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Home • Products • GPS Jamming & Spoofing Detection • BroadSense BroadSense GPS Jamming and Spoofing Detection Sensor BroadSense PRODUCT | GPS JAMMING & SPOOFING DETECTION Frequencies GPS L1, GPS L2 Antenna Integrated or External Screen Real-time visual data Outputs J/S measurements, Custom NMEA message via USB or UART ANY QUESTIONS? GET QUOTE About BroadSense is a GPS jamming and spoofing detection sensor designed to provide real-time and historical situational awareness data. Utilizing sophisticated GNSS receivers and patented jamming and spoofing detection algorithms, BroadSense can detect when the GPS signal or GPS spectrum is compromised. Applications – UAV Platforms – Dismounted Warfighters – Cell Towers ​ – GPS degraded or denied environments Features – Advanced RF front end (AGC, LNA, etc.) – No RF calibrations required – Low Size, Weight and Power (SWaP) BroadSense detects interference, data anomalies and inconsistencies, GPS simulators, jumps in position and time, and everything in between Algorithms rigorously tested and field-proven for over a decade Regularly updated to conform to new and emerging threats Extremely easy to integrate and operate Protect Proactively An increased number of GPS jamming and spoofing attacks have been reported and documented in recent years. High-quality software-defined radios (SDRs) capable of GPS jamming and spoofing are more affordable than ever. Open-source projects have turned these low-cost SDRs into GPS jammers and spoofers. Without the ability to detect jamming or spoofing, PNT systems can be unreliable due to reporting errors from the GPS receiver. It is more critical now than ever to ensure the necessary precautions are taken to protect these systems. RESOURCES Early Prototype Demo Button Watch BroadSense Nano in action demonstrated using BroadSim to generate interference signals. Click to download the BroadSense data sheet. VIEW DATA SHEET

Doppler Effects on Spaceborne PNT Applications DOWNLOAD PDF By Joshua Prentice Since the very first space missions positioning, navigation, and timing (PNT) have been crucial for spaceborne applications. Traditionally, space vehicle PNT has been achieved through various combinations of ground stations, optical navigation, onboard high-precision clocks, inertial measurement units, and other methods. Only recently, however, has existing global navigation satellite systems (GNSS) been added to that list. GNSS constellations were designed to provide PNT for Earth-borne applications taking place on the ground, sea, or in the atmosphere. As such, those GNSS waveforms are primarily aimed toward the Earth, but there is a small amount of spill-over of the main lobe beyond the silhouette of Earth and into space. Additionally, the side lobes of most GNSS waveforms are also broadcast into space beyond Earth. Because these signals are visible from orbit, they can conceivably be used for the PNT of space vehicles. In terms of spaceborne navigation from GNSS constellations, there are generally two main orbital regions of concern. Altitudes between Earth and the GNSS altitude, known as being under the “canopy”, and altitudes above the GNSS canopy as shown below in Figure 1. Figure 1: Below and Above the GNSS Canopy When orbiting the Earth underneath the GNSS canopy the receiver antenna must point “skyward” towards the GNSS constellations. This scenario is more closely related to traditional GNSS navigation, although satellites will rise and set more frequently. The full spectrum of these signals is available with the advantage of stronger signal strength compared to surface and low-atmospheric operations. In scenarios where the receiver vehicle is orbiting above the GNSS canopy, navigating based on GNSS constellations becomes much more difficult as the only available portions of the waveform are the main lobe spill-over and the side lobes. For simplification and to limit the scope of this tech brief, the primary area of concern will be space vehicles in geocentric orbits beneath the GNSS canopy. When navigating from GNSS signals Doppler shift is always present no matter how close to the GNSS canopy the receiver is. However, when the navigating receiver is traveling at velocities necessary to maintain a stable orbit, the Doppler shift is much greater. Figure 2: Doppler shift diagram The Doppler shift change in frequency can be expressed as (Parker, 2017): In equation (1) 𝑓₀ is the source carrier frequency, Δ𝑣 is the relative velocity of the space vehicles, and 𝑐₀ is the speed of light. This equation does not account for ionospheric and tropospheric effects encountered when GNSS signals pass through the Earth’s atmosphere. When considering equation (1) for multiple scenarios and orbital altitudes, the speed of light is a constant, and depending on the GNSS constellation being used so is the source carrier frequency. Thus, the biggest factor affecting Doppler shift is the relative velocity of the space vehicles. Because the satellites that make up GNSS constellations are held to very strict orbits with known orbital velocities and those orbits are maintained throughout the lifetime of the constellation, the determining factor of the relative velocity for any given mission is the orbital velocity of the receiver vehicle. It follows that the goal in computing a theoretical maximum Doppler shift a spaceborne receiver may encounter is to maximize the relative velocity between the receiver vehicle and the GNSS vehicle. A scenario that would accomplish this would be a receiver vehicle in very low earth orbit (VLEO) tracking GNSS signals. Spaceborne missions taking place in LEO are a unique case of GNSS PNT due to the high relative velocity compared to the GNSS constellation vehicles while still being beneath the GNSS canopy. The dynamics of such a scenario are some of the highest that a receiver may experience during typical PNT operations. As such, the Doppler search space of receivers deployed in LEO must be much wider than needed for ground, sea, and airborne missions. One example of a very low earth orbit mission (VLEO) is the Gravity Field and Steady-State Ocean Circulation Explorer (GOCE). The GOCE mission required extremely precise orbit determination to carry out its scientific objective of mapping Earth’s gravity field to an accuracy of 1-2 cm. The GOCE space vehicle maintained an average orbital altitude of 255 km, placing the average orbital velocity around 8 ᵏᵐ⁄ₛ (European Space Agency, 2022). The GOCE mission tracked GPS signals to assist in orbit determination. GPS satellites orbit at an altitude of 20,200 km with an average orbital velocity of roughly 4 ᵏᵐ⁄ₛ (US Space Force, 2022). Figure 3: GOCE Missions in VLEO have much shorter durations than other spaceborne missions due to the need for constant orbital maintenance maneuvers to counteract the atmospheric drag, and as such, it