Category: Mobile

  • Researchers Use Traffic App Data to Identify Accident Hotspots

    Researchers at Israel’s Ben-Gurion University of the Negev (BGU) say reveal that data culled from geosocial networks like the GPS traffic app Waze can help prevent traffic incidents with better deployment of police resources at the most accident prone areas.

    “Only now are we beginning to discover the potential in the huge amount of data collected daily,” explains BGU researcher and Ph.D. student Michael Fire. “Studies of this kind, which monitor events such as traffic accidents over time, can help the police identify dangerous sections of roads in real time, or alternatively, locations where few police are needed.”

    The paper, “Data Mining Opportunities in Geosocial Networks for Improving Road Safety,” was presented at the IEEE 27th Convention of Electrical and Electronics Engineers in Israel.

    Waze records location data and enables users to upload and share comments on any detail, including traffic alerts, accidents or police presence. According to its website, Waze has 30 million worldwide users and describes itself as “a community-based traffic and navigation app whose users share real-time traffic and road info, saving time and gas money.”

    Using Waze data and Google Earth, the BGU researchers determined that three-quarters (75 percent) of the locations in Israel with the highest number of accidents were intersections. They then analyzed references to a police presence to determine if the police were present at the spots that had the worst traffic accidents.

    “There were numerous instances where the police were manning quieter intersections, while busier intersections went unmonitored,” Fire explains.  “According to the data, police response time varied from 20 minutes to 40 minutes in some situations.”

    Using Waze, data from May and June 2012 was collected and analyzed on accident reports, police presence, traffic jams, and speed traps. BGU researchers identified 579 different locations in Israel that had at least five reoccurring accidents during this time where 5,156 reported accidents occurred. Police were reported at least 15 times at more than 3,500 locations.

    Other researchers involved with the study from BGU’s Department of Information Systems Engineering and BGU’s Telekom Innovation Laboratories include Prof. Yuval Elovici, head of the lab, as well as Dr. Rami Puzis, Prof. Lior Rokach as well as student Dima Kagan.

  • Report Looks at Indoor Location Positioning and Mobile Markets

    In December 2011, Grizzly Analytics released its first comprehensive report on indoor location positioning technology, predicting that indoor location services were ready to revolutionize the mobile market. The five months that followed have shown how true this was, with new initiatives announced on a regular basis and numerous demonstrations at industry conferences, Grizzly Analytics says.

    In a fully revised and updated 163-page report, Grizzly Analytics gives an up-to-date analysis and comprehensive overview of indoor location positioning R&D. Included is information on the research activity of all the major mobile companies — Google, Microsoft, Samsung, Apple, Nokia, RIM, Cisco, Qualcomm, Broadcom, STMicroElectronics, Sony Ericsson and others — and also more than 30 start-up companies that are actively bringing indoor location services to market.

    “These technologies are poised to revolutionize smartphone usage by enabling GPS-style mapping, navigation, local search, check-ins, location-sharing and other location-based services to work indoors in malls, megastores, offices, airports, casinos and other big indoor places,” according to a statement by Grizzly Analytics. “Indoor location will also transform commerce, enabling searching for items on store shelves, sending deals and promotions to nearby customers, advertisements for nearby stores in malls, and more. Location services are also entering the enterprise, with indoor asset tracking, employee search, and more.

    “In this updated technology trend report, Indoor Location Positioning: Research Pipelines, Start-ups and Predictions, Grizzly Analytics answers the questions you have about this new technology. What approaches are being researched by different companies? Which companies have mature research? What are the gaps in each company’s research that they are likely to fill by acquiring start-up companies? Which start-up companies are likely to be acquired or to emerge successful in the market? What areas of technology are not yet addressed by start-ups, and remain open to new entrepreneurs and investors?”

    A related report, Indoor Location Solutions and Services: Challenges, Opportunities and Market Outlook, is also available from Research and Markets.

  • Telit Introduces Qualcomm-Based HSPA Modules for Global M2M Markets

    Telit Wireless Solutions today introduced the UE910 V2 HSDPA (High Speed Downlink Packet Access) and HE910 V2 HSPA+ (High Speed Packet Access) modules based on Qualcomm Technologies, Inc. chipsets, each to be banded for European and North American markets.

    The MDM6200-based HE910 V2 supports both GPS and GLONASS location technologies, is fully digital audio capable, and provides full-duplex PCM input and output. With these features — combined with the up to 14.4Mpbs downlink and 5.76Mbps uplink data rates — the HE910 V2 is designed for applications such as video surveillance and security, and emerging applications areas such as healthcare, Smart Home, and Smart Grid.

    Both products feature dual-band 3G and GSM/GPRS/EDGE support. The entry-level 3G UE910 V2 is based on Qualcomm Technologies’ QSC6270 chipset and delivers a top 3.6Mbps downlink data rate.

    The new products are fully compatible with Telit’s xE910 family and can be easily dropped into existing or planned designs for xE910 modules requiring no additional rework. Positioned at entry-level and mid-range respectively, the new Qualcomm Technologies-based UE910 V2 and HE910 V2 modules enable the Telit xE910 family to enhance cross-technology compatibility with its other popular global air-interface technologies. The application of the Qualcomm Technologies chipsets improves interchangeability between CDMA (1xRTT, EV-DO) and UMTS (HSDPA, HSPA+) variants making the adaptation of customer applications to regional technical requirements quick and easy, minimizing time to market and total cost of ownership.

    The QSC6270-based UE910 V2 is to be positioned as a 2G to 3G migration path product, and includes high-value features such as analog audio, making it ideal for applications from home and commercial security and surveillance systems, to asset monitoring, logistics, and mass-transit monitors. Telit is planning a UE910 V2 variant based on QSC6270-Turbo with additional support for Java J2ME 3.2 and eCall.

    Both the UE910 V2 and HE910 V2 will be available in local band-group variants as required for all major carriers and partner networks in North America and Europe. The Qualcomm Technologies-based products will be available in North America with 850/1900MHz and in Europe with 900/2100MHz dual-band combinations. Both regional variants will be available in data-only as well as data & voice variants.

    “The Qualcomm Technologies-based entry-level 3G UE910 V2 and mid-range HE910 V2 are Telit’s new 3G products launched in response to increasing demand for dual-band HSDPA, and HSPA+ modules,” said Dominikus Hierl, chief marketing officer at Telit Wireless Solutions. “They come to address the need from application areas and regions requiring easy interchangeability between CDMA or UMTS lines of air interface technology, particularly in United States, Europe and key opportunities.”

