Category: Mapping

  • Research project reveals Old Faithful secrets

     

    Photo: Old Faithful/National Park Service
    Photo: Old Faithful/National Park Service

    By Paul Gabrielsen, University of Utah

    Old Faithful is Yellowstone National Park’s most famous landmark. Millions of visitors come to the park every year to see the geyser erupt every 44 to 125 minutes. But despite Old Faithful’s fame, relatively little was known about the geologic anatomy of the structure and the fluid pathways that fuel the geyser below the surface. Until now.

    University of Utah scientists have mapped the near-surface geology around Old Faithful, revealing the reservoir of heated water that feeds the geyser’s surface vent and how the ground shaking behaves in between eruptions. The map was made possible by a dense network of portable seismographs and by new seismic analysis techniques. The results are published in Geophysical Research Letters. Doctoral student Sin-Mei Wu is the first author.

    For Robert Smith, a long-time Yellowstone researcher and distinguished research professor of geology and geophysics, the study is the culmination of more than a decade of planning and comes as he celebrates his 60th year working in America’s first national park.

    “Here’s the iconic geyser of Yellowstone,” Smith says. “It’s known around the world, but the complete geologic plumbing of Yellowstone’s Upper Geyser Basin has not been mapped nor have we studied how the timing of eruptions is related to precursor ground tremors before eruptions.”

    A portable seismometer used to map the geology beneath Old Faithful. (Photo: Paul Gabrielsen)
    A portable seismometer used to map the geology beneath Old Faithful. (Photo: Paul Gabrielsen)

    Small seismometers

    Old Faithful is an iconic example of a hydrothermal feature, and particularly of the features in Yellowstone National Park, which is underlain by two active magma reservoirs at depths of 5 to 40 km depth that provide heat to the overlying near-surface groundwater. In some places within Yellowstone, the hot water manifests itself in pools and springs. In others, it takes the form of explosive geysers.

    Dozens of structures surround Old Faithful, including hotels, a gift shop and a visitor’s center. Some of these buildings, the Park Service has found, are built over thermal features that result in excessive heat beneath the built environment. As part of their plan to manage the Old Faithful area, the Park Service asked University of Utah scientists to conduct a geologic survey of the area around the geyser.

    For years, study co-authors Jamie Farrell and Fan-Chi Lin, along with Smith, have worked to characterize the magma reservoirs deep beneath Yellowstone. Although geologists can use seismic data from large earthquakes to see features deep in the earth, the shallow subsurface geology of the park has remained a mystery, because mapping it out would require capturing everyday miniature ground movement and seismic energy on a much smaller scale. “We try to use continuous ground shaking produced by humans, cars, wind, water and Yellowstone’s hydrothermal boilings and convert it into our signal,” Lin says. “We can extract a useful signal from the ambient background ground vibration.”

    To date, the University of Utah has placed 30 permanent seismometers around the park to record ground shaking and monitor for earthquakes and volcanic events. The cost of these seismometers, however, can easily exceed $10,000. Small seismometers, developed by FairfieldNodal for the oil and gas industry, reduce the cost to less than $2,000 per unit. They’re small white canisters about six inches high and are totally autonomous and self-contained. “You just take it out and stick it in the ground,” Smith says.

    In 2015, with the new instruments, the Utah team deployed 133 seismometers in the Old Faithful and Geyser Hill areas for a two-week campaign.

    The sensors picked up bursts of intense seismic tremors around Old Faithful, about 60 minutes long, separated by about 30 minutes of quiet. When Farrell presents these patterns, he often asks audiences at what point they think the eruption of Old Faithful takes place. Surprisingly, it’s not at the peak of shaking. It’s at the end, just before everything goes quiet again.

    After an eruption, the geyser’s reservoir fills again with hot water, Farrell explains. “As that cavity fills up, you have a lot of hot pressurized bubbles,” he says. “When they come up, they cool off really rapidly and they collapse and implode.” The energy released by those implosions causes the tremors leading up to an eruption.

    One scientist’s noise is another scientist’s signal

    Typically, researchers create a seismic signal using an active source, such as swinging a hammer onto a metal plate on the ground or setting off an explosion. Lin and Wu developed the data analysis method that would help find useful signals among the seismic noise without disturbing the sensitive environment in the Upper Geyser Basin. Wu says she was able to use the hydrothermal features themselves as a seismic source, to study how seismic energy propagates by correlating signals recorded at the sensor close to a persistent source to other sensors. “It’s amazing that you can use the hydrothermal source to image the structure here,” she says.