can be considered the lower limit of possible orbital altitudes. To estimate a maximum possible Doppler shift the worst possible case scenario would be the receiver satellite travelling in exactly the opposite direction (±180°) of the GNSS vehicle. While this is generally a very rare situation some space vehicles do travel in non-standard orbits, so it is possible. Thus, the relative velocity of the space vehicles can be expressed as: Where: So that: Note that all velocities are expressed as linear for simplification. With an established relative velocity, the maximum estimated Doppler shift can be calculated using the following values: Calculating the Doppler shift using the equation (1) results in: With a worst-case-scenario Doppler shift of 63 kHz, it is imperative to ensure the receiver being placed into orbit can perform under such conditions. Skydel Simulation Engine of the BroadSim product line is capable of simulating spaceborne scenarios, even under conditions where Doppler shift is maximized. One of the default vehicle profiles within Skydel is an Earth-orbiting spacecraft with highly customizable Keplerian elements to define the exact orbit thereceiver vehicle will experience. Should the default spacecraft profile not provide enough customization, Skydel can also be interfaced through hardware in the loop (HIL) where exact positions are pushed tothe simulator to simulate the specific trajectory of a receiver vehicle. Unlike some simulators where the Doppler shift will have to be either predetermined or manually added to the scenario, Skydel handles Doppler, ionospheric, and tropospheric effects automatically based on the scenario without requiring user input. Figure 4: Skydel Screenshot LEO and VLEO missions are becoming more and more popular especially in the fields of PNT, from both from a provider and user standpoint. To make sure those missions will have sufficient PNT capabilities advanced receivers will need to be used and new receivers will be developed to fill specific roles and advance current capabilities. While the Doppler shifts experienced by receivers on these missions will be high, robust testing to ensure mission success is capable using BroadSim simulation products powered by Skydel. References European Space Agency. (2022). GOCE Facts and Figures. Retrieved from https://www.esa.int/Applications/Observing_the_Earth/FutureEO/GOCE/Facts_and_figures Parker, M. (2017). Digital Signal Processing 101. Elsevier Inc. US Space Force. (2022). GPS: The Global Positioning System. Retrieved from https://www.gps.gov/systems/gps/space/#orbits DOWNLOAD PDF

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Addressing Assured PNT needs through Open Standards DOWNLOAD PDF By Brent Abbott Executive Summary With all military services actively focused on modernizing system capabilities and bringing the latest enhanced capabilities to the warfighter, Orolia continues to align our capabilities to include the integration of Military Code (M-Code) and advanced sensors to maintain trusted and assured PNT data even in a GPS denied and/or threatened environment. The benefits of assured PNT can be realized and addressed through the adoption of open standards. Section 1 of this document describes the need for assured PNT in any modernized system. Section 2 describes the adoption of open system architectures and its impact on process and business rules. Section 3 describes the adoption of SOSA and FACE and the impacts on competition generation. Section 4 covers the ability of the Air Force to rapidly innovate and plan. This document is intended to guide engineering staff, integrators, and decision makers in recognizing the need for assured PNT in modernized systems. The adoption of open standard elements leads to improvements in technical performance and sustainment of systems through the use of assured PNT in modernized systems. Section 1 - Assured PNT backbone Assured PNT is more than just beneficial. It is an integral part to any system as the basis of assured position, navigation and timing needed to maintain system operability. Position and navigation are required to update the warfighter with critical, real-time accurate location that can be used to act and react as necessary. Timing, arguably the most critical piece, ensures that the combination of system components operate at the highest capacity possible. Maintaining high operational performance is paramount to warfighter safety and success. Achieving and maintaining high operational performance is not an easy task. With each new mission, the environment will have an impact on the PNT solution used to drive system performance. Maintaining the integrity and trust of the PNT solution is of the utmost importance. For example, a simple delay in time of 1 millisecond or more can cause the navigation solution derived from an inertial navigation solution to diverge and provide incorrect position and velocity information. Likewise, the same millisecond (or even microsecond) inaccuracy in time can and will impact the integrity of a radar, EW, or SIGINT system. The need for resiliency is there. The need for a system that the warfighter can reliably trust is there. Through SOSA and FACE, Orolia provides a means for an Assured PNT that can protect, detect, and mitigate the impacts of emerging threats. Figure 1: The importance of integrity in Assured PNT With all military services actively focused on modernizing PNT and bringing the latest enhanced capabilities to the warfighter, vendors and government continue to align capabilities to include the integration of new technologies such as Military Code (M-Code) and advanced sensors to maintain trusted and Assured PNT data even in a GPS denied and/or threatened environment. The A-PNT solution must be layered. These PNT capabilities can be incorporated into an open standard architecture that allows for modular upgrades to any fielded platform. Alignment with an open standard makes this possible. Remaining agnostic to the platform allows for streamlined integration based on mission requirements. Figure 2: The layers of protection in a Resilient PNT solution The most versatile assured PNT card utilizes a layered approach. A timing reference with performance characteristics tailored to the system. A GPS or GNSS reference that can be hardened, easily updated, secure, and encrypted. An integrated sensor fusion platform capable of quick, seamless integration of new sensor and technologies to address emerging needs. An inertial measurement unit (IMU) that can provide high fidelity measurements in at least 6 degrees of freedom. Alternate assured PNT sources, such as odometry and RF signals, that are available and can be coupled and IMU and timing reference to provide reliable data even through GPS degraded and denied environments. A jamming and spoofing detection and mitigation platform, such as BroadShield, that provides