    “Qualcomm Technologies’ fully-integrated QSC6270, QSC6270-Turbo and MDM6200 chipsets support the bandwidth and feature requirements of a broad range of M2M applications, and we are pleased to enable  HSDPA, and HSPA+ products in the xE910 family,” said Nakul Duggal, vice president of product management for IOE, Qualcomm Technologies. “By using Qualcomm Technologies’ Gobi 3G solutions in its xE910 product family, Telit will be able to offer its customers the technology flexibility to address M2M products and drive 2G to 3G migration in Europe and North America.”

  • Trimble, ng Connect Collaborate on Connected Service Vehicle Demo

    Trimble’s ThingMagic Mercury6 (M6) RFID Reader will be part of the ng Connect Program’s Connected Service Vehicle, which showcases a full suite of cloud-based services designed to deliver office productivity to vehicle-based workers. In this concept vehicle, the ThingMagic reader will be used to support work-order based inventory management and tool tracking applications to illustrate aspects of a typical service visit.

    The ng Connect Program, founded by Alcatel-Lucent, is a multi-industry ecosystem dedicated to the creation of the new generation connected user experience. ng Connect is comprised of more than 190 Contributing and Associate member companies including network, consumer electronics, application and content providers. Twelve proof of concept demos will be featured this year in the Alcatel-Lucent CES booth at the 2013 Consumer Electronics Show, January 8-11, in Las Vegas.

    As a collaborating member of the ng Connect program, Trimble is providing the development platform for in-vehicle RFID solutions and sensor technology for high-volume commercial, industrial and enterprise applications. Achievements in the automotive market include receiving the Ford World Excellence Award for contributions to a first-to-market RFID-enabled solution designed to help contractors track and manage their tools.

    “We’re honored to join the ecosystem of innovative, market-shaping companies in the ng Connect program,” said Bernd Schoner, vice president of business development at Trimble’s ThingMagic Division. “Using the vehicle as the basic point of data capture can enhance productivity. Uploading asset information from the vehicle to a central data aggregation layer for anywhere, anytime consumption by a variety of applications is the future.”

  • Sygic Launches Location Sharing and Family Safety App

    Family,” a new app by GPS navigation software company Sygic, is designed to help parents keep their children safe and simplify the way families stay in touch. The app is now live on the Apple App Store and Google Play Store.

    The app shows the real-time location of all the family members on the map. It allows parents to set up Safe / Unsafe zones and sends automatic notifications when kids enter or leave a zone. Geofence is useful for one-time notification when users enter certain areas. Augmented reality shows family members in the real surroundings — for example, if kids are running around in a park. Navigation to the family member’s location can be launched from within the app. The app also features free family messaging.

    “We wanted to create an app that will help its users in their everyday life,” said Sygic’s CEO Michal Stencl. “As parents we want to raise our children to be self-reliant but we also need to have confidence that they are safe. Family by Sygic gives parents this peace of mind, while kids will appreciate that parents don’t feel the need to call them all the time to check where they are.”

    The app is free until January 31st on Google Play and App Store. Afterward, the price will be 2.99 Euro per year/family.

  • Qualcomm, AT&T Support Internet of Everything Development Platform

    Qualcomm Incorporated, through its wholly-owned subsidiary Qualcomm Technologies, Inc., has announced an Internet of Everything (IoE) development platform based on Qualcomm Technologies’ QSC6270-Turbo chipset that supports Oracle’s Java ME Embedded 3.2. The IoE development platform features support for standalone GPS.

    The platform, which uses Qualcomm Technologies’ Gobi modem solution for 3G, enables developers to accelerate development efficiency and decrease time-to-market for a wide range of applications and devices to connect to the AT&T mobile internet. AT&T and Qualcomm Technologies expect this IoE development platform to be available to developers in the second quarter of 2013.

    The IoE development platform provides a starting point for creating a range of cellular-connected products and applications for IoE verticals such as tracking, industrial controls and health care. With this platform being capable of supporting Oracle’s Java ME Embedded 3.2 software release, developers with little mobile development experience can quickly go from concept to writing and executing Java applications directly on the QSC6270-Turbo chipset.

    In North America, this IoE development platform will be supported by AT&T, allowing developers to test their solutions and demonstrate functionality on a live network in the design and development phases, which can reduce complexity, cost and time for developers as they drive to get their solutions to market. With access to the various hardware interfaces and capabilities of the 3G modem via the application environment hosted on the QSC6270-Turbo chipset, developers can also customize and optimize end-product PCBs without the need for additional discreet processors or micro-controllers, thus cost-effectively integrating cellular capabilities into a wider range of devices and solutions.

    The platform includes several onboard sensors and indicators, including an accelerometer, light sensor and temperature sensor. The Java ME 3.2 software release, which can run on this platform, includes several new JSRs for IoE applications, as well as Device Access and AT Command Pass Through APIs that give developers access to a large number of chipset IOs and interfaces, such as GPIO, I2C and SPI. The platform supports cellular coverage for tri-band UMTS/HSDPA – 2100/1900/850 MHz – and quad-band GSM – 850/900/1800/1900 MHz – support, as well as 2.4GHz Wi-Fi a/b/g/n via a Qualcomm Atheros, Inc. AR6103 module.

    “This IoE development platform opens a world of opportunity for equipment makers who want to connect their devices to the mobile internet,” said Chris Penrose, senior vice president, emerging devices, AT&T. “Wireless connectivity makes products better, and this IoE development platform makes it easier for both existing and new AT&T developers to embed wireless into their products.”

    “Qualcomm Technologies sees the Internet of Everything as having significant potential. In addition to large IoE verticals like automotive and energy that have established industry players, application developers are key to creating future IoE verticals and applications that haven’t even been thought of yet,” said Kanwalinder Singh, senior vice president of business development, Qualcomm Technologies, Inc. “This IoE development platform with Java support is a tool to extend the power of our integrated chipsets to application developers. We are excited that AT&T shares our vision of a cellular-connected IoE, and by the opportunities that will be created by the AT&T developer community.”