    The model of Old Faithful’s hydrogeological system suggested by the study’s results. (Image: Sin-Mei Wu)
    The model of Old Faithful’s hydrogeological system suggested by the study’s results. (Image: Sin-Mei Wu)

    When analyzing data from the seismic sensors, the researchers noticed that tremor signals from Old Faithful were not reaching the western boardwalk. Seismic waves extracted from another hydrothermal feature in the north slowed down and scattered significantly in nearly the same area suggesting somewhere west of Old Faithful was an underground feature that affects the seismic waves in an anomalous way. With a dense network of seismometers, the team could determine the shape, size, and location of the feature, which they believe is Old Faithful’s hydrothermal reservoir.

    Wu estimates that the reservoir, a network of cracks and fractures through which water flows, has a diameter of around 200 meters, a little larger than the University of Utah’s Rice-Eccles Stadium, and can hold approximately 300,000 cubic meters of water, or more than 79 million gallons. By comparison, each eruption of Old Faithful releases around 30 m3 of water, or nearly 8,000 gallons. “Although it’s a rough estimation, we were surprised that it was so large,” Wu says.

    Further work

    The team is far from done answering questions about Yellowstone. They returned for another seismic survey in November 2016 and are planning their 2017 deployment, to begin after the park roads close for the winter. Wu is looking at how subsurface structure and hence the propagation of seismic waves can change with time. Farrell is using the team’s seismic data to produce even higher resolution subsurface images and predict how earthquake waves might reverberate through the region.

    Smith is looking forward to conducting similar analysis in Norris Geyser Basin, the hottest geothermal area of the park. Lin says that the University of Utah’s research program in Yellowstone owes much to Smith’s decades-long relationship with the park, enabling new discoveries. “You need new techniques,” Lin says, “but also those long-term relationships.”

    The full study can be found here. The research was funded by the National Science Foundation and by King Abdullah University of Science and Technology, the Brinson Foundation and the Carrico Fund. Fan-Chi Lin is the Principal Investigator.


    Paul Gabrielsen is a science writer at University of Utah Communications.

  • GPS.gov helps with wrong addresses on personal devices

    Members of the public often turn to GPS World and Geospatial Solutions for help when their personal device gives them incorrect mapping information.

    GPS.gov has set up a page that points users to the correct place to report problems, by walking them through a series of steps.

    As our readers know, the problem isn’t with the satellites, but in the mapping software used by the devices and apps. Links are provided to mapping companies Google, Waze, TomTom, HERE, OpenStreetMap, Garmin and Apple.

  • Harris offers Geiger-mode lidar for accurate elevation data

    After two decades of providing the U.S. government with Geiger-mode lidar data, Harris Corporation offers high-resolution lidar data and its derived products to commercial organizations.

    The data can be used for land-use planning and management, transmission-line monitoring, pipeline design and maintenance, transportation engineering and planning, urban modeling, asset management and forestry analytics.

    Geiger-mode lidar offers the most accurate elevation data available, according to Harris Corporation, the only provider of Geiger-mode lidar data.

    According to the company, the sensor allows for collections on a large scale, while also collecting data up to 10 times faster and at 10 times the resolution of existing linear lidar sensors.

    Geiger-mode lidar provides multi-angle illumination that penetrates foliage, removes shadows and and eliminates voids.

  • Apply now for methane leak detection technology competition

    Just over three weeks remain to apply to the Mobile Monitoring Challenge (MMC), led by Stanford and the Environmental Defense Fund (EDF) with technical advice from ExxonMobil.

    There’s a big push to develop mobile technologies to monitor and quantify methane leaks at oil and natural gas sites. Mobile monitoring offers the promise of surveying highly dispersed industrial facilities — including smaller and older ones — quickly and effectively.

    Stanford and EDF, aided by industry and other expert advisors like those from ExxonMobil, will rigorously field test and compare the most promising new mobile technologies and approaches submitted via the MMC – with extra interest in commercially scalable options. Results will be published in peer-reviewed journals.

    Details on the competition, what is required, and the benefits of applying can all be found here.

    All applications are due by Oct. 31.

  • Hexagon presents solutions for geospatial, construction industries at Intergeo

    Hexagon AB showcased its geospatial and construction portfolio at Intergeo 2017 in Berlin, Germany.