integrity monitoring and statistical information both used in the sensor fusion platform as well as provided to other systems through a standard distribution interface. PNT distribution over a standardized data interface allowing for assured PNT distribution across cards. An A-PNT solution is backed by a solid foundation of sensors that play a large role in the performance of the navigation and timing solution. This solid foundation is built around two core competencies - timing and position. For timing, this can be an Oven Controlled Crystal Oscillator (OCXO) up to miniaturized rubidium oscillators (mRO) and chip scale atomic clocks (CSAC). There are trade-offs that should be considered by a system designer which will determine which timing reference to use. Two of these items, phase noise and stability, are important for different reasons. Phase Noise – Phase noise is the noise generated from the rapid, short-term fluctuations in the phase (frequency) of the timing reference. These fluctuations spread the power of the signal to adjacent frequencies, causing noise and interference. In systems where the frequency reference is used to send and receive signals, the impacts may be viewed as amplitude variations of received signals, channel interference, and random rotations of received signals. Phase noise is unavoidable, but the impacts of phase noise can be mitigated by choosing low phase noise timing references. Stability – Stability can be ability for the timing reference to transmit at the designated frequency for the entire life of the device without any deviation. Short-term stability, frequency accuracy, and aging are important for signal integrity and co-channel interference. In systems that require very accurate frequencies with little drift or accurate phase coherence may look for stable timing references. Phase Noise and stability are important criteria to take into consideration but not all timing references support both low phase noise and stability. To complicate matters, vibration and system dynamics will have a large impact on the performance specifications for both phase noise and stability. Each system design has different requirements and using a modular approach, the requirements can be met through a signal A-PNT form factor. Through using an open standard, the difficulties behind integrating different timing references are mitigated by common architectures and platforms that facilitate rapid development, testing, and deployment. For position and navigation, the absolute reference typically used is an IMU. These devices can be described as commercial (automotive), tactical, navigation, and strategic grade. Figure 3: IMU grade comparison (leveraging Petovello) These grades directly correlate to the performance specifications and errors inherent to the IMUs. Figure 4: Comparison of IMU technologies and grades (Passaro) The errors and specifications will have an impact on the drift of the IMU, the lower the bias and noise, the less the IMU will drift. However, there is a trade-off in size, weight and power and cost when using higher grade parts. Not all systems require higher grade, larger IMUs when the smaller IMUs are adequate for the mission. Figure 5: Comparison of IMU technologies and grades (Passaro) An IMU will impact navigation performance in GPS degraded and denied environments when the only sensor to rely on is an IMU. Thus, incorporating other sensors like barometers, alternative signals, and location references can provide high fidelity estimations of position, velocity, heading and orientation. Not all these sensors are available in different platforms, so ensuring a modular approach to the A-PNT solution allows for swapping out different sensors, fusion algorithms, and capabilities to meet the system needs. As technology advances, IMUs capabilities will increase. Systems will soon be able to utilize high performance gyroscope in a small form factor meant for modular form factors. A modular A-PNT solution is the difference between operating over seconds to minutes without GPS versus operating for hours without GPS. Inside the A-PNT solution lies an integrity checking and monitoring solution. Through tests in the lab and during other test event opportunities, interference detection and mitigation (IDM) software must be thoroughly updated to address the ever-present threats. Using updated IDM software, the A-PNT solution introduces dual purpose situationally aware sensor fusion platform and protected system driver for the important PNT data. At a top level, PNT distribution over the VICTORY Data Bus allows for accessibility and information distribution that is agnostic to any system. Taking advantage of an open system architecture allows for system integrators to design systems around performance specifications and mission requirements without the need to also modify system components outside of the PNT card. A multi-layered A-PNT approach is needed to (1) maintain and improve situational awareness, (2) enable GPS denied mission operations, and (3) keep our warfighters safe through threatened environments. A-PNT solutions address these challenges by providing encrypted GPS M-Code signals, multiple layers of protection, and unprecedented capability to defeat and function in the presence of Electronic Warfare (EW) threats. An A-PNT sensor card that adheres to an open standard tackles very important criteria for any system used by warfighters today: Military Off-The-Shelf components – Procurement and sustainability are addressed through use of off-the-shelf components. Flexibility, Scalability and Upgradability – The system is flexible, scalable, and upgradable to newer sensors and technologies with developer support. Ease of Use and Ease of Integration – Easy for the integrator and user to operate with familiarity. PNT subject matter expertise – Allows for integrity and trust of the technology as a system designed around an integrated PNT sensor core. Not all systems are the same. As emerging missions evolve, so must the technology that is relied on by the warfighter. Historically, this has not been an easy task. Modular Open System Architecture (MOSA) has provided a means to address the need for rapid development, test, and integration of new technologies for emerging missions. The benefit of this should not be understated. Rapid development and test leads to simplifying the procurement challenges that confront acquisition efforts. Leveraging the open standards in SOSA and FACE alongside simulation technologies allows the Air Force to be ready when needed. Section 2 - The impacts on culture and practices Organizational structure is very delicate detail. Bureaucracy exists in all large organizations. The most successful organizations are methodical in their approach towards achieving success. These approaches are typically unique to the business or organization as there is not a “one