  • iOnRoad Steers iPhone Navigation Towards Safer Driving

    iOnRoad,  the maker of the iOnRoad app that improves driving in real-time using the power of modern computer vision algorithms and smart-phone cameras, has released its award-winning app on iOS 6 operating systems. iOnRoad, now available for immediate download in the App Store, is taking advantage of the leap in processing power of the iPhone 5 and  new navigation integration offered on iOS 6, the company said.

    iOnRoad’s new iOS 6 features bring about a whole new depth to driving assistance applications. The iOnRoad application’s advanced fusion with iOS 6 navigation allows the driver the benefit of turn-by-turn navigation along with iOnRoad’s augmented driving UI. Furthermore, iOnRoad’s new “black-box” like video recording feature acts as a virtual driving log, archiving users’ driving history. Should an accident occur, drivers may now be given a greater understanding of the events leading up to it.

    “We have serviced hundreds of thousands of mobile users over the past year and are excited to provide iPhone users an enhanced version of iOnRoad,” said Alon Atsmon, CEO of iOnRoad. “In addition, the new in-phone analytics dashboard tells a driver how safe and ‘green’ the drive was and can even estimate gas prices, which is quite useful given the fluctuation in gas prices today.”

    iOnRoad uses the iPhone camera and sensors to detect lanes and vehicles in front of the vehicle, alerting drivers when they are in danger. The app provides a range of personal driving assistance functions including augmented driving, collision warning, speeding alert and safety scoring.

    “We are witnessing a trend in which  systems and features that we used to find in jet-planes such as navigation, collision warnings, HUD and night vision are increasingly finding their way into the driving environment,” says Atsmon. iOnRoad’s innovation and market leadership has been validated by numerous industry awards including the 2012 CTIA E-Tech Award, CES 2012 showcase award, and one of Gartner’s cool vendors in automotive for 2012.

    View a video of iOnRoad in action.

  • LiveViewGPS Transforms Cell Phone into Location Device

    LiveViewGPS, a GPS tracking company for business, government and individuals, is unveiling a prepaid Mobile Phone Locate Card in Booth #75015 in the Eureka Park area at the International CES Show in Las Vegas this week. The card allows users to transform a cell phone into a 24-hour safety location device for families and businesses without having to buy a $100 locator or expensive apps.

    Mobile Phone Locate capitalizes on the location technology already built into cell phones to instantly locate single or multiple phones, explained George Karonis, LiveViewGPS CEO. It uses both Assisted GPS and cell network data to ensure fast, accurate locates for discreet monitoring when and where it’s needed. Because location accuracy depends on cell phone reception, GPS settings, environmental conditions and more, results can vary from a few feet to several thousand feet.

    Under the program, a customer purchases a prepaid LiveViewGPS Mobile Phone Locate card either online or at a retail store. After signing up, users select a locate plan and register the phones they want to locate. An SMS text is sent to the target phone(s) requesting a reply. Once the phone users opt in, the Mobile Phone Locater service is immediately activated. With a single click, the target phone’s location is displayed on a high-resolution graphic or satellite view map. There is no software to install, no battery draining app to download, no expensive devices to buy, and no contract to sign.

    The Mobile Phone Locate service is approved for use and works with Tier 1 carriers in North America including AT&T, T-Mobile, Sprint PCS, Verizon, Boost Mobile and TracFone in the United States; and Rogers and Telus in Canada. More carriers and countries will be added as they become available.

    “For businesses, keeping track of a mobile workforce is easier than ever,” Karonis added. “Mobile Phone Locate is a cost-effective, in-the-field management solution that’s fast, easy and reliable. It offers value-driven, on demand mobile location services businesses can trust. Deployment is easy across one or 1000 phones, with no additional hardware to purchase or battery draining apps to install.

  • TI’s Wi-Link 8Q Provides Wireless Connectivity for Auto Infotainment

    Wireless connectivity is becoming a key feature in automobiles for sharing and viewing content from smartphones and tablets to in-car systems, easy pairing of devices, navigation and replacement of expensive cables for in-car communication. To answer this need, today Texas Instruments Incorporated (TI) introduced the WiLink 8Q family of wireless automotive connectivity solutions.

    “GNSS technology combines GPS and GLONASS signals with the on-chip positioning engine producing a more accurate fix of your location, making “urban canyons” non-existent,” according to the TI Behind the Wheel blog. TI is demonstrating WiLink 8Q and other technologies at the Consumer Electronics Show this week in Las Vegas.

    With its multi-radio technology, the WiLink 8Q family reaches new levels of cross platform scalability and delivers advanced features including in-car multimedia streaming video in parallel with Bluetooth hands-free calling and advanced audio distribution profile (A2DP) stereo sound. Additionally, with near field communications (NFC) for easy Wi-Fi and Bluetooth pairing, WiLink 8Q solutions enable an easy connection between a smartphone or tablet and the automobile, providing a seamless user experience, according to TI.

    The WiLink 8Q family is designed for Wi-Fi Certified Miracast operation. With an integrated power amplifier (PA) and complete software reuse across all family members, WiLink 8Q solutions provide a full range of products for wireless automotive infotainment including:

    • Super-combo SoCs with Wi-Fi, Bluetooth, Bluetooth low energy, NFC, and GNSS support.
    • Combo-connectivity system-on-chips (SoCs) with Wi-Fi and Bluetooth support.
    • More integrated combo-connectivity SoCs with Wi-Fi, Bluetooth, Bluetooth low energy and NFC.

    “Delivering the familiar experience consumers have with smartphones and the tablets into the automobile to share information and content from drivers’ and passengers’ devices is driving the need for strong wireless connectivity solutions. Wi-Fi, Bluetooth, NFC and GNSS have to work together seamlessly as integrated parts of the entire system,” said Mattias Lange, automotive connectivity product line manager, Wireless Connectivity Solutions, TI. “The WiLink 8Q family takes our expertise in wireless connectivity and automotive applications to the next level with support of four different RF technologies on one SoC – a truly integrated approach to automotive infotainment.”

  • Spectrum Interference Standards: Seeking a Win-Win Rebound from Lose-Lose

     

    By Christopher J. Hegarty

    Based upon lessons learned from the LightSquared situation, the author identifies important considerations for GPS spectrum interference standards, recommended by the PNT EXCOM for future commercial proposals in bands adjacent to the RNSS band to avoid interference to GNSS.

    On January 13, 2012, the U.S. National Positioning, Navigation, and Timing Executive Committee (PNT EXCOM) met in Washington, D.C., to discuss the latest round of testing of the radiofrequency compatibility between GPS and a terrestrial mobile broadband network proposed by LightSquared. The proposed network included base stations transmitting in the 1525 – 1559 MHz band and handsets transmitting in the 1626.5 – 1660.5 MHz band. These bands are adjacent to the 1559 – 1610 MHz radionavigation satellite service (RNSS) band used by GPS and other satellite navigation systems. Based upon the test results, the EXCOM unanimously concluded that “both LightSquared’s original and modified plans for its proposed mobile network would cause harmful interference to many GPS receivers,” and that further “there appear to be no practical solutions or mitigations” to allow the network to operate in the near-term without resulting in significant interference.