    Hexagon’s sensor portfolio combined with a range of software creates solutions that support the geospatial and construction industries.

    According to the company, visitors were able to explore a number of solutions, including mobile mapping; asset collection and management for geographic information systems (GIS); 3D laser scanning; photogrammetry; remote sensing; airborne sensors and unmanned aerial vehicles (UAVs); global positioning and monitoring like GNSS; construction project controls and progress documentation; utility detection; measurement software and cloud-based dynamic mapping. Hexagon will be at booth A1.024 in Hall 1.1.

    “Hexagon is focused on creating smart digital realities,” said Hexagon President and CEO Ola Rollén. “At Intergeo, we will demonstrate the productivity and savings that can be realized from digitalizing customer workflows, automating processes and ensuring all stakeholders have access to dynamic, critical information.”

    During the conference portion of Intergeo, Hexagon executives addressed the growing need for digitalization in geospatial and construction industries:

    • Transformation through digitalization. Hexagon Geosystems President Juergen Dold provides the Intergeo opening keynote exploring the need for businesses to transform from efficient digitisation to connected digitalisation for continued progress.
    • The power of combining cost, schedules and models in the cloud. Director of Global Business Development for HxGN SMART Build at Hexagon PPM, Cathi Hayes, explains how SMART Build integrates model, schedule, cost and digital layout capabilities into a single solution that addresses the most critical phases of construction planning and execution.
    • Hexagon integrated solution for utility detection and mapping. Leica Geosystems Construction Tools President Katherine Broder and IDS GeoRadar President Alberto Bicci present how to achieve high productivity in mapping utilities with Hexagon’s underground detection portfolio, including ground penetrating radar (GPR) solutions.
    • Escaping the flatlands. Hexagon Geospatial President Mladen Stojic envisions new and easier approaches that ingest the influx of data, use automated approaches to extract the signal from the noise and provide intuitive ways of communicating insights to decision makers and field teams so they can shape smarter change.
    • Connecting perceptions with reality in the world of BIM, GIS and survey. Leica Geosystems Laser Scanning Vice-President of Business Development Faheem Khan looks at the benefits of sensor fusion, the growth of digital reality solutions and how both are affecting project lifecycles in the real, digital world.
    • Streamlining UAV workflows for surveying, construction and inspection. Leica Geosystems Product Manager for UAV Solutions Valentin Fuchs and Leica Geosystems Director of Marketing and Communications for UAV Solutions Benjamin Federmann deliver a series of presentations and hands-on demonstrations on how Hexagon integrates UAVs as part of the technology tool kit to digitalise workflows.
  • GNSS Smart Target Base Station simplifies map production from UAVs

    Trimble has released the Trimble GNSS Smart Target Base Station for high-accuracy mapping from unmanned aerial vehicles (UAVs).

    The announcement was made at Intergeo 2017, the world’s largest conference on geodesy, geoinformatics and land management.

    Comprised of a survey grade, multi-frequency, multi-constellation GNSS reference station complete with a foam Ground Control Target with integrated carrying case, the Smart Target Base Station logs the raw GNSS observables required to perform centimeter level post-processed Differential GNSS positioning of UAVs, and acts as a photo-identifiable Ground Control Point (GCP) for quality control.

    Cost effective, simple to operate, and supported by both the Applanix POSPac UAV GNSS-inertial post-processing software for direct georeferencing on UAVs and Trimble UASMaster photogrammetric software, the Smart Target Base Station makes aerial mapping from UAVs easier, according to Trimble.

    Users can place the foam target with its receiver in the project area and stake it down. With the included smartphone app or web user interface, users can remotely begin logging the raw GNSS observables data collected by the target that is required for post processing.

    At the end of the mission, the user retrieves the target and downloads the raw GNSS data along with the data collected from the Trimble APX UAV GNSS-inertial system installed in the UAV.

    Global coordinates of the reference station are computed automatically using the Trimble Centerpoint RTX post-processing service in POSPac UAV or, if local coordinates are desired, the foam target can be centered over an existing reference point.

    “Efficient mapping from UAVs using cameras, lidar and other sensors requires the right solutions that need to be simple and easy to use,” said Joe Hutton, director of inertial technology and airborne products at Applanix, a Trimble Company. “The Smart Target Base Station is a result of listening to our customers’ needs for a GNSS reference station to support direct georeferencing on UAVs that is cost-effective, easy to deploy in all terrains, and does not require special knowledge to operate. Aerial surveyors can quickly realize greater value and significant cost savings with this system, while obtaining high accuracy.”

