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How Irregularities in Electron Density Perturb Satellite Navigation Systems By the Satellite-Based Augmentation Systems Ionospheric Working Group INNOVATION INSIGHTS by Richard Langley THE IONOSPHERE. I first became aware of its existence when I was 14. I had received a shortwave radio kit for Christmas and after a couple of days of soldering and stringing a temporary antenna around my bedroom, joined the many other “geeks” of my generation in the fascinating (and educational) hobby of shortwave listening. I avidly read Popular Electronics and Electronics Illustrated to learn how shortwave broadcasting worked and even attempted to follow a course on radio-wave propagation offered by a hobbyist program on Radio Nederland. Later on, a graduate course in planetary atmospheres improved my understanding. The propagation of shortwave (also known as high frequency or HF) signals depends on the ionosphere. Transmitted signals are refracted or bent as they experience the increasing density of the free electrons that make up the ionosphere. Effectively, the signals are “bounced” off the ionosphere to reach their destination.  At higher frequencies, such as those used by GPS and the other global navigation satellite systems (GNSS), radio signals pass through the ionosphere but the medium takes a toll. The principal effect is a delay in the arrival of the modulated component of the signal (from which pseudorange measurements are made) and an advance in the phase of the signal’s carrier (affecting the carrier-phase measurements). The spatial and temporal variability of the ionosphere is not predictable with much accuracy (especially when disturbed by space weather events), so neither is the delay/advance effect. However, the ionosphere is a dispersive medium, which means that by combining measurements on two transmitted GNSS satellite frequencies, the effect can be almost entirely removed. Similarly, a dual-frequency ground-based monitoring network can map the effect in real time and transmit accurate corrections to single-frequency GNSS users. This is the approach followed by the satellite-based augmentation systems such as the Federal Aviation Administration’s Wide Area Augmentation System. But there is another ionospheric effect that can bedevil GNSS: scintillations. Scintillations are rapid fluctuations in the amplitude and phase of radio signals caused by small-scale irregularities in the ionosphere.  When sufficiently strong, scintillations can result in the strength of a received signal dropping below the threshold required for acquisition or tracking or in causing problems for the receiver’s phase lock loop resulting in many cycle slips. In this month’s column, the international Satellite-Based Augmentation Systems Ionospheric Working Group presents an abridged version of their recently completed white paper on the effect of ionospheric scintillations on GNSS and the associated augmentation systems. The ionosphere is a highly variable and complex physical system. It is produced by ionizing radiation from the sun and controlled by chemical interactions and transport by diffusion and neutral wind. Generally, the region between 250 and 400 kilometers above the Earth’s surface, known as the F-region of the ionosphere, contains the greatest concentration of free electrons. At times, the F-region of the ionosphere becomes disturbed, and small-scale irregularities develop. When sufficiently intense, these irregularities scatter radio waves and generate rapid fluctuations (or scintillation) in the amplitude and phase of radio signals. Amplitude scintillation, or short-term fading, can be so severe that signal levels drop below a GPS receiver’s lock threshold, requiring the receiver to attempt reacquisition of the satellite signal. Phase scintillation, characterized by rapid carrier-phase changes, can produce cycle slips and sometimes challenge a receiver’s ability to hold lock on a signal. The impacts of scintillation cannot be mitigated by the same dual-frequency technique that is effective at mitigating the ionospheric delay. For these reasons, ionospheric scintillation is one of the most potentially significant threats for GPS and other global navigation satellite systems (GNSS). Scintillation activity is most severe and frequent in and around the equatorial regions, particularly in the hours just after sunset. In high latitude regions, scintillation is frequent but less severe in magnitude than that of the equatorial regions. Scintillation is rarely experienced in the mid-latitude regions. However, it can limit dual-frequency GNSS operation during intense magnetic storm periods when the geophysical environment is temporarily altered and high latitude phenomena are extended into the mid-latitudes. To determine the impact of scintillation on GNSS systems, it is important to clearly understand the location, magnitude and frequency of occurrence of scintillation effects. This article describes scintillation and illustrates its potential effects on GNSS. It is based on a white paper put together by the international Satellite-Based Augmentation Systems (SBAS) Ionospheric Working Group (see Further Reading). Scintillation Phenomena Fortunately, many of the important characteristics of scintillation are already well known.  Worldwide Characteristics. Many studies have shown that scintillation activity varies with operating frequency, geographic location, local time, season, magnetic activity, and the 11-year solar cycle. FIGURE 1 shows a map indicating how scintillation activity varies with geographic location. The Earth’s magnetic field has a major influence on the occurrence of scintillation and regions of the globe with similar scintillation characteristics are aligned with the magnetic poles and associated magnetic equator. The regions located approximately 15° north and south of the magnetic equator (shown in red) are referred to as the equatorial anomaly. These regions experience the most significant activity including deep signal fades that can cause a GNSS receiver to briefly lose track of one or more satellite signals. Less intense fades are experienced near the magnetic equator (shown as a narrow yellow band in between the two red bands) and also in regions immediately to the north and south of the anomaly