Kategori: Nyheter

Inertial Labs has introduced its ADC inertial navigation system (INS) designed to calculate and provide air data parameters, including altitude, air speed, air density, outside air temperature (OAT) and windspeed for avionic applications.

ADC’s compact form makes it easy for users to integrate into existing UAV systems with strict size and weight requirements. The INS calculates the air data parameters using information received from the integrated pitot and static pressure sensors, and an outside air temperature probe.

This compact device consumes less than one watt of power. It is designed for the most demanding environments, has a IP67 rating, and integrates total and static pressure sensors to calculate indicated airspeed accurately. ADC also supports aiding data from external GNSS receivers and ambient air data, which enhances its precision in a variety of flight conditions.

SimActive Inc., a developer of photogrammetry software, and the Alabama Department of Transportation (ALDOT) have partnered to use SimActive’s Correlator3D software to process UAV imagery for damage assessment.

In early 2023, a powerful tornado ripped through the southwest portion of the city of Selma, Alabama. ALDOT quickly collected more than 18,000 images of the area. The SimActive software allowed the team to process the data within 24 hours and deliver digital surface models and orthomosaics.

Correlator3D is an end-to-end photogrammetry solution designed to generate high-quality geospatial data from satellite and aerial imagery, including UAVs. The software performs aerial triangulation (AT) and produces dense digital surface models (DSM), digital terrain models (DTM), point clouds, orthomosaics, 3D models and vectorized 3D features.

Powered by graphics processing unit (GPU) technology and multi-core central processing units (CPU), Correlator3D offers enhanced processing speed to support the quick and efficient production of large datasets.

BAE Systems’ digital GPS anti-jam receiver (DIGAR) has entered the next phase of the Phase 4 Enhancements (P4E) capability program for the Eurofighter Typhoon.

DIGAR is designed to enhance the Typhoon’s ability to withstand GPS signal jamming, spoofing, and radio frequency (RF) interference, ensuring optimal mission execution in challenging RF environments.

The receiver uses advanced antenna electronics, high-performance signal processing and digital beamforming for improved GPS signal reception and jamming immunity, which aim to increase the level of GPS jamming protection. These capabilities are critical for combat aircraft as they maneuver through a contested battlespace.

This upgrade, coupled with BAE Systems’ GEMVII-6 airborne digital GPS receiver, reinforces the Eurofighter Typhoon’s role as a component in air security for the UK and its international allies.

In recent years, BAE Systems delivered the first Eurofighter Typhoon fighter aircraft to the Royal Air Force of Oman and the Italian Air Force officially received its final Eurofighter Typhoon, which completed its order for 21 aircraft.

In addition to Typhoon, DIGAR is also installed on the F-16, F-15, and other special-purpose aircraft in the United States such as air interdiction and force protection platforms, intelligence, surveillance or reconnaissance aircraft and UAVs.

“Seen & Heard” is a monthly feature of GPS World magazine, traveling the world to capture interesting and unusual news stories involving the GNSS/PNT industry.

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The scooter burglar

By using location data and a username from a Lime rental scooter, police have identified a man caught on video scootering around a Denver, Colorado, neighborhood loading up on stolen goods from surrounding homes, reported 9 News. Police obtained a search warrant for the scooter’s location data and account information. The suspect appears to have used his real name when renting the scooter to conduct the burglaries. 9 News is not naming the man identified as the scooter user as he hasn’t been arrested or charged. However, a background check on his name revealed he’s currently wanted on two theft cases that occurred in 2022, also in Denver.

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Doordashing goes wrong

A DoorDash driver followed his navigation system into a wooded area and then into a body of water while attempting to deliver an order to a residential neighborhood in Middleton, Massachusetts, reported the Daily Caller. After following the navigation system straight into water, the driver called police. The Middleton Police Department is now charging the DoorDash driver for “negligent operation of a motor vehicle” and has put in a request to suspend the driver’s license.

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Beidou birds

Researchers at the Jiangxi Nanfengmian National Nature Reserve in China are utilizing BeiDou during bird banding to monitor their migration period from September to October. Bird banding involves attaching customized tags to birds’ legs or wings to track their movements and patterns. Out of 614 birds, 36 are being equipped with specially designed positioning devices that will continuously transmit data for researchers to analyze migration routes, stopping places, and migration time, according to a nature reserve official.

