan. 9, Honeywell announced it is ready to deliver its EAGLE-M Embedded Global Positioning System/Inertial Navigation System (EGI) with M-code capabilities this year, after the United States Army completed the first test flight.

The Army tested the EGI units with enabled M-code on the MQ-1C Gray Eagle unmanned aerial system and validated it to be deployed on military aircraft. This year, the Army will begin migrating its fleet to the Honeywell EAGLE-M EGI with M-code, as this navigation solution enhances the resiliency of GPS navigation to enemy actions.

The defense technology company has delivered more than 300 EGIs with M-code to customers and will deliver qualified units, featuring M-code GPS, to the Army. Honeywell is a leader in EGI for military applications and has provided more than 45,000 EGI units for several different types of aircraft in more than 30 countries.

On Jan. 6, ROCK Robotic, a geospatial company specializing in lidar-based data processing and high-definition mapping, announced the availability of ROCK Base, a triple frequency RTK base station. Additionally, ROCK Robotic has partnered with the Web3 GEODNET initiative to support critical applications in civil surveying, high-definition mapping, digital twin creation and more.

ROCK Base is a resilient, secure, full-constellation GNSS receiver, capable of tracking signals transmitted from GPS, GLONASS, Galileo, BeiDou, QZSS, and the IRNSS navigation satellite constellations. It includes 1,400 channels, survey-grade antennae, cables and antennae-mounting equipment required to set up a permanent continuously operating reference station location.

To make high-definition mapping more accessible and affordable, ROCK Robotic joined the Web3 GEODNET initiative, the largest decentralized GNSS reference network globally. Under the new partnership, ROCK Robotic customers will have access to the GEODNET base-station network to geo-reference ROCK Robotic’s 3D data products to millimeter-level absolute position accuracy, without setting up ground control points. Additionally, ROCK Base is pre-certified on the GEODNET network.

In October 2022, Raytheon Missiles & Defense, a Raytheon Technologies company, received a $207 million contract from the United States Army for Ku-band radio frequency sensors (KuRFS) and Coyote effectors. The Army plans to equip two of its divisions with KuRFS and Coyote effectors to defend against threats from unmanned aerial systems (UAS).

The KuRFS precision targeting radar and scaled Ku-720 mobile sensing radar provides 360-degree detection, identification and tracking of airborne threats. Coyote Block 2 kinetic and Block 3 non-kinetic effectors can defeat single UAS and swarms at high altitudes and long ranges.

The Army’s Mobile-Low, Slow, Small, Unmanned Aircraft Integrated Defeat System, integrates KuRFS and Coyote effectors with Northrop Grumman’s Forward Area Air Defense Command-and-Control system and Syracuse Research Corporation’s electronic warfare system. This creates a mobile deployed system that provides a complete extended-range defense solution.

In October 2022, Curtiss-Wright Corporation’s Defense Solutions division, a supplier of modular open system approach-based solutions, released the VPX3-673A module. This module is the first to deliver assured position, navigation and timing (A-PNT) along with alternative RF navigation and pntOS architecture.

The VPX3-673A is a rugged, 3U OpenVPX, form factor module, which integrates with existing navigation sensors in vehicles operating in environments with limited or denied access to GPS, to increase assurance in the platform’s PNT solutions. It is designed to ingest positioning and timing data from multiple sensors and output accurate timing and navigation information on the battlefield using VICTORY data messages.

It is compatible with the United States Army’s C5ISR/EW Modular Open Suite of Standards and aligned with the Sensor Open Systems Architecture Technical Standard 1.0.

VPX3-673A includes a low noise chip-scale atomic clock with intelligence provided by Xilinx MPSoc, an alternative RF navigation receiver and a 10-degree of freedom IMU. It supports an internal or external GPS module via a front panel connector. Additionally, the VPX3-673A provides processing resources and sensor interface capabilities needed for operability with a variety of external processing and sensor units.

On Jan. 3, Synaptics released the SYN4778, a small, low power, accurate GNSS integrated circuit for Internet of Things (IoT) devices. SYN4778 is designed to extend battery life, reduce product size, and enhance performance of advanced location-based services for IoT devices, including wearables, mobile accessories, asset tagging and tracking systems, UAVS and transportation navigation.

SYN4778 includes advanced multi-path interference mitigation using L5 band signals from GPS, Galileo, BeiDou, NAVIC, SBAS, and Quasi Zenith Satellite System (QZSS). The chip also uses L1 satellite bands to reduce the time to first fix, as well as the power consumed, improving end-user experience, and enabling product developers to add additional functionality and features to their IoT devices.

This GNSS chip includes LTE jamming and signal filtering, and continuous — highly parallel — search and track of all GNSS channels for greater positioning accuracy for LBS applications, specifically in urban environments. Additionally, it offers support for multiple operating systems and third-party software to enable a broader range of application-optimized IoT devices.

SYN4778 is currently only available to select customers.