    The LightSquared outcome was a lose-lose in the sense that billions were spent by the investors in LightSquared and, as noted by the EXCOM, “substantial federal resources have been expended and diverted from other programs in testing and analyzing LightSquared’s proposals.” To avoid a similar situation in the future, the EXCOM proposed the development of “GPS Spectrum interference standards that will help inform future proposals for non-space, commercial uses in the bands adjacent to the GPS signals and ensure that any such proposals are implemented without affecting existing and evolving uses of space-based PNT services.”

    This article identifies and describes several important considerations in the development of GPS spectrum interference standards towards achieving the stated EXCOM goals. These include the identification of characteristics of adjacent band systems and an assessment of the susceptibility of all GPS receiver types towards interference in adjacent bands. Also of vital importance to protecting GPS receivers is an understanding of the user base, applications, and where the receivers for each application may be located while in use. This information, along with the selection of proper propagation models, allows one to establish transmission limits on new adjacent-band systems that will protect currently fielded GPS receivers. The article further comments on the implications of the evolution of GPS and foreign satellite navigation systems upon the development of efficacious spectrum interference standards.

    Adjacent Band Characteristics

    The type of adjacent-band system for which there is currently the greatest level of interest is a nationwide wireless fourth-generation (4G) terrestrial network to support the rapidly growing throughput demands of personal mobile devices. Such a nationwide network would likely consist of tens of thousands of base stations distributed throughout the United States and millions of mobile devices. The prevalent standard at the present time is Long Term Evolution (LTE), which is being deployed by all of the major U.S. carriers. LTE and Advanced LTE provide an efficient physical layer for mobile wireless services. Worldwide Interoperability for Microwave Access (WiMAX) is a competing wireless communication standard for 4G wireless that is a far-distant second in popularity.

    For the purposes of the discussion within this article, an LTE network is assumed with characteristics similar to that proposed by LightSquared but perhaps with base stations and mobile devices that transmit upon different center frequencies and bandwidths. The primary characteristics include:

    • Tens of thousands of base stations nationwide, reusing frequencies in a cellular architecture, with the density of base stations peaking in urban areas.
    • Base-station antennas at heights from sub-meter to 150 meters above ground level (AGL), with a typical height of 20–30 meters AGL. Each base station site has 1–3 sector antennas mounted on a tower such that peak power is transmitted at a downtilt of 2–6 degrees below the local horizon, with a 60–70 degree horizontal 3-dB beamwidth and 8–9 degree vertical 3-dB beamwidth.
    • Peak effective isotropic radiated power (EIRP) in the vicinity of 20–40 dBW (100–10,000 W) per sector.
    • Mobile devices transmit at a peak EIRP of around 23 dBm (0.2 W), but substantially lower most of the time when lower power levels suffice to achieve a desired quality of service as determined using real-time power control techniques.
    • As LTE uses efficient transmission protocols, emissions can be accurately modeled as brickwall, that is, confined to a finite bandwidth around the carrier.

    Throughout this article it will be presumed that LTE emissions in the bands authorized for RNSS systems such as GPS will be kept sufficiently low through regulatory means.

    The opening photo shows a typical base-station tower, with three sectors per cellular service provider and with multiple service providers sharing space on the tower, including non-cellular fixed point microwave providers. As a cellular network is being built out, coverage is at first most important, and many base-station sites will use minimum downtilt and peak EIRPs within the ranges described above. As the network matures, capacity becomes more important. High-traffic cells are split through the introduction of more base stations, and this is commonly accompanied by increased downtilts and lower EIRPs.

    The assumed characteristics for adjacent band systems plays a paramount role in determining compatibility with GPS, and obviously lower-power adjacent-band systems would be more compatible. If compatibility with GPS precludes 4G network implementation on certain underutilized frequencies adjacent to RNSS bands, then it may be prudent to refocus attention for these bands on alternative lower-power systems.

    GPS Receiver Susceptibility

    Over the past two years, millions of dollars have been expended to measure or analyze the susceptibility of GPS receivers to adjacent band interference as part of U.S. regulatory proceedings for LightSquared. Measurements were conducted through both radiated (see photo) and conducted tests at multiple facilities, as well as in a live-sky demonstration in Las Vegas. This section summarizes the findings for seven categories of GPS receivers. These categories, which were originally identified in the Federal Communications Commission (FCC)-mandated GPS-LightSquared Technical Working Group (TWG) formed in February 2011, are: aviation, cellular, general location/navigation, high-precision, timing, networks, and space-based receivers.

    Aviation. Certified aviation GPS receivers are one of the few receiver types for which interference requirements exist. These requirements take the form of an interference mask (see Figure 1) that is included in both domestic and international standards. Certified aviation GPS receivers must meet all applicable performance requirements in the presence of interference levels up to those indicated in the mask as a function of center frequency. In Figure 1 and throughout this article, all interference levels are referred to the output of the GPS receiver passive-antenna element. Although the mask only spans 1500–1640 MHz, within applicable domestic and international standards the curves are defined to extend over the much wider range of frequencies from 1315 to 2000 MHz.

    Figure 1. Certified aviation receiver interference mask. Credit: Christopher J. Hegarty
    Figure 1. Certified aviation receiver interference mask.

    A handful of aviation GPS receivers were tested against LightSquared emissions in both conducted and radiated campaigns. The results indicated that these receivers are compliant with the mask with potentially some margin. However, the Federal Aviation Administration (FAA) noted the following significant limitations of the testing:

    • Not all receiver performance requirements were tested.
    • Only a limited number of certified receivers were tested, and even those tested were not tested with every combination of approved equipment (for example, receiver/antenna pairings).
    • Tests were not conducted in the environmental conditions that the equipment was certified to tolerate (for example, across the wide range of temperatures that an airborne active antenna experiences, and the extreme vibration profile that is experienced by avionics upon some aircraft).

    Due to these limitations, the FAA focused attention upon the standards rather than the test results for LightSquared compatibility analyses, and these standards are also recommended for use in the development of national GPS interference standards. One finding from the measurements of aviation receivers that may be useful, however, is that the devices tested exhibited susceptibilities to out-of-band interference that were nearly constant as a function of interference bandwidth. This fact is useful since the out-of-band interference mask within aviation standards is only defined for continuous-wave (pure tone) interference, whereas LightSquared and other potential adjacent-band systems use signals with bandwidths of 5 MHz or greater.