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Spoofing targets airlines

More than 20 airline and corporate jets flying over Iran overnight on October 1, were targeted by spoofed GPS signals. The spoofed signals were sent from the ground, infiltrated the navigation systems of the jets, and steered them off course, reported The Times of India. According to the Ops Group, which runs a flight data intelligence crowdsourcing website, a majority of the GPS spoofing occurred in airway UM688 in Iran’s airspace. In response, the U.S. Federal Aviation Administration issued this warning to airlines: “Iraq/Azerbaijan — GPS jamming and spoofing poses safety risk.”

An expert safety review team assembled by the Federal Aviation Administration (FAA) addressed several near-misses at U.S. airports in recent months. The group has called for “urgent action” to be taken to maintain airline safety.

The National Airspace System Safety Review Team released a 52-page report on Nov. 15, which cited air traffic control staffing shortages, technology issues and funding needs as the suspected reasons for the incidents.

The review team, which includes former FAA executives, a former National Transportation Safety Board chairman and former aviation union leaders, was established in April 2023. The group was tasked with examining the air traffic control system and delivering recommendations on how to enhance safety, according to the  FAA.

Additionally, the report said that past investments in overhauling FAA technology have worsened the agency’s technology. Newer systems are being layered on top of older systems, and few of the old systems have been decommissioned or replaced, according to the report.

The old systems are becoming difficult to maintain because companies have gone out of business, spare parts are no longer available and the older workers who installed the technologies are retiring without passing knowledge onto younger employees. The equipment replacement backlog is $5.3 billion.

The panel also called for significant changes to the way air traffic controllers are trained. The report said using upgraded simulators and removing “unnecessary and outdated curriculum” could lead to faster certification and more employees.

Transportation Secretary Pete Buttigieg said the FAA is 3,000 controllers short of its goal, and according to the union representing controllers, the ranks grew by only 6% in the past year. If the current hiring plan is followed, only 200 empty seats would be filled, the report said.

The understaffing is causing controllers to work significant amounts of overtime, which the report said is causing “absenteeism, lower productivity and fatigue.” 

The report comes as the National Transportation Safety Board is conducting separate investigations into several of the near collisions, one involving a near collision in Boston and a collision involving two private jets in Houston. The near misses have since caught the attention of Congress. A Senate subcommittee held a hearing on Nov. 9, where Jennifer L. Homendy, chairwoman of the National Transportation Safety Board, stressed the importance of safety checks to maintain airline safety.

Point One Navigation has introduced the Atlas inertial navigation system (INS) designed for autonomous vehicles, mapping and other applications.

Traditional INS solutions have typically relied on extensive post-processing to reach the high precision levels needed for accurate mapping and observability applications. In contrast, Atlas can provide users with ground-truth level accuracy in real-time, which can streamline engineering workflows, significantly reduce project costs and improve operational efficiency.

Atlas is designed to be used in large fleets. It integrates a highly accurate, low-cost GNSS receiver and IMU with the Polaris RTK corrections network and Sensor Fusion algorithms. The company aims to make it easier for businesses to equip their entire autonomous fleets with high-accuracy INS.

The system features a user-friendly interface, on-device data storage and both ethernet and Wi-Fi connectivity. Field engineers can easily configure and operate Atlas using smartphones, tablets and in-car displays.

Atlas aims to drive innovation across a variety of sectors, including autonomous vehicles, robotics, mapping and photogrammetry. Its real-time capabilities and affordability can enhance the widespread deployment of ground truth-level location in fleet operations.

Inertial Labs has been awarded an SBIR Phase III contract by the Army Applications Laboratory of Army Futures Command. This award supports Inertial Labs development, design and fabrication of the Cannon Artillery Pointing and Sighting System (CAPSS) for potential use on the U.S. Army’s Paladin and the extended range cannon artillery (ERCA) vehicles.

The CAPSS aims to dramatically reduce weight on the target vehicle platforms by providing a digital replacement for the vehicle’s current panoramic telescope (PANTEL). The PANTEL is used as a sighting system for the gun when the fire control system is inoperable. The CAPSS prototype is being designed to physically replace the PANTEL.

CAPSS is a collection of cameras, inertial measurement units (IMUs), advanced electronics and an intuitive tablet-based user interface. Designed to digitally mirror the PANTEL, the CAPSS system allows soldiers to emulate all PANTEL functions via the tablet, bypassing the need to physically manage the telescope.

More than 400 lbs in equipment weight is eliminated by replacing the current equipment with CAPSS, which improves the vehicle’s operational efficiency. Additionally, the features integrated within CAPSS eliminate the need for warfighters to leave the vehicle cabin for typical aiming and sighting activities connected to the PANTEL setup, such as working with the auto-collimator. All of the functionalities are inherently embedded in the CAPSS, which simplifies operations.