size-fit-all” solution. The impacts of the differences in cultures and practices between organizations can and does impact the timeliness and effectiveness of decisions being made. Altering culture and practices that prevent timely and effective decisions is difficult, but it starts by making open systems available to the Air Staff. In the ecosystem that provides warfighters with the latest and greatest technology, intellectual property is owned by the vendor. This is problematic when trying to develop, test, and field systems for the warfighter. Adopting open standards like SOSA and FACE reduce the restrictions that impact information flow between governing bodies and vendors. Intellectual property is owned by vendors. This makes it difficult for the same information to be shared between vendors, between governing bodies, and between vendors and governing bodies. The goal of SOSA and FACE is to not own the intellectual property of the vendor but to make the interfaces and modules, used by the proposed solution, widely available. In removing the intellectual property barrier and making the interfaces and modules widely available reduces another pain point in the development of products. With known requirements for interfaces and modules, time is not spent on making the design decisions but rather on the development, test, and integration of the solution. This allows for the air fighter to improve speed, quality of decision support, and achieve greater alignment among Air Staff. Orolia had the opportunity to participate in an Open Innovation Lab (OIL) Plugfest. A Plugfest is typically an event, based on a technical standard or system, where the designers of some technology (electrical equipment or software capabilities) test the interoperability of their products or designs with those of other manufacturers. The technical goal is twofold: check compliance to the standard and test the effectiveness of the standard. Besides helping the vendors improve their interoperability, Plugfests help create awareness about the standard and can improve transparency on compliance. These Plugfests can be formal, providing public test scores or informal and private. SOSA and FACE provide opportunities through Plugfests and technical exchange meetings for vendors and government to not only stay informed of compliance and alignment success but also collaborate and innovate. Such opportunities are only made possible through the application of open standards and modular frameworks. During the OIL Plugfest, multiple vendors were asked to provide CMOSS, and SOSA aligned products to integrate alongside other cards and chassis. Years ago, such an event could not exist due to vendor restrictions. Open standards reduced the overhead requirements of designing the electrical and mechanical interface, understanding the software modules, and deciding on the form factor that would be implemented. In as little as 6 weeks, Orolia adapted a boxed based A-PNT solution to a card based A-PNT solution that was plug-in compatible with the system. Systems that adopt the Modular Open System Architecture (MOSA) provided by SOSA, CMOSS and FACE have proven to be modular, easily accessible, and easy to integrate. The end goal of any business or organization may not change, but the methods that may be employed must often adapt. Adaptation does not come easy but is necessary for constant improvement. Section 3 - Addressing long-term strategic competition MOSA is meant to enhance the department’s ability to modify weapon systems effectively. Modularization simplifies system design by making complexity manageable, enables programs to conduct parallel development efforts, and accommodates future uncertainty by allowing incremental changes to a system. A statement from the Summary of the 2018 National Defense Strategy: “A long-term strategic competition requires the seamless integration of multiple elements of national power – diplomacy, information, economics, finance, intelligence, law enforcement, and military. More than any other nation, America can expand the competitive space, seizing the initiative to challenge our competitors where we possess advantages, and they lack strength. A more lethal force, strong alliances and partnerships, American technological innovation, and a culture of performance will generate decisive and sustained U.S. military advantages.” Key edicts from the national defense strategy that can prove paramount to warfighter success. Open standards are a key differentiating factor that benefit both industry and government. As the needs of the warfighter continues to expand, technological capabilities employed by the warfighter must also continue to expand. Be strategically predictable, but operationally unpredictable . Adopting an open standard in SOSA and FACE provides the means to innovate and bring about new technologies. These technologies, either being improvements upon existing technologies or completely new technologies, will allow the warfighter to address this mission critical piece to competitiveness. Frustrating their efforts . Assured PNT is the backbone of any mission critical system. Knowledge of position and time will impact the functionality of any system. As such, position and time are very critical, and very susceptible components to a system designer or integrator. Competitors are aware of such a bottle neck and will try to disrupt these capabilities through this point of weakness. The need to protect, detect, and mitigate against such threats emerges every day. The need to rapidly address, innovate, and deploy the new technologies should not be slowed by proprietary interfaces, communication protocols, and process. Open System Architectures provide a means to counteract and even accelerate development and procurement to ensure success. Integrate with U.S. interagency . This edict expands to all aspects of U.S. interagency, including applying internally as well. The need to identify and build partnerships amongst military entities is an absolute requirement to address areas of economic, technological, and informational vulnerabilities. Such a task must not be hindered by the development or acquisition of systems caused by lack of information sharing and lack of common architectures. The deployment of common platforms, supported by MOSA, facilitates this agenda. Foster a competitive mindset . To succeed, new technologies must be robust and resilient. The key is to out-think, out-maneuver, and out-innovate the competitors. The use of resources to verify compliance and credibility is paramount to ensure any newly developed technology is deployable. New technologies can be developed using simulated environments without the overhead of working through proprietary methods which inevitably delays the development process and loses the competitive advantage. Using internal testing and hardware-in-the-loop capabilities that can