    Cellular. The TWG tested 41 cellular devices supplied by four U.S. carriers (AT&T, Sprint, US Cellular, and Verizon) against LightSquared emissions in the late spring/early summer of 2011. At least one of the 41 devices failed industry standards in the presence of a 5- or 10-MHz LTE signal centered at 1550 MHz at levels as low as –55 dBm, and at least one failed for a 10-MHz LTE signal centered at 1531 MHz at levels as low as –45 dBm. The worst performing cellular devices were either not production models or very old devices, and if the results for these devices are excluded, then the most susceptible device could tolerate a 10-MHz LTE signal centered at 1531 MHz at power levels of up to –30 dBm. Careful retesting took place in the fall of 2011, yielding a lower maximum susceptibility value of –27 dBm under the same conditions.

    General Location/Navigation. The TWG effort tested 29 general location/navigation devices. In the presence of a pair of 10-MHz LTE signals centered at 1531 MHz and 1550 MHz, the most susceptible device experienced a 1-dB signal-to-noise ratio (SNR) degradation when each LTE signal was received at –58.9 dBm. In the presence of a single 10-MHz LTE signal centered at 1531 MHz, the most susceptible device experienced a 1-dB SNR degradation when the interfering signal was received at –33 dBm.

    Much more extensive testing of the effects of a single LTE signal centered at 1531 MHz on general location/ navigation devices was conducted in the fall of 2011, evaluating 92 devices. The final report on this campaign noted that 69 of the 92 devices experienced a 1-dB SNR decrease or greater when “at an equivalent distance of greater than 100 meters from the LightSquared simulated tower.” Since the tower was modeled as transmitting an EIRP of 62 dBm, the 100-meter separation is equivalent to a received power level of around –14 dBm. The two most susceptible devices experienced 1-dB SNR degradations at received power levels less than –45 dBm.

    High Precision, Timing, Networks. The early 2011 TWG campaign tested 44 high-precision and 13 timing receivers. 10 percent of the high-precision (timing) devices experienced a 1-dB or more SNR degradation in the presence of a 10-MHz LTE signal centered at 1550 MHz at a received power level of –81 dBm (–72 dBm). With the 10-MHz LTE signal centered at 1531 MHz, this level increased to –67 dBm (–39 dBm).

    The reason that some high-precision GPS receivers are so sensitive to interference in the 1525–1559 MHz band is that they were built with wideband radiofrequency front-ends to intentionally process both GPS and mobile satellite service (MSS) signals. The latter signals provide differential GPS corrections supplied by commercial service providers that lease MSS satellite transponders, from companies including LightSquared.

    Space. Two space-based receivers were tested for the TWG study. The first was a current-generation receiver, and the second a next-generation receiver under development. The two receivers experienced 1-dB C/A-code SNR degradation with total interference power levels of –59 dBm and –82 dBm in the presence of two 5-MHz LTE signals centered at 1528.5 MHz and 1552.7 MHz. For a single 10-MHz LTE signal centered at 1531 MHz, the levels corresponding to a 1-dB C/A-code SNR degradation increased to –13 dBm and –63 dBm. The next-generation receiver was more susceptible to adjacent-band interference because it was developed to “be reprogrammed in flight to different frequencies over the full range of GNSS and augmentation signals.”

    Discussion. Although extensive amounts of data were produced, the LightSquared studies are insufficient by themselves for the development of GPS interference standards, since they only assessed the susceptibility of GPS receivers to interference at the specific carrier frequencies and with the specific bandwidths proposed by LightSquared. If GPS interference standards are to be developed for additional bands, then much more comprehensive measurements will be necessary.

    Interestingly, NTIA in 1998 initiated a GPS receiver interference susceptibility study, funded by the Department of Defense (DoD) and conducted by DoD’s Joint Spectrum Center. One set of curves produced by the study is shown in Figure 2. This format would be a useful output of a further measurement campaign. The curves depict the interference levels needed to produce a 1-dB SNR degradation to one GPS device as the bandwidth and center frequency of the interference is varied. The NTIA curves only extended from GPS L1 (1575.42 MHz) ± 20 MHz. A much wider range would be needed to develop GPS interference standards as envisioned by the PNT EXCOM. It may be possible, to minimize testing, to exclude certain ranges of frequencies corresponding to bands that stakeholders agree are unlikely to be repurposed for new (for example, mobile broadband) systems.

    Figure 2 Example of NTIA-initiated receiver susceptibility measurements from 1998. Credit: Christopher J. Hegarty
    Figure 2. Example of NTIA-initiated receiver susceptibility measurements from 1998.

    Receiver-Transmitter Proximity

    The LightSquared studies, with the exception of those focused on aviation and space applications, spent far less attention to receiver-transmitter proximity. Minimum separation distances and the associated geometry are obviously very important towards determining the maximum interference level that might be expected for a given LTE network (or other adjacent band system) laydown.

    Within the TWG, the assumption generally made for other (non-aviation, non-space) GPS receiver categories was that they could see power levels that were measured in Las Vegas a couple of meters above the ground from a live LightSquared tower. Figure 3 shows one set of received power measurements from Las Vegas. In the figure, the dots are measured received power levels made by a test van. The top curve is a prediction of received power based upon the free-space path-loss model. The bottom curve is a prediction based upon the Walfisch-Ikegami line-of-sight (WILOS) propagation model. The NPEF studies presumed that the user could be within the boresight of a sector antenna even within small distances of the antenna (where the user would need to be at a significant height above ground).

    Figure-5 . Credit: Christopher J. Hegarty
    Figure 3 Measurements of received power levels from one experimental LightSquared base station sector in Las Vegas live-sky testing.

    The difference between the above received LTE signal power assumptions has been hotly debated, especially after LightSquared proposed limiting received power levels from the aggregate of all transmitting base stations as measured a couple of meters above the ground in areas accessible to a test vehicle. After summarizing the aviation scenarios developed by the FAA, this section highlights scenarios where so-called terrestrial GPS receivers can be at above-ground heights well over 2 meters. The importance of accurately understanding transmitter-receiver proximity is illustrated by Figure 4. This shows predicted received power levels for one LTE base station sector transmitting with an EIRP of 30 dBW and with an antenna height of 20 meters (65.6 feet). The figure was produced assuming the free-space path-loss model and a typical GPS patch-antenna gain pattern for the user. Note that maximum received power levels are very sensitive to the victim GPS receiver antenna height.