The CAPSS camera technology is also used for semi-automated ranging capabilities. Warfighters can effortlessly zoom in on specific objects, offer estimated data based on the object’s attributes, such as size estimation, and the system will generate the estimated range to that particular object.

Looking ahead, Inertial Labs plans to continue research on optical/inertial-based GPS-denied navigation designed for land vehicles, integrating both camera systems and inertial sensor data.

This is an introduction to the November 2023 Innovation article, “Using GNSS Phase Reflectometry on Maui’s Haleakalā”

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We’ve all seen the news reports of the terrible devastation and loss of life in the town of Lahaina on the island of Maui by a wildfire this past August. Those terrible reports jarringly contrasted with happy memories of visits to Hawaii and its paradise islands. I recalled my visit some years ago to Maui in particular. My wife and I traveled all around Maui, but we particularly enjoyed the drive up to the top of Mount Haleakalā.

Rising to just over 3,000 meters, Haleakalā is a large, active (though currently dormant) shield volcano that forms about 75% of Maui. Just below its summit there is a visitor center with informative panels describing the geology of the volcano and the flora and fauna to be found on its flanks. On the drive up, for example, you can see endangered nēnē, the Hawaiian Goose, and the threatened silversword plants, which only bloom once in their lifetimes. And the sunrise and sunset views from the summit are quite beautiful.

A few hundred meters away from the visitor center is the Haleakalā High Altitude Observatory Site — a complex informally known as “Science City.” The site accommodates various optical telescopes and other instruments, including among others the 4-meter-aperture Daniel K. Inouye Solar Telescope (the largest solar telescope in the world), a satellite laser ranging station, and the Maui Space Surveillance Complex, which consists of a suite of telescopes operated by the Department of Defense for satellite tracking.

Also at the site is an innovative system observing the ocean surface far below using the phase of GNSS signals. Not only receiving normal line-of-sight signals from satellites, this system also receives signals that are reflected by the ocean surface, a technique called GNSS reflectometry or GNSS-R. GNSS-R can be thought of as a bi-static radar, where the transmitters (the GNSS satellites) and the receiver are separated by a large distance. The receiver can be on Earth’s surface, on an aircraft or on a low-Earth-orbiting satellite. The reflected signals contain information about the surface from which they were reflected. Depending on the receiver’s location and with suitable data processing, parameters such as ground surface elevation and its variation, water level and tide height, sea state (wave height, wind speed and wind direction), soil moisture content, and even snow depth can be deduced.

Over the years, we have had a number of articles on GNSS-R in this column using different receiver platforms (April, 1999; October, 2007; October, 2009; September 2010; September 2014; and October, 2019). In this quarter’s “Innovation” column, we have an article by some members of the team who built and operate the GNSS-R system on the top of Haleakalā. They explain how the system works and some of the preliminary observations and results they have obtained. More science in paradise!

Read Richard Langley’s introduction to this article: “Innovation Insights: Science in paradise”

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Originally developed for navigation and timing applications, signals from global navigation satellite systems (GNSS) are now commonly used for geophysical remote sensing applications, including observation of Earth’s surface and atmosphere using near sea-level ground stations as well as mountaintop, airborne and spaceborne platforms. GNSS reflectometry (abbreviated GNSS-R), which is the technique of using reflected signals to measure properties of Earth’s surface, has been a growing area of research and application for GNSS remote sensing. Notably, the Cyclone Global Navigation Satellite System (CYGNSS) satellite mission produces delay-Doppler maps (DDMs) that are used to monitor ocean surface wind speeds during hurricanes. Meanwhile, terrestrial and airborne GNSS-R has been used to monitor soil moisture, snow depth and vegetation growth. One area of increasing interest is precision reflectometry using signal carrier-phase measurements. The first attempt to perform precision (phase) altimetry over sea ice using GPS reflectometry measurements from the low-Earth orbiting TechDemoSat-1 was reported by researchers in 2017. Subsequently, researchers demonstrated the use of reflections collected by a Spire satellite to perform altimetry over Hudson Bay and the Java Sea and how reflections off ice in the polar regions can be used to measure ionospheric total electron content over the polar caps. While these demonstrations of GNSS-R for precision carrier-phase-based reflectometry are promising, more work needs to be done to characterize when carrier-based altimetry is feasible and what challenges it faces.