emulate real world threats, developers and integrators can take that next step to developing resilient and assured capabilities. GPS simulators, either used on mobile test platforms or coupled with hardware-in-the-loop capabilities to simulate inertial movement, can shorten the development and testing that would be required for final integration. An evolving technological capability is an absolute requirement. Minimal impact to system interoperability is a key goal to ensuring that the edicts mentioned above are achieved. By allowing for modular open system architectures, rapid improvements can be made to A-PNT cards that include: Encryption – Layering and improving encryption methodologies (such as upgrading receivers in the field), it would be possible to harden GPS. A robust PNT ecosystem allows for a unified effort to improve encryption through affordable solutions. Threat Detection and Mitigation – Various algorithms can drive and improve filtering and help operators detect potentially malicious interference in navigation and timing systems. Through modular software components and hardware architectures, updating threat detection and mitigation capabilities using algorithms and layered PNT remains seamless. As new threats emerge, protecting the A-PNT through on-board interference detection and mitigation algorithms is a need. Improved signal processing – Emerging tools on the consumer side have improved the ability to process radio frequency signals. The NATO Research and Technology Organization points to improved signal processing as one of several key measures needed “to boost the resistance of GPS to [adversarial] jamming technologies.” High-end simulators can help the military to test such capabilities and get them into the field more quickly. Improved signal processing could also support more robust uses of PNT data leading to more effective systems. Higher receiver bandwidth, more accurate position and navigation, and phase coherent timing solutions are all results of the improved signal processing. Using analytics and modeling and simulation analyses, continuous testing can be performed to challenge the current systems and the potential to create new requirements to provide the correct PNT information. Advanced antennas – An advanced antenna creates focused beams and antenna patterns, focusing on where the satellites are and avoiding any potential interference. Strategically predictable yet unpredictable with the ability to adapt quickly. A high-level view of this approach and the different PNT information opportunities can be found in Figure 6: Figure 6: Available assured sensors for more robust solutions Each individual item adds a unique solution that is incorporated into the PNT solution provided by an A-PNT card. With opportunities to use these sensors, the ability to adapt, foster competition, and frustrate the competition is easier to achieve. While not all sensors may be available all the time, having choices allows for an adaptable solution that remains unpredictable and fosters interagency communication. Finally, the use of GPS simulators and other various test events drive collaboration among government and vendors alike. The Air Force must take advantage of operational tests that exercise the new technologies. With modular technologies and open, available standards that vendors have access to, the Air Force can quickly test these new technologies, fostering not only an atmosphere of collaboration but competitiveness as well. Section 4 - Preparing for the future starts now The goal is for any leveraged system to be the state of the art. Integration of the newest sensor and system technology, the highest operational performance, and the advancement of software design and implementation are of the utmost importance. These goals are shared both by vendors and government alike. Despite the common goal set, the approach has been different. As each approach is different, systems today result in tightly coupled integration without portability and flexibility. State of the art at the cost of flexibility decelerates the transition from the force that exists today to the Air Force the nation needs. To achieve technological preparedness, the groundwork must be laid now. Adopting a common framework through open standards is a means to do so. Utilizing a standard reference architecture helps remove the barriers prohibiting modularity, portability, and interoperability. Modularity . Software and sensor components drive the capability of the system. Vendor specific software leads to tightly coupled integration which prohibits the modularity of the software and system. The hardware modules must be decoupled from the software components such that software components and hardware modules can be developed and tested independently. This independence cuts down on development time and promotes the development of test tools that can be further leveraged to verify compliance and compatibility. VICTORY, as an example, promotes a standardized software interface. Along with a test tool and standards body, conformance and capability can be tested and verified without the need for specific hardware implementations. This allows developers to continue addressing near term implementation goals without relying on supply chain management or other roadblocks. Portability . Sensor components found in fielded systems are the backbone of the system functionality. These items must be easily replaced and updated to sustain and increase system performance. The same is applied to software components developed for systems and solutions. The need to port existing software solutions to newer processors or platforms will assist in reducing the impacts of supply chain or procurement initiatives. The adoption and implementation of open standards leads to portability between platforms. Ease of portability allows for integrators and decision makers to address emerging needs with resilient, tested, and trusted solutions. As an example, the Orolia C-PNT solution has been ported to multiple different platforms and iterations. The software is built to remain agnostic to sensors such that the inclusion of VICTORY, SOSA, CMOSS and FACE allow for easy portability to more available processors. Interoperability . Communication between components and modules is important for any functioning system. Plugfest opportunities help test the compliance, the interoperability, and performance of newly designed systems. Such events may only exist due in part to the adoption of MOSA and standards that are managed and agreed upon. As open standards bodies, SOSA and FACE host opportunities for vendors and government to test this interoperability. A key importance of interoperability is found in the ease of replacing technologies as well as updating technologies. For example, if the need arises to swap out an inoperable sensor or the need to update a sensor