    Figure 4 Received power in dBm at the output of a GPS patch antenna from one 30 dBW EIRP LTE base station sector at 20 meters. Credit: Christopher J. Hegarty
    Figure 4. Received power in dBm at the output of a GPS patch antenna from one 30 dBW EIRP LTE base station sector at 20 meters.

    Aviation. The first LightSquared-GPS study conducted for civil aviation was completed by the Radio Technical Commission for Aeronautic (RTCA) upon a request from the FAA. Due to the extremely short requested turnaround time (3 months), RTCA consciously decided not to devote any of the available time developing operational scenarios, but rather re-used scenarios that it had developed for earlier interference studies. It was later realized that the combination of five re-used scenarios and assumed LightSquared network characteristics did not result in an accurate identification of the most stressing real-world scenarios. For instance, within the RTCA report, base stations’ towers were all assumed to be 30 meters in height. At this height, towers could not be close to runway thresholds where aircraft are flying very low to the ground, because this situation would be precluded by obstacle clearance surfaces. Later studies used actual base-station locations, from which the aviation community became aware that cellular service providers do place base stations close to airports by utilizing lower base-station heights as necessary to keep the antenna structure just below obstacle clearance surfaces.

    The FAA completed an assessment of LightSquared-GPS compatibility in January 2012 that identified scenarios where certified aviation receivers could experience much higher levels of interference than was assessed in the RTCA report. The areas where fixed-wing and rotary-wing aircraft rely on GPS are depicted in Figures 5 and 6 (above the connected line segments), respectively.

    Figure-7 . Credit: Christopher J. Hegarty
    Figure 5. Area where GPS use must be sssured for fixed-wing aircraft.
    Figure-8 . Credit: Christopher J. Hegarty
    Figure 6. Area where GPS use must be assured for rotary-wing aircraft.

    Aircraft rely upon GPS for navigation and Terrain Awareness and Warning Systems (TAWS). Helicopter low-level en-route navigation and TAWS for fixed- and rotary-wing aircraft are perhaps the most challenging scenarios for ensuring GPS compatibility with adjacent-band cellular networks. In these scenarios, the aircraft can be within the boresight of cellular sector antennas and in very close proximity, resulting in very high received-power levels. The FAA attempted to provide some leeway for LightSquared while maintaining safe functionality of TAWS through the concept of exclusion zones (see Figure 7). The idea of an exclusion zone is that, at least for cellular base-station transmitters on towers that are included within TAWS databases, that it would be permitted for the GPS function to not be available for very small zones around the LTE base-station tower. This concept is currently notional only; the FAA plans to more carefully evaluate the feasibility of this concept and appropriate exclusion-zone size with the assistance of other aviation industry stakeholders.

    Figure-9 . Credit: Christopher J. Hegarty
    Figure 7. Example exclusion area around base station to protect TAWS.

    High-precision and Networks: Reference Stations. To gain insight into typical reference-station heights for differential GPS networks, the AGL heights of sites comprising the Continuously Operating Reference Station (CORS) network organized by the National Geodetic Survey (NGS) were determined. The assessment procedure is detailed in the Appendix.

    Figure 8 portrays a histogram of estimated AGL heights for the 1543 operational sites within the continental United States (CONUS) as of February 2012. The accuracy of the estimated AGL heights is on the order of 16 meters, 90 percent, limited primarily by the quality of the terrain data that was utilized. The mean and median site heights are 5.7 and 5.2 meters, respectively.

    Figure 8. Distribution of heights for CORS sites. Credit: Christopher J. Hegarty
    Figure 8. Distribution of heights for CORS sites.

    RALR, atop the Archdale Building in Raleigh, North Carolina, was the tallest identified site at 64.1 meters. This site, however, was decommissioned in January 2012 (although it was identified as operational in a February 2012 NGS listing of sites). The second tallest site identified is WVHU in Huntington, West Virginia at 39.6 meters, which is still operational atop of a Marshall University building. 223 of the 1543 CORS sites within CONUS have AGL heights greater than 10 meters, and furthermore the taller sites tend to be in urban areas where cellular networks tend to have the greatest base-station density.

    High Precision and Networks: End Users. Many high-precision end users employ GPS receivers at considerable heights above ground. For instance, high-precision receivers are relied upon within modern construction methods. The adjacent photos show GPS receivers used for the construction of a 58-story skyscraper called The Bow in Calgary, Canada. For this project, a rooftop control network was established on top of neighboring buildings using both GPS receivers and other surveying equipment (for example, 360-degree prisms for total stations), and GPS receivers were moved up with each successive stage of the building to keep structural components plumb and properly aligned. Similar techniques are being used for the Freedom Tower, the new World Trade Center, in New York City, and many other current construction projects.

    Other terrestrial applications that rely on high-precision GPS receivers at high altitudes include structural monitoring and control of mechanical equipment such as gantry cranes. At times, even ground-based survey receivers can be substantially elevated. Although a conventional surveying pole or tripod typically places the GPS antenna 1.5 – 2 meters above the ground, much longer poles are available and occasionally used in areas where obstructions are present. 4-meter GPS poles are often utilized, and poles of up to 40 ft (12.2 meters) are available from survey supply companies.

    General Location/Navigation. Although controlling received power from a cellular network at 2 meters AGL may be suitable to protect many general navigation/location users, it is not adequate by itself. For example, GPS receivers are used for tracking trucks and for positive train control (the latter mandated in the United States per the Rail Safety Improvement Act of 2008). GPS antennas for trucks and trains are often situated on top of these vehicles. Large trucks in the United States for use on public roads can be up to 13 ft, 6 in (~4.1 meters), and a typical U.S. locomotive height is 15 ft, 5 in (~4.7 meters). Especially in a mature network that is using high downtilts, received power at these AGL heights can be substantially higher than at 2 meters.

    Within the TWG and NPEF studies, the general location/navigation GPS receiver category is defined to include non-certified aviation receivers. One notable application is the use of GPS to navigate unmanned aerial vehicles. UAVs are increasingly being used for law enforcement, border control, and many other applications where the UAV can be expected to occasionally pass within the boresight of cellular antennas at short ranges.