To study the challenges associated with processing reflected and low-elevation-angle radio occultation signals, the University of Colorado (CU) Boulder Satellite Navigation and Sensing (SeNSe) Laboratory has deployed a GNSS data collection site on top of Mount Haleakalā on the island of Maui, Hawaii. Recent collection campaigns aim to use this site as a testbed for GNSS-R algorithms that utilize multi-frequency and multi-polarization measurements. Previously, we carried out delay map processing for left-hand circular (LHC) and right-hand circular (RHC) polarizations for L1 and L2 GPS signals. Those results validate the open-loop processing methodology and provide an initial assessment of the data quality. We observed that the received reflected signals show deep and rapid fading in amplitude. In the work reported in this article, we extend our assessment to triple-frequency GPS (L1CA, L2C, L5Q) signals and document our methodology for extraction of the signal carrier phase. Our initial results indicate that coherent signal phase extraction is challenging, and may not be feasible for this particular experiment setup. We discuss ways in which the experiment may be improved for the purpose of obtaining coherent ocean surface reflections in the future.

EXPERIMENT BACKGROUND

The current form of the CU SeNSe Lab Mount Haleakalā GNSS experiment was deployed in June 2020. It consists of a side-facing dual-polarization horn antenna, which is shown in the left panel of FIGURE 1, along with a zenith-facing reference antenna. The horizontally- and vertically-polarized wideband signals from the horn antenna are fed into front-end hardware and are combined using 90-degree phase combiners to form LHC and RHC polarized signals, which are then recorded by a set of Ettus Universal Software Radio Peripherals (USRPs). Meanwhile, the signal from the reference antenna is sent to a Septentrio PolaRxS receiver. The right panel in Figure 1 illustrates the system setup. Note that the Septentrio onboard oven-controlled crystal oscillator is used to drive the USRPs. This allows us to use the Septentrio outputs to estimate the receiver clock variations and use them in the receiver clock component of our open-loop models, which we discuss below.

Each USRP can record up to four signals at two different mixdown frequencies, allowing for recording of both the RHC and LHC polarized signals on up to four different bands. The first USRP records the L1 and L2 bands with center frequencies at 1575.42 and 1227.6 MHz, respectively, at a bandwidth of 5 MHz. The second USRP records the L5 and E6/B3 bands at center frequencies of 1176.45 and 1271.25 MHz and at a 20 MHz bandwidth. TABLE 1 lists the IDs for each receive channel along with its corresponding band, polarization and sampling rate. Note that the recorded signals covering the E6 band also capture BeiDou B3 signals, but we restrict our analysis to GPS L1, L2 and L5 signals in this article. The samples from these USRPs are written to disk along with the Septentrio Binary Format (SBF) output of the PolaRxS receiver.

Starting in June 2021, periodic collections were taken for around one hour at a time, which is about the amount of time it takes for a GPS satellite to pass from an elevation angle of 0 degrees to one of more than 20 degrees. The collection times were adjusted to target the passes of satellites whose specular reflection point passed within the azimuthal range of the horn antenna, which faces roughly to the south and has a beam width of around 60 degrees. FIGURE 2 summarizes the available datasets from the first month of collections. The right-most panels of FIGURE 3 show examples of the specular track for GPS PRN 6 as it sets over the horizon on June 13, 2022, at around 12:00-13:00 UT. This is the pass on which we focus in this work, since PRN 6 transmits the L1CA, L2C and L5 signals and consistently had a specular point in our region of interest.

METHODOLOGY

Our processing method for open-loop tracking of the reflected GNSS signals is based on our previous work in which we produced DDMs and delay maps of the signal-to-noise ratio (SNR) measurements for multiple signal frequencies and received polarizations.

Pseudorange Model. We start by generating a model of the pseudorange for both the direct and reflected signal. The model only needs to be accurate down to the chip level, since we correlate across several chips of delay for the received signals. Setting a somewhat arbitrary accuracy requirement of 0.5 chips (equivalent to a delay of around 150 meters for L1CA/L2C or 15 meters for L5 signals), allows us to ignore path delays from the ionosphere and troposphere, which should only account for up to several meters of delay. The model has three terms that we estimate relative to GPS System Time (GPST): the receiver clock error, the satellite transmitter clock error and the geometric range. We use a surveyed position of the horn antenna along with International GNSS Service precise orbit and clock products for the transmitter clock error and positions. These allow us to compute the transmitter clock error and path delay for the direct signal. The reflected signal path delay can be found by computing the specular reflection point on the WGS84 ellipsoid and adding the distances from the transmitter to the specular point and the specular point to the receiver. The remaining term to estimate is the receiver clock error. Recall that our USRPs are driven by the Septentrio internal oscillator. Therefore, the clock error in Septentrio measurements is associated with variations in the reference oscillator for the USRPs. We utilize a geodetic detrending technique to estimate these clock variations and apply them to our pseudorange model. To construct the full receiver clock error, we estimate the time-alignment of the samples near the beginning of the collections to GPST by tracking one minute of a strong, mid-elevation-angle satellite and decoding its timing information. This provides us with an estimate of GPST at the start of the file, which we can use to construct a full estimate of the GPST at any sample in the file. Also, given our pseudorange model, we can find the received code phase and the Doppler frequency.