itself with a newer version, the interoperability of the sensor card is important to reduce integration and development time. Take, for example, the Modular Open RF Architecture established through SOSA. Figure 7: The MORA topology The VICTORY Position Navigation and Timing (PNT) is abstracted from the system software component types such that an end user can address and update components through a common standard data bus. The only limitation for an A-PNT solution to be updated or upgraded is the adherence to an established standard in VICTORY. With the communication and component level standardized, the three key aspects of modularity, portability and interoperability can easily be addressed with no impact on other devices or components of the system. The importance of removing these barriers allows for the Air Force to transition to the next level and take advantage of the state-of-the-art technologies. Removing the focus on integration and development and spending more time focusing on the strategic targets allows for success and safety of the warfighter. Giving the Air Force more time to address the areas of need allow for greater attention to be paid to the near term and long-term strategic mission. Evaluating acceptable levels of risk to mission, force and security is paramount to the success of any organization. Leveraging open system architectures and standards remains beneficial to this end goal. Conclusion Modernized systems require modernized technology. As the emerging needs grow and evolve, the technology needs to advance with it. As a mission critical piece to any modernized system, assured position, navigation, and timing technology cannot be hindered by tightly locked solutions that do not allow for modularity and growth. The capabilities must rapidly and effectively evolve. The adoption of open standards is a unified approach to addressing the needs of the air fighter today and for the future. To rapidly evolve, designers should not be burdened by lack of modularity, interoperability, or information flow. To effectively evolve, decision makers should not be burdened by information flow and process which detracts from more focus on planning and strategy. Promoting the collaboration between industry, academia and government will allow the Air Force to overcome any technical challenge. Such a change in culture and process can be facilitated through the adoption of open standards. They allow us to go fast, be effective, and most importantly, be successful. References ( Please note that the links below are good at the time of writing but cannot be guaranteed for the future .) Modular Open Systems Approach (MOSA) Reference Frameworks in Defense Acquisition Programs, published by the Office of the Under Secretary of Defense for Research and Engineering, Director of Defense Research and Engineering for Advanced Capabilities, May 2020, refer to: https://ac.cto.mil/wp-content/uploads/2020/06/MOSA-Ref-Frame-May2020.pdf Summary of the 2018 National Defense Strategy of The United States, authored by Jim Mattis, refer to: https://dod.defense.gov/Portals/1/Documents/pubs/2018-National-Defense-Strategy-Summary.pdf FACE™ Technical Standard, Edition 3.1 (C207), published by The Open Group, July 2020; refer to: www.opengroup.org/library/c207 Technical Standard for SOSA™ Reference Architecture, Edition 1.0 (C212), published by The Open Group, September 2021; refer to: www.opengroup.org/library/c212 Gyroscope Technology and Applications: A Review of the Industrial Perspective, authored by Passaro, Cuccovillo, Valani, De Carlo, and Campanella. Methods for Accuracy Verification of Positioning Module authored by Patric Jansson Beyond GPS: A Multilayered Approach to Addressing PNT Vulnerabilities, authored by Adam Stone, refer to: https://www.orolia.com/beyond-gps-a-multilayered-approach-to-addressing-pnt-vulnerabilities/ Real-Time Integration of a Tactical-Grade IMU and GPS for High-Accuracy Positioning and Navigation, authored by Mark G. Petovello. About the Author Brent Abbott is an R&D technical lead and manager for Orolia Defense & Security, a leader in Assured Position, Navigation, and Timing products. He has a Bachelor’s and Master’s in Signal Processing and has worked in the DoD space for more than 13 years. He constantly seeks to promote the advancement of technology as seen through several PNT related patents, publications, and presentations. About The Open Group FACE™ Consortium The Open Group Future Airborne Capability Environment™ (FACE) Consortium, was formed as a government and industry partnership to define an open avionics environment for all military airborne platform types. Today, it is an aviation-focused professional group made up of industry suppliers, customers, academia, and users. The FACE Consortium provides a vendor-neutral forum for industry and government to work together to develop and consolidate the open standards, best practices, guidance documents, and business strategy necessary for acquisition of affordable software systems that promote innovation and rapid integration of portable capabilities across global defense programs. Further information on the FACE Consortium is available at www.opengroup.org/face . About The Open Group SOSA™ Consortium The Open Group SOSA™ Consortium enables government and industry to collaboratively develop open standards and best practices to enable, enhance, and accelerate the deployment of affordable, capable, interoperable sensor systems. The SOSA Consortium is creating open system reference architectures applicable to military and commercial sensor systems and a business model that balances stakeholder interests. The architectures employ modular design and use widely supported, consensus-based, non-proprietary standards for key interfaces. Further information on the SOSA Consortium is available at www.opengroup.org/sosa . About The Open Group The Open Group is a global consortium that enables the achievement of business objectives through technology standards. With more than 870 member organizations, we have a diverse membership that spans all sectors of the technology community – customers, systems and solutions suppliers, tool vendors, integrators, and consultants, as well as academics and researchers. The mission of The Open Group is to drive the creation of Boundaryless Information Flow™ achieved by: Working with customers to capture, understand, and address current and emerging requirements, establish policies, and share best practices. Working with suppliers, consortia, and standards bodies to develop consensus and facilitate interoperability, to evolve and integrate specifications and open-source technologies. Offering a comprehensive set of services to enhance the operational efficiency of consortia. Developing and operating the industry’s premier certification service and encouraging procurement of certified products. Further information on The Open Group is available at www.opengroup.org . DOWNLOAD PDF