    Cellular. The majority of Americans own cell phones, and a growing number are using cell phones as a replacement for landlines within their home. Already, 70 percent of 911 calls are made on mobile phones. Although pedestrians and car passengers are often within 2 meters of the ground, this is not always the case. Figure 9 shows three cellular sector antennas situated atop a building filled with residential condominiums. The rooftop is accessible and frequently used by the building inhabitants. According to an online real estate advertisement, “The Garden Roof was voted the Best Green Roof in Town and provides amazing 360 degree views of downtown Nashville as well as four separate sitting areas and fabulous landscaping.” One of the sector antennas is pointing towards the opposite corner of the building. If the downtilt is in the vicinity of 2–6 degrees, then it is quite likely that a person making a 911 call from the rooftop could see a received power level of –10 dBm to 0 dBm, high enough to disrupt GPS within most cellular devices if the antennas were transmitting in the 1525–1559 MHz band.

    Figure 9. Cellular antennas atop Westview Condominium Building in downtown Nashville. Credit: Christopher J. Hegarty
    Figure 9. Cellular antennas atop Westview Condominium Building in downtown Nashville.

    This situation is not unusual. Many cellular base stations are situated on rooftops in urban areas, and many illuminate living areas in adjacent buildings. In recent years, New York City even considered legislation to protect citizens from potential harmful effects of the more than 2,600 cell sites in the city, since many sites are in very close proximity to residential areas.

    Propagation Models

    Within the LightSquared proceedings, there was a tremendous amount of debate regarding propagation models. Communication-system service providers typically use propagation models that are conservative in their estimates of received power levels in the sense that they overestimate propagation losses. This conservatism is necessary so that the service can be provided to end users with high availability. From the standpoint of potential victims of interference, however, it is seen as far more desirable to underestimate propagation losses so that interference can be kept below an acceptable level a very high percentage of time. As shown in Figure 3, some received power measurements from the Las Vegas live-sky test indicate values even greater than would be predicted using free-space propagation model. Statistical models that allow for this possible were used in the FAA Status Report. The general topic of propagation models is worthy of future additional study if GPS interference standards are to be developed.

    Future Considerations

    GPS is being modernized. Additionally, satellite navigation users now enjoy the fact that the Russian GLONASS system has recently returned to full strength with the repopulation of its constellation. In the next decade, satellite navigation users also eagerly anticipate the completion of two other global GNSS constellations: Europe’s Galileo and China’s Compass. Notably, between the GPS modernization program and the deployment of these other systems, satellite navigation users are expected to soon be relying upon equipment that is multi-frequency and that needs to process many more signals with varied characteristics. New equipment offers an opportunity to insert new technologies such as improved filtering, but of course the need to process additional signals and carrier frequencies may make GNSS equipment more susceptible to interference as well. Clearly, these developments will need to be carefully assessed to support the establishment of GPS spectrum interference standards.

    Summary

    This article has identified a number of considerations for the development of GPS interference standards, which have been proposed by the PNT EXCOM. If the United States proceeds with the development of such standards, it is hoped that the information within this article will prove useful to those involved.

    Bow highrise under construction in Calgary, showing GPS receivers in use ( . photos courtesy Rocky Annett, MMM Group Ltd.) .Credit: Christopher J. Hegarty
    Bow highrise under construction in Calgary, showing GPS receivers in use (photos courtesy Rocky Annett, MMM Group Ltd.)
    Bow highrise under construction in Calgary, showing GPS receivers in use (photos courtesy Rocky Annett, MMM Group Ltd.) . Credit: Christopher J. Hegarty
    (Photo courtesy of Rocky Annett, MMM Group Ltd.)
    Bow highrise under construction in Calgary, showing GPS receivers in use (photos courtesy Rocky Annett, MMM Group Ltd.) . Credit: Christopher J. Hegarty
    (Photo courtesy of Rocky Annett, MMM Group Ltd.)

     

    Appendix: AGL Heights of CORS Network Sites

    The National Geodetic Survey Continuously Operating Reference Station (CORS) website provides lists of CORS site locations in a number of different reference frames. To determine the height above ground level (Screen shot 2013-01-07 at 12.35.25 PM . Credit: Christopher J. Hegarty) for each site within this study, two of these files (igs08_xyz_comp.txt and igs08_xyz_htdp.txt) were used. These two files provide the (x,y,z) coordinates of the antenna reference point (ARP) for each site in the International GNSS Service 2008 (IGS08) reference frame, which is consistent with the International Terrestrial Reference Frame (ITRF) of 2008. These coordinates are divided into two files by NGS, since the site listings also provide site velocities and velocities are either computed (for sites that have produced data for at least 2.5 years) or estimated (for newer sites). The comp file includes sites with computed velocities and the htdp file includes sites with estimated velocities (using a NGS program known as HTDP).

    The data files can be used to readily produce height above the ellipsoid, Screen shot 2013-01-07 at 12.35.17 PM .  Credit: Christopher J. Hegarty, for each site. This height can be found using well-known equations to convert from (x, y, z) to (latitude, longitude, height). Obtaining estimates of Screen shot 2013-01-07 at 12.35.25 PM . Credit: Christopher J. Hegarty requires information on the geoid height and terrain data, per the relationship:

    Screen shot 2013-01-07 at 12.35.31 PM .Credit: Christopher J. Hegarty  (A-1)

    For the results presented in this article, terrain data was obtained from http://earthexplorer.usgs.gov in the Shuttle Radar Topography Mission (SRTM) Digital Terrain Elevation Data (DTED) Level 2 format. For this terrain data, the horizontal datum is the World Geodetic System (WGS 84). The vertical datum is Mean Sea Level (MSL) as determined by the Earth Gravitational Model (EGM) 1996. Each data file covers a 1º by 1º degree cell in latitude/longitude, and individual points are spaced 1 arcsec in both latitude and longitude. The SRTM DTED Level 2 has a system design 16 meter absolute vertical height accuracy, 10 meters relative vertical height accuracy, and 20 meter absolute horizontal circular accuracy. All accuracies are at the 90 percent level. Considering the accuracies of the DTED data, the differences between WGS-84 and IGS08 as well as between the ARP and antenna phase center were considered negligible. Geoid heights were interpolated from 15-arcmin data available in the MATLAB Mapping Toolbox using the egm96geoid function.

    Lower AGL heights are preferred for CORS sites to minimize motion between the antenna and the Earth’s crust. However, many sites are at significant heights above the ground by necessity, particularly in urban areas due to the competing desire for good sky visibility.