    The Trimble GNSS Smart Target Base Station operates autonomously for up to four hours with its embedded lithium ion battery. Extended operation can be achieved with a user-supplied external USB battery.

  • TerraGo showcases mobile geospatial solutions at Intergeo 2017

    TerraGo is exhibiting at Intergeo 2017, which is taking place Sept 26-28 in Berlin, Germany.

    “Intergeo brings together the global leaders of the industry and creates an exceptional forum for interpersonal collaboration and the opportunity to show the industry’s only zero-code platform to visitors from nearly 100 countries,” said Stuart Miller, international sales manager at TerraGo. “The event gives us a chance to dialogue and understand our visitors’ goals before we demonstrate our technology. Then by understanding their specific objectives, we can show them how to customize geospatial apps for their unique requirements.”

    TerraGo’s GeoPDF products enable free, lightweight GIS applications and have evolved into a de facto standard around the globe, helping organizations get more value — for more users — from their current investments in GIS and imagery platforms, the company said.

    Also, TerraGo Magic enables end users without development skills to build custom apps that enable high-accuracy, survey-grade GNSS with advanced GIS and mapping features on Android and iOS devices.

    TerraGo’s exhibition will be located at the UK Pavilion, Hall 1.1, Booth D1.016. Click this link to schedule a time for a live demonstration.

  • Harxon showcases GNSS products at Intergeo 2017

    Harxon is showcasing a series of GNSS antennas and wireless data-link modems at 2017 Intergeo, being held Sept. 26-28 in Berlin, Germany.

    The products aim to provide the user better industrial solutions in the fields of surveying and mapping, precision agriculture and unmanned aerial vehicles (UAVs).

    The Harxon D-Helix Antenna.

    D-Helix Antenna: The multi constellation antenna is capable of superior tracking signals from 4 satellite constellations, including GPS L1/L2 L-Band, GLONASS L1/L2, BDS B1/B2/B3 and Galileo. The innovative quadrifilar helix antenna design of low wind-resistance is ideal for aerial photographs, telemetry technology, disaster monitoring and security monitoring industries. Its 3.5dBi peak gain ensures exceptional low elevation tracking performance. The low noise figure enhanced transmission interference reduction and improve the signal quality.

    The Harxon GPS 1000 Survey Antenna.

    Survey Antenna GPS 1000: The all constellation GNSS antenna has passed the NGS certification, which receives GPS L1/L2/L5 L-Band, BDS B1/B2/B3, GLONASS L1/L2, Galileo E1/E2/E5a/E5b signals. It can be used in land survey, marine survey, channel survey and agriculture applications, with a consistent performance across the full bandwidth. GPS 1000 has high gain and wide beam width to ensure the signal receiving performance of satellite at the low elevation angle, and the phase center remains constant as the azimuth and elevation angle of the satellites change. The influence of measurement error can be minimized via the multi-feed design and embedded multi-path rejection board.

    Rover Radio HX-DU1603D: The high-speed, Bluetooth-enabled ruggedized UHF rover radio is designed for GNSS/RTK surveying and positioning. It ensures the data communication between 410MHz and 470 MHz in either 12.5KHz or 25 KHz channels. HX-DU1603D is equipped with a Bluetooth transceiver for wireless communications of external devices, features a 6800mAh rechargeable internal battery and configurable transmit power between 0.5W and 2W, also the IP67 waterproof capability allows outdoor long operational hours.

    Harxon Frequency Hopping Module HX-DU1018D/HX-DU2017D.

    Frequency Hopping Module HX-DU1018D/HX-DU2017D: The built-in frequency hopping transceiver modules are small size, light weight, low power consumption and strong resistance to disturbance. They provide a reliable, high speed and low latency data transmission, which are suitable for UAV flight control. These modules support a band range among 400MHz, 840MHz and 900MHz and long distance of communication. Besides, HX-DU1018D/HX-DU2017D can realize a switchover between air baud rate and serial port baud rate.

    Harxon Smart Antenna.

    Smart Antenna: It is a multi-functional GNSS product which is integrated by multi-frequency OEM antenna, OEM receiver and frequency hopping transceiver. Smart Antenna utilizes the dual anti-multipath antenna to receive stable GNSS signals under the bad-signal environment and precisely output the direct information with a centimeter-level positioning accuracy. The IP67 waterproof design allows the smart antenna for a long time outdoor operation.