Orolia’s GNSS Simulators Now Support an Ultra-Low Latency of 5ms ROCHESTER, NY, June 17, 2021 Orolia recently announced the launch of its Real-Time Performance capability that achieves an ultra-low latency of five milliseconds. The feature will be standard on all Skydel-powered GNSS simulators. Skydel is the software-defined simulation engine that powers Orolia’s advanced GNSS simulators including its BroadSim (available via Orolia Defense & Security) and GSG product lines. “Skydel is known by users for its intuitive nature and ability to be quickly re-deployed for a variety of projects. Delivering Real-Time Performance with latency as low as five milliseconds further shows that Orolia is a market leader empowering our customers by exceeding their expectations,” said Orolia Defense & Security Director of Engineering Tim Erbes. Skydel’s software-defined architecture, offering unparalleled flexibility and adaptability, is designed to meet the most demanding GNSS simulation testing requirements in the automotive, military, space and other high-tech industries. Skydel also supports Hardware-in-the-Loop (HIL) simulations without sacrificing ultra-low latency and high-end performance. The user interface boasts a sophisticated dashboard, where the Real-Time Performance graphs are located. The tool enables users to grade the simulator’s performance, interpret data, diagnose inefficiencies, and optimize scenarios on the fly. In the video tutorial , Orolia demonstrates how the simulation engine processes data and how easy it is to read the graphs through its distinct visualization and precise indications. As the system reaches its limits, it remains stable and fully operational, preserving the integrity of the simulation. Erbes said the Real-Time Performance graphs not only instill confidence in the simulator but allow for better integration in the testbed. “For example, instead of just hoping their hardware-in-the-Loop configuration is working, users can view the real-time data and see that low latency is being maintained,” he added. “This feature provides enhanced visibility not only into the performance of the simulation but also into the reliability of the hardware-in-the-loop integration, resulting in a more robust solution. This is critical when generating complex environments with high dynamics, jamming, spoofing, repeating, and alternative PNT sensors.” About Orolia Orolia is the world leader in Resilient Positioning, Navigation and Timing (PNT) solutions that improve the reliability, performance and safety of critical, remote or high-risk operations, even in GPS/GNSS denied environments. With a presence in more than 100 countries, Orolia provides virtually fail-safe GNSS and PNT solutions for military and commercial applications worldwide. www.Orolia.com About Orolia Defense & Security Orolia Defense & Security provides Resilient PNT solutions and custom engineering services to U.S. Government agencies, defense organizations and their contractors. Orolia Defense & Security is authorized to work on the full spectrum of U.S. Government classified and unclassified projects, in addition to supporting strategic partnerships for key defense PNT technologies. www.OroliaDS.com Orolia Defense & Security operates as a proxy-regulated company and wholly-owned subsidiary of Orolia. Contact: Rachael Smith Orolia Defense & Security +1 614-736-3736 VIEW PDF

Defense PNT in Challenged Environments DOWNLOAD PDF By Tim Erbes DOWNLOAD PDF

Home • Products • Inertial Navigation Systems • SpaceNaute ™ SpaceNaute™ Ultra-compact navigation system for space launchers SpaceNaute ™ PRODUCT | INERTIAL NAVIGATION SYSTEMS Gyro bias < 0.01°/h Accelero bias < 50 μg SWaP 3 L / 11 lbs / 15 W ANY QUESTIONS? GET QUOTE About Competitive, accurate and compact, SpaceNaute is the most advanced inertial navigation unit for space applications in the world. Selected for Ariane 6, it offers excellent performance and very high reliability under harsh conditions. SpaceNaute inertial guidance system provides high performance inertial guidance thanks to: ​ HRG Crystal™ cutting-edge technology for foolproof reliability Insensitive to space radiation and vibration Compact and low weight Reliable Rugged Low SWaP HRG Crystal™ cutting-edge technology for foolproof reliability Insensitive to space radiation and vibration Compact and low weight A game-changing new generation SpaceNaute offers the best of its generation, all criteria combined: SWaP, robustness, longevity, precision… Guaranteeing space launchers perfect control over their navigation and orientation in space, SpaceNaute inertial guidance system covers all space applications, from put into orbit to space exploration. Click to download the SpaceNaute ™ data sheet. VIEW DATA SHEET

Orolia Defense & Security ignites new era as Safran Federal Systems at the 2023 Joint Navigation Conference ROCHESTER, N.Y., June 12, 2023 The Leader in M-Code PNT Solutions announces re-brand, introduces Inertial Navigation offering Orolia Defense & Security, a Safran Electronics & Defense company, has announced at the Institute of Navigation’s 2023 Joint Navigation Conference that it will re-brand under a new name, Safran Federal Systems, following its 2022 acquisition by Safran, a global aerospace and defense company. “Though our name and look are changing, our people, our operations, and our leadership team remain the same. The name Safran Federal Systems signifies being part of the Safran Group, a world leader in aerospace and defense, while reflecting what we do best, serving our U.S. Government & Military customers with cutting-edge positioning, navigation and timing (PNT) systems,” said Hironori Sasaki, President of Safran Federal Systems. “We remain fully committed to ensuring the success of our customers and the success of our warfighters. By joining the Safran Group, we are excited to be able to offer an even larger portfolio of industry-leading technology tailored for the U.S. military.” In addition to its Resilient PNT solutions, M-Code/GNSS testing and simulation tools, precision time synchronization systems and navigation warfare (NAVWAR) equipment, Safran Federal Systems is now one of the only companies with a full complement of PNT technologies with proven inertial navigation solutions. “The Safran Federal Systems inertial navigation portfolio now includes the Hemispherical Resonator Gyro (HRG) Crystal™ technology, which leverages state-of-the-art manufacturing and offers revolutionary performance and reliability over existing technologies, for tactical to strategic applications across all military domains,” said Jon Leombrone, Executive Vice President of Navigation Systems at Safran Federal Systems. “With more than 30,000 HRGs produced and over 15 million operational hours, the technology is proven and tested in military applications