Signal Correlation. Using the established code phase and Doppler models, we generate correlations for both reflected and direct signals. We correlate a reference signal over each 1-millisecond interval, and for sanity-checking purposes, we compute correlations over ± 3 chips at 0.5 chip spacing. This results in in-phase and quadrature (I/Q) correlation outputs every 1 millisecond. The left panels in Figure 3 show examples of the processed reflected signals for RHC and LHC polarization L1CA, L2C and L5Q signals from PRN 6 on June 13, 2021, at 12:00-13:00 UT. Note that as the satellite sets, at around 4 degrees elevation angle, the reflected signals merge with the stronger direct signal on the L1 and L2 signals. This happens later on L5 due to its higher bandwidth. We use the 0.0 chip bin to obtain I/Q outputs for carrier-phase processing for L1 and L2. For L5, we use the 0.0, -0.5, or -1.0 chip bin to account for model mismatch toward the end of the file.

Signal Fading and the WW3 Ocean Model. An eventual goal of the Haleakalā reflectometry experiment is to compare the characteristics of processed reflected signals with the ocean surface parameters near the specular point and glistening zone. To this end, we have incorporated data from the Hawaii regional WaveWatcher 3 (WW3) model. The model outputs information about wave height, direction and period due to both wind and swell, and has a resolution of around 5 kilometers. The data from this model is available in NetCDF format from several web services. The right panels of Figure 3 show contours of the wind- and swell-significant wave height in the South Haleakalā region. Meanwhile, note that the reflected signals (left panels) show high variability in the received power throughout the duration of the collection. While we hoped to be able to immediately observe a correlation between these wave parameters and the power fluctuations, it is clear that we need additional processing to tease out such a signal, and the changing satellite geometry will likely make this difficult to observe and validate. Even still, our results at the end of this article will show that there is likely some correlation between fading and wind parameters, though to what extent is unknown. Finally, note that the LHC polarizations (RX6, RX8, RX2) show much stronger reflected signals than the RHC polarizations. Since we are interested in processing the phase for the reflected signals, we report exclusively on the use of the LHC polarization signals in the rest of this article.

Carrier-Phase Processing. Once the correlations are performed, we take the I/Q correlations for both direct and reflected signals and process them to retrieve the cleaned reflected signal phase. The first series of steps in this process involve processing the direct signal to determine navigation / overlay symbol alignment and to estimate any residual phase fluctuations, which are mostly due to unmodeled receiver clock fluctuations. FIGURE 4 illustrates this process for the L1CA signal. The raw I/Q correlations are shown in the top panel. To these we apply a Costas phase-lock loop (PLL) to track the residual phase fluctuations without being sensitive to navigation / overlay symbol transitions. Next, we remove these residual phase fluctuations to obtain the detrended I/Q values.

As shown in the second panel, these quadrature components of the detrended I/Q values are centered at zero while the in-phase component now shows the data bits / overlay symbols. We use the detrended I/Q values to estimate the navigation bit sequence on the L1CA and L2C signals. Likewise, we estimate the alignment of the Neumann-Hoffmann overlay sequence for the L5 signal. Finally, we wipe off the estimated data bits or overlay sequence to verify the procedure. The results of wiping off the estimated navigation bits for the L1CA signal are shown in the third panel of Figure 4.

Having obtained the residual phase fluctuations and navigation / overlay symbols for the direct signal, we next apply these to clean up the reflected signal. Specifically, we remove residual phase fluctuations from the raw reflected signal I/Q values and then wipe off the corresponding navigation bits or overlay code. FIGURE 5 shows an example of the reflected I/Q data before and after this procedure. The navigation bits are clearly removed, but the reflected signal still shows fairly significant fluctuations in the cleaned I/Q values. It is from these values that we hope to extract the residual reflected signal phase.