    Christopher J. Hegarty is the director for communications, navigation, and surveillance engineering and spectrum with The MITRE Corporation. He received a D.Sc. degree in electrical engineering from George Washington University. He is currently the chair of the Program Management Committee of the RTCA, Inc., and co-chairs RTCA Special Committee 159 (GNSS). He is the co-editor/co-author of the textbook Understanding GPS: Principles and Applications, 2nd Edition.

     

  • Medical Alert System to Have u-blox GPS and 2G/3G GPS

    u-blox, the Swiss positioning and wireless chip and module company, has been chosen for global positioning and embedded 2G/3G wireless technologies by MobileHelp, an American provider of M-PERS (Mobile-Personal Emergency Response System) technology. Based on u-blox’ LISA 2G/3G wireless modem and MAX GPS modules, the comprehensive system includes compact, portable alert devices that function in and around the home, and while traveling.

    “As the population ages, more and more people are choosing to remain independent for as long as possible” said Robert Flippo, President of MobileHelp. “With the help of u-blox’ reliable, low-power positioning and wireless technologies, our MobileHelp medical alert systems are giving a whole generation of people the freedom to live in their homes and travel independently knowing that simple and fast emergency assistance is just a push-button away.”

    Unlike traditional 911 direct dial services, MobileHelp devices deliver instant positional information as well as personalized medical data to an emergency response center at the touch of a button. The system is integrated with nationwide wireless voice, data and satellite GPS technology to provide real-time medical monitoring services, location tracking, and instant voice contact with trained emergency response operators. MobileHelp also offers Caregiver Tools, an innovative event notification and online tracking platform that keeps families and caregivers informed of an emergency event. With AT&T as connectivity partner, the devices work in 97 percent of the inhabited areas of the USA.

    MobileHelp comes in three configurations, “Classic” for home-monitoring over fixed line telephone, “Solo” for travelling and at homes without a fixed line telephone connection, and “Duo,” for travelling and at homes that have a fixed line telephone connection.

    MobileHelp’s alert products have been developed with Singapore-based Daviscomms, a design and manufacturing partner providing advanced engineering services to customers in the consumer and industrial markets worldwide.

  • Will Fragmentation Hurt Location Business?

    Get out of the way, GPS. Wi-Fi is elbowing in on the location game. Wi-Fi operators are tracking people and offering retailers and marketers access to customers’ behavior and location. Traffic patterns emitted by smartphone Wi-Fi signals let network operators keep tabs on what shoppers are doing. Heat maps are being created with data from Wi-Fi points to map out aggregated customer behavior. Nearbuy Systems offers stores software that will let them track the website that a shopper is viewing, overlaid by where the shopper is within the store. However, beware of companies’ hyped up claims on indoor location. Another worry is the deployment of proprietary location systems which reduce overall usefulness. And some offerings are simply PowerPoint aspirations. In other news, Apple and Google are kings of the hill; in-vehicle mapping belongs to Nokia; and location privacy of a different sort.

    Fragmented Indoor Location. If proprietary indoor location systems are developed, the market will be hampered. Ben Rodilitz of Level8 noted that, while attending GPS Wireless last March, he was bemused by the excitement regarding indoor location as manifested in a number of one-off, proprietary systems. If Home Depot used its own system, an airport used another, and a shopping mall implemented a third, ubiquitous indoor location would be problematic. “I know companies like Qualcomm, Broadcom, and SiRF/CSR were building competing platforms; one would hope this is a vehicle for best-of-breed choices for service providers,” says Rodilitz. I am glad to see the formation of the In-Location Alliance and the players who are supporting it.”

    Other Complications. The nuts and bolts of indoor location aren’t easy peasy. “For detailed location pinpointing in places like malls, a high density of Wi-Fi radios need to be deployed and it isn’t super cheap to do so,” says Joseph DeStasio of Boingo Wireless. Stores may want to deploy a denser Wi-Fi system than in the outer mall. But it can be a clunky transition between two different Wi-Fi systems. DeStasio estimates that true mobile retail location-based advertising/couponing at malls is still 18 months away.

    Mapping in Vehicles. Nokia may be battered, but the mapping it acquired years ago from its acquisition of Navteq is shining bright. Companies have long fought over “ownership” of the in-dash navigation market, and Navteq lords over the market, powering four out of five systems. Nokia has deals with many car makers, including BMW, Hyundai, Mercedes, and Volkswagen, as well as with Pioneer and Garmin.

    Wireless Data Privacy and Mooching. There is always an interesting mobile location privacy case. In Pennsylvania, police obtained a warrant to search the house where child pornography was being downloaded. Police determined that the offender was a neighbor who had been free-loading on the house’s wireless Internet. The suspect was found with Moocherhunter, an app to identify wireless moochers. The suspect argued that police needed a warrant to use the app to locate him. The court ruled that he “could have no reasonable expectation of privacy in the signal he was sending to or receiving” from the wireless router.

    More on Wi-Fi. Towerstream is building wholesale Wi-Fi access points across some urban regions, including Manhattan, with 1,000 access spots arranged in a giant dense honeycomb across the Big Apple. Before you equate this with previous municipal wireless disasters, know that these networks are several times fasters and don’t involve local government.

    Towerstream is granting users four hours use with no charge if the user will interact with a location specific advertisement. These deals may be targeted to within dozens of feet of the user. Since service over Wi-Fi doesn’t count against U.S. mobile data limits, usage is particularly appealing to 18-34 year olds, who may be wallet constrained and open to viewing location-based ads in exchange for streaming video at high speeds.

    Oligopoly! Google’s Android and Apple’s iOS continue to wipe the floor with their competition. Together they controlled 87.9 percent of the U.S. smartphone market in October, according to comScore. Android ended October with 53.6 percent nationwide smartphone share, increasing 1.4 percentage points over July. iOS grew its U.S. market share from 33.4 percent in July to 34.3 percent in October, a 0.9 percent improvement.

    Tweet This. Use of social media and social networking is growing rapidly. Consumers continue to spend more time on social networks than on any other category of site—roughly 30 percent of total time online via mobile, reports Nielsen and NM Incite. Facebook remains the top social network, followed by Twitter and Blogger, but new social media sites continue to emerge.

    Foursquare Wants Money. The tepid, if not poor, performances of social media IPOs has made investors skittish. The fates of Facebook, Zynga and GroupOn stocks have weighed heavily on this category. Foursquare, which pioneered location check-ins and is now succeeding with target location couponing, is having difficulty attracting added investment, reports the Wall Street Journal. Foursquare counts more than 25 million registered users, with only about 8 million accessing the app monthly. Some investors believe the company is moving too slowly to monetize.