    The Harxon H-RTK.

    H-RTK: H-RTK is for UAV positioning and navigation, which reaches the positioning accuracy to a centimeter level. It is integrated with positioning, height setting and heading functions to provide accurate, reliable solutions. H-RTK ensures the positioning accuracy to a centimeter level for a more stable flightpath. Also, it provides the reliable height information and solve the height-error problem to prevent air turbulence. H-RTK outputs precise navigation information with powerful magnetic disturbance resistance, it enables the flight reliability under a magnetic disturbance environment, and avoid security risks. The built-in anti-interference frequency hopping transceiver helps data transfer back to the base station, and supports the frequencies of 400 MHz, 840 MHz and 900 MHz.

    For more information,visit Harxon’s booth at Intergeo in Hall 4.1 booth C4.013.

  • Phase One Industrial introduces 190MP aerial system

    Phase One Industrial introduces 190MP aerial system

    Phase One Industrial has launched the 190MP Aerial System, built on dual CMOS sensors and the dual-lens iXU-RS1900 camera, which is capable of capturing images at 190 megapixels, according to the company.

    An alternative to traditionally expensive large-format cameras, the system was designed with input from engineers and experts in photogrammetry to address challenging aerial applications such as remote sensing, monitoring, inspection and disaster management.

    The system is equipped with an Applanix’ POS AV system, enabling direct geo-referencing of aerial images. It is also compatible with other GNSS/IMU systems. By integrating precision GNSS with inertial technology, POS AV enables precise determination of position and attitude, as well as the completion of geospatial projects in a more efficient and cost-effective manner.

    The system’s accurate large image coverage, light weight and low power consumption make it compatible with most light aviation vehicles, including those that previously could not manage a large format system.


    The iXU-RS1900 camera and 190MP aerial camera system will be presented at Intergeo 2017, to be held in Berlin, Germany, from Sept. 26-28. Phase One Industrial’s booth is in Hall 4.1, stand B4.002. Applanix is exhibiting in Hall 4.1, stand C4.050.


    At the system’s heart is the IXU-RS1900 camera. It features two CMOS sensors and two 90mm lenses for capturing RGB information. Key imaging attributes include:

    • a small pixel size (4.6 µ)
    • large image area (16,470 x 11,540)
    • high image-capture rate of 0.6 second and exposure time of up to 1/2000 second.

    An optional four-band configuration, adding a 50-mm lens for capturing near infrared (NIR) information, provides four-band (RGB, NIR) or color-infrared (CIR) imagery.

    Integrated iX Capture software automatically generates distortion-free images and automatically performs an accurate matching of the NIR and RGB images.

    The iXU-RS1900 can also be a  standalone camera for photogrammetric work, as a component for lidar systems, or as part of a multiple camera array, such as a nadir camera for oblique systems.

    “Introducing the Phase One 190MP aerial system demonstrates our continuing commitment to the aerial photography market,” said Dov Kalinski, general manager of Phase One Industrial. “The cooperation with leading partners in mount design, GNSS, and Flight Managements Systems enables Phase One to offer an innovative system at affordable pricing, and enables our customers to execute projects faster and at lower cost.”

    190MP Aerial System Features

    The entire system comprises many elements including:

    iX Controller MK III: This is the central hub of the system. It controls the camera, the gyro-stabilizing mount and the GNSS/IMU system, and runs the capture application and the flight management system. The iX Controller supports dual monitors, so both the pilot and the operator are able to monitor and observe different views of the setup in parallel.

    iX Capture: iX Capture is an aerial capture, control and image processing software with an intuitive interface that displays key information such as exposure settings, histogram, GPS data and frame count. It provides the operator with real-time feedback and ensures confidence that each image has been captured correctly.

    Gyro Stabilized Camera Mount – Somag DSM400: Designed specifically for Phase One 190MP Aerial System, this mount has a low weight of 14 kg and high payload of 35 kg. It provides optimal stabilization of the system pod and allows highly efficient and precise image capturing under most flight conditions.

    GNSS/IMU system: The Phase One 190MP Aerial System is equipped with an Applanix’ POS AV system, enabling direct geo-referencing of aerial images. It is also compatible with other GNSS/IMU systems. By integrating precision GNSS with inertial technology, POS AV enables precise determination of position and attitude, as well as the completion of geospatial projects in a more efficient and cost effective manner.