Under coherent conditions, the phase of the clean reflected I/Q data should contain only the unmodeled effects, including any signature of ocean surface height variation. However, the effect of multipath due to the rough ocean surface causes fluctuations in the received signal amplitude and phase, and can additionally cause cycle slips when we unwrap the phase. To filter out these cycle slips, we apply our simultaneous cycle slip and noise filtering (SCANF) method, which is essentially just a Kalman filter PLL with an additional step that tries to estimate and remove cycle slips. The figures in the next section show the results of applying this entire procedure to the reflected signals. The black and blue lines show the phase before and after applying SCANF. The reflected signal I/Q SNR is also included for reference. Note how the jumps in the black line coincide with SNR fades, and the blue line effectively recreates the phase trend of the black line without these jumps. This is good qualitative evidence that the SCANF algorithm was effective.

RESULTS

FIGURES 6, 7, 8, 9, 10, and 11 show the reflected signal SNR and phase for GPS PRN 6 on 6 different days. Note that these days correspond to the marked days in Figure 2, from which we observe that the wind-significant wave height is relatively high on days 1, 5, and 6, moderate on days 2 and 3, and relatively low on day 4. We noticed that the SNR fluctuations on days 1, 5, and 6 are comparatively more frequent than on other days, which we believe may be a signature of the ocean surface conditions. A more detailed analysis of this result is a topic for our future work.

Overall, we observe that the phase trend is not consistent across the three signals (L1CA, L2C, L5) for any of the days. With all the multipath signatures in the cleaned reflected signal, it was uncertain whether the extracted phase will be useful for applications such as ocean surface altimetry, and these qualitative results suggest that they probably will not be. However, season and hours of the day that were processed for our work discussed in this article are very limited. It is possible that processing more data will shed further insight onto whether the reflected signal phase is usable in this experiment.

ACKNOWLEDGMENTS

The Haleakalā data collection system has been established with support from the University of Hawaii Institute of Astronomy, and the Air Force Research Laboratory. The authors appreciate the assistance from Michael Maberry, Rob Ratkowski, Daniel O’Gara, Craig Foreman, Frank van Graas and Neeraj Pujara. This research is funded by a subaward from the National Oceanic and Atmospheric Administration through the University Corporation for Atmospheric Research to CU Boulder and with partial funding support from the NASA Commercial Smallsat Data Acquisition program.

This article is based on the paper “Initial Carrier Phase Processing for the Haleakala Mountaintop GNSS-R Experiment” presented at ION ITM 2023, the 2023 International Technical Meeting of the Institute of Navigation, Long Beach, California, Jan. 23–26, 2023.

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BRIAN BREITSCH is a postdoctoral fellow at the University of Colorado (CU) Boulder, where he received his Ph.D. in aerospace engineering sciences.
JADE MORTON is a professor in the Ann and H.J. Smead Department of Aerospace Engineering Sciences and the director of the Colorado Center for Astrodynamics Research at CU Boulder.

Trimble has partnered with HALO Trust, a landmine-clearing non-profit organization, to help expand its demining operations across Ukraine.

The grant from the Trimble Foundation Fund will focus on strengthening the HALO Trust’s ability to locate and remove landmines, unexploded ordnance and other explosive hazards from civilian areas to create safer communities. In addition, it will allow HALO to support the Ukrainian national authorities in planning and coordinating landmine clearance activities by streamlining the mapping and data flow from the operational teams in the field to the national database.

The Russian invasion of Ukraine has left areas of the country contaminated with landmines, unexploded ordnance and improvised explosive devices. These hazards block access to farmland, impede reconstruction efforts, prevent displaced persons from returning to their homes and continue to hinder the safety of Ukrainian civilians. The Ukrainian government estimates that 174,000km2 of the country’s land may be contaminated.

More than a thousand HALO staff members are active daily, both to clear explosives in critical priority areas and to recruit and train hundreds of new staff members to help keep communities safe from dangerous weapons left behind.

Surveying and mapping technology has played a significant role in the success of HALO’s operations around the world, including in Ukraine. Over the last six years, Trimble R1 and Trimble R2 GNSS receivers along with Esri ArcGIS Survey123 software have been used by HALO to identify and clear landmines.

Trimble’s Geospatial and Positioning Services businesses provided HALO with a new deployment of 255 high-precision Trimble DA2 GNSS receivers with Trimble Catalyst corrections service, allowing HALO to modernize and transform its landmine clearance operations by providing improved accuracy for more detailed maps, streamlined data flows and increased operational efficiency and safety.