worldwide.” Safran Federal Systems continues to be the trusted Resilient PNT solution provider for military end users and industry partners, from the lab to the field. Safran Federal Systems continues to operate as a proxy-regulated company, Free of Foreign Ownership, Control, or Influence (FOCI), approved to work on the full spectrum of U.S. Government classified and unclassified projects. Visit Safran Federal Systems at JNC in booth #500 from Tuesday, June 13–Wednesday, June 14. Safran Federal Systems provides Resilient PNT solutions and custom engineering services to U.S. Government agencies, defense organizations and their contractors. Safran Federal Systems is authorized to work on the full spectrum of U.S. Government classified and unclassified projects, in addition to supporting strategic partnerships for key defense PNT technologies. Safran Federal Systems operates as a proxy-regulated company, Free of Foreign Ownership, Control, or Influence (FOCI). For more information: www.safranfederalsystems.com Press Contact: Rachael Smith: rachael.smith@safranFS.com / +1 (614) 736-3736 VIEW PDF

The Inside Scoop on GPS Spoofing Most in our industry are aware of the threat that GPS interference poses, both in the US and overseas. GPS jamming is commonplace. Spoofing, however, is different than jamming in that it can be utilized in a far more devious manner.... (continued in PDF) VIEW PDF

GPS Receiver Testing: From the Lab to the Field DOWNLOAD PDF By Tyler Hohman DOWNLOAD PDF

Home • Products • GNSS Testing & Simulation • BroadSim Solo BroadSim Solo Single-Output Software-Defined GNSS Simulator BroadSim Solo PRODUCT | GNSS TESTING & SIMULATION Simulation Capability All constellations and frequency bands, jamming or spoofing, one at a time, on one RF output Encrypted Military Codes AES M-Code Shared Benefits Intuitive user interface, high-dynamics, comprehensive API and ultra-low latency ANY QUESTIONS? GET QUOTE About Designed to address the permanent challenges that engineers face with laboratory capacity and availability, BroadSim Solo was developed to bring advanced GNSS scenario creation to your desk and propel development cycles. Total Freedom Instead of scheduling time around and limiting use to 1-2 simulators in a lab, an entire team of engineers can have BroadSim Solos at their desks, working on different simulation projects & tasks, while letting the lab simulators run the primary scenarios. ​ BroadSim Solo allows you to create a simulation eco-system that is scalable based on the size of your team, and non-location-dependent, which accounts for the rising popularity of flexible work positions. Empower your entire team by adding BroadSim Solo to your simulation ecosystem. Compact form factor fits nicely at your desk or workstation Remarkably affordable price point Increase performance and drive innovation RESOURCES New Product Press Release Button Learn how to quickly create and automate a multitude of dynamic spoofing scenarios using BroadSim. Terrain Modeling Demonstration Button Learn how terrain modeling is a cost-effective alternative to field testing, demonstrated using BroadSim Solo Click to download the BroadSim Solo data sheet. VIEW DATA SHEET

Surface Vessel Navigation For Defense Applications DOWNLOAD PDF By Anthony Full Problem We Solve In an environment without landmarks, naval vessel crews require precise navigation, autonomy and endurance. Moreover, with the threat on GNSS Global navigation satellite system (GNSS): A general term describing any satellite constellation that provides positioning, navigation, and timing (PNT) services on a global or regional basis. See also signal jamming and spoofing, ship operators need ways to protect against GPS satellite signal threats and ensure that they know where they are and where they are headed. Operating in a GNSS-denied environment presents challenges to most navigation systems, because they can either be jammed, or deceptively guided off course via spoofing attacks. The Argonyx serves as an exceptional navigation solution by providing dependable position and heading data without relying on GPS satellite signals. This allows sea vessels to maintain their course and positional awareness seamlessly, even in the absence of GPS connectivity. The Argonyx offers essential current-location data and guarantees the operational continuity of other navigation equipment throughout the mission. Why Is It Important Accurate navigation and positioning are crucial for strategic mission planning, execution, and coordination with allied units. Navigation errors can lead to mission failure, unintended engagements, or friendly fire incidents. Sea vessels, from nimble patrol boats to massive aircraft carriers, must navigate through diverse marine environments where traditional GPS signals may be weak or obstructed. These environments can range from the open sea to coastal areas near adversaries employing electronic warfare to disrupt GPS signals. Ensuring precise navigation under such conditions is vital for mission success and the safety of crew and vessel. A robust navigation system like the Argonyx, capable of providing real-time location and guidance to the next waypoint, is indispensable for maritime defense applications. Even when a vessel enters a GNSS-denied zone, the Argonyx enables it to proceed along its intended route and minimizes drift, a common issue when external signals are not available for navigation. Over time, relying solely on an internal navigation system without external checks can lead to decreasing accuracy. The accuracy needed for waypoint navigation varies based on specific operational requirements, which we address with our tailored solutions. Of course, there are different grades of accuracy for waypoint navigation depending on your needs. And we’ll cover the most relevant solutions next. How We Solve it Developed for the demanding needs of naval operations, the Argonyx offers reliable route guidance in environments where GNSS signals are compromised. Utilizing advanced inertial navigation system (INS) technology based on HRG (Hemispherical Resonator Gyro), the Argonyx does not depend on external satellite signals for navigation and heading. Instead, it calculates the vessel’s position, orientation, and velocity using onboard motion and rotation sensors. The system provides the vessel’s current location and intended position data to the ship’s navigation or combat management system, maintaining accurate positioning for up to 72 hours. ARGONYX INERTIAL NAVIGATION SYSTEM The Argonyx is a battle-tested INS solution tailored for sea vessels, enhancing their navigation and combat management capabilities. Its rugged design ensures a long and maintenance-free service life. The system achieves exceptional heading accuracy (<0.01° RMS) through HRG Crystal technology and offers quick and adaptable alignment, even in GNSS-denied conditions. DOWNLOAD PDF