    Flight Management System: Controlled and operated with ease, TopoFlight flight management system, integrated into the Phase One 190MP Aerial Camera System, enables the planning, positioning and sensors’ management – reducing aerial survey operational costs and increasing productivity. The 190MP Aerial System is also compatible with other flight management systems.

    Availability and Pricing: The iXU-RS1900 camera and 190MP Aerial Systems are available now from Phase One Industrial partners worldwide. The iXU-RS1900 camera pricing starts at US$150,000; the 190MP Phase One Aerial System pricing starts at U.S. $280,000; and the190MP Four-Band Aerial System pricing starts at US$365,000.

  • EagleView capturing Hurricane Irma imagery to speed response

    EagleView capturing Hurricane Irma imagery to speed response

    EagleView Technologies is actively flying to acquire post-storm imagery in Florida following Hurricane Irma. With more than 20 planes staged or in the air, EagleView is continuously capturing high-resolution aerial imagery to enable rapid assessment and response to Hurricane Irma relief efforts.

    EagleView is a provider of aerial imagery and property analytics for the government, insurance and commercial sectors.

    Using both fixed-wing aircraft and drones, EagleView imagery supports post-hurricane insurance claims adjusting, property assessment, public safety and land surveying professionals.

    “With these hurricanes affecting so many Americans, we’re putting our planes in the air as soon as possible to begin the image capture process,” said EagleView President Rishi Daga. “From our unique high-resolution post-event imagery to our industry-leading machine learning capabilities, EagleView’s technology can massively accelerate recovery efforts and because of this, we find it crucial to take flight immediately once permitted into the airspace.”

    EagleView’s historical image library, dating back to 2002 in Florida, offers insurance carriers, first responders, non-profit organizations and local government agencies the ability to analyze the impact of the storm on homes, commercial buildings and infrastructure by comparing previously captured imagery with the latest post-event images.

    Image capture and processing post-Hurricane Irma will take place continuously over several weeks, with EagleView making constant updates to its nearly four-petabyte imagery and data library.

    “We have access to an impressive amount of resources in Florida and the surrounding areas, allowing us to provide the largest post-storm image capture capabilities to our clients,” said Jay Martin, senior vice president of operations for EagleView. “Our team is working around the clock to deliver imagery to those who need it most following these devastating weather events.”

    EagleView is capturing varying types of aerial imagery throughout Florida. This includes its ultra-high-resolution (UHR) imagery, also known as Reveal imagery, which is the highest resolution aerial imagery available on the market today.

  • Hurricane Irma prep gets boost from Esri resource catalog

    Hurricane Irma prep gets boost from Esri resource catalog

    Esri has published a Hurricane Irma Resource Catalog in advance of the Category 4 hurricane cutting through the Caribbean islands on its path toward Florida.

    The catalog features read-to-use applications compiled by the Esri Disaster Response Program (EDRP). EDRP is an around-the-clock service that helps with monitoring events online, discovering useful content, augmenting software and obtaining assistance from Esri experts.

    To see the track of the hurricane, Esri provides its hurricane map.

    Resources include:

    • Hurricane Public Information Map (PIM)
    • Hurricane Impact Summary
    • Hurricane Force Wind Impact Summary
    • Storm Surge and Flooding
    • Storm Surge Inundation
    • Hurricane Evacuation Zones
    • Waze Alerts – Hurricane Irma
    • Florida 511 – Real-Time Traffic Information
    • Hurricane Irma Photo Story Map
    • Airport and Port Status
    • NOAA Real-Time Coastal Observations
    • Florida Division of Emergency Management Open Data
    Waze alerts light up Florida highways as people evacuate. (Image: Esri)
  • DigitalGlobe releases satellite imagery of Houston

    DigitalGlobe releases satellite imagery of Houston

    DigitalGlobe released satellite imagery of Houston after Hurricane Harvey hit.

    Hurricane Harvey slammed into the Gulf Coast of Texas — just southwest of Houston — on Aug. 25. According to DigitalGlobe, the hurricane packed sustained winds at more than 130 miles per hour and has been identified as the largest single rainmaking event in continental U.S. history.

    The images show downtown Houston, George Bush Intercontinental Airport and the interstate highways, which are relatively dry. Significant flooding remains in towns east and north of Houston, including Kingwood, Highlands and Channelview, the company says.