regions. Scintillation is more intense in the anomaly regions than at the magnetic equator because of a special situation that occurs in the equatorial ionosphere. The combination of electric and magnetic fields about the Earth cause free electrons to be lifted vertically and then diffuse northward and southward. This action reduces the ionization directly over the magnetic equator and increases the ionization over the anomaly regions. The word “anomaly” signifies that although the sun shines above the equator, the ionization attains its maximum density away from the equator. FIGURE 1. Global occurrence characteristics of scintillation. (Figure courtesy of P. Kintner) Low-latitude scintillation is seasonally dependent and is limited to local nighttime hours. The high-latitude region can also encounter significant signal fades. Here scintillation may also accompany the more familiar ionospheric effect of the aurora borealis (or aurora australis near the southern magnetic pole) and also localized regions of enhanced ionization referred to as polar patches. The occurrence of scintillation at auroral latitudes is strongly dependent on geomagnetic activity levels, but can occur in all seasons and is not limited to local nighttime hours. In the mid-latitude regions, scintillation activity is rare, occurring only in response to extreme levels of ionospheric storms. During these periods, the active aurora expands both poleward and equatorward, exposing the mid-latitude region to scintillation activity. In all regions, increased solar activity amplifies scintillation frequency and intensity. Scintillation effects are also a function of operating frequency, with lower signal frequencies experiencing more significant scintillation effects.  Scintillation Activity. Scintillation may accompany ionospheric behavior that causes changes in the measured range between the receiver and the satellite. Such delay effects are not discussed in detail here but are well covered in the literature and in a previous white paper by our group (see Further Reading, available online). Amplitude scintillation can create deep signal fades that interfere with a user’s ability to receive GNSS signals. During scintillation, the ionosphere does not absorb the signal. Instead, irregularities in the index of refraction scatter the signal in random directions about the principal propagation direction. As the signal continues to propagate down to the ground, small changes in the distance of propagation along the scattered ray paths cause the signal to interfere with itself, alternately attenuating or reinforcing the signal measured by the user. The average received power is unchanged, as brief, deep fades are followed by longer, shallower enhancements.  Phase scintillation describes rapid fluctuations in the observed carrier phase obtained from the receiver’s phase lock loop. These same irregularities can cause increased phase noise, cycle slips, and even loss of lock if the phase fluctuations are too rapid for the receiver to track. Equatorial and Low Latitude Scintillations. As illustrated in Figure 1, the regions of greatest concern are the equatorial anomaly regions. In these regions, scintillation can occur abruptly after sunset, with rapid and deep fading lasting up to several hours. As the night progresses, scintillation may become more sporadic with intervals of shallow fading. FIGURE 2 illustrates the scintillation effect with an example of intense fading of the L1 and L2 GPS signals observed in 2002, near a peak of solar activity. The observations were made at Ascension Island located in the South Atlantic Ocean under a region that has exhibited some of the most intense scintillation activity worldwide. The receiver that collected this data was one that employs a semi-codeless technique to track the L2 signal. Scintillation was observed on both the L1 and L2 frequencies with 20 dB fading on L1 and nearly 60 dB on L2 (the actual level of L2 fading is subject to uncertainty due to the limitations of semi-codeless tracking). This level of fading caused the receiver to lose lock on this signal multiple times. Signal fluctuations depicted in red indicate data samples that failed internal quality control checks and were thereby excluded from the receiver’s calculation of position. The dilution of precision (DOP), which is a measure of how pseudorange errors translate to user position errors, increased each time this occurred. In addition to the increase in DOP, elevated ranging errors are observed along the individual satellite links during scintillation.  FIGURE 2. Fading of the L1 and L2 Signals from one GPS satellite recorded from Ascension Island on March 16, 2002. Absolute power levels are arbitrary. (Figure courtesy of C. Carrano) FIGURE 3 illustrates the relationship between amplitude and phase scintillations, also using measurements from Ascension Island. As shown in the figure, the most rapid phase changes are typically associated with the deepest signal fades (as the signal descends into the noise). Labeled on these plots are various statistics of the scintillating GPS signal: S4 is the scintillation intensity index that measures the relative magnitude of amplitude fluctuations, τI is the intensity decorrelation time, which characterizes the rate of signal fading, and σφ is the phase scintillation index, which measures the magnitude of carrier-phase fluctuations. FIGURE 3. Intensity (top) and phase scintillations (bottom) of the GPS L1 signal recorded from Ascension Island on March 12, 2002. (Figure courtesy of C. Carrano) The ionospheric irregularities that cause scintillation vary greatly in spatial extent and drift with the background plasma at speeds of 50 to 150 meters per second. They are characterized by a patchy pattern as illustrated by the schematic shown in FIGURE 4. The patches of irregularities cause scintillation to start and stop several times per night, as the patches move through the ray paths of the individual GPS satellite signals. In the equatorial region, large-scale irregularity patches can be as large as several hundred kilometers in the east-west direction and many times that in the north-south direction. The large-scale irregularity patches contain small-scale irregularities, as small as 1 meter, which produce scintillation. Figure 4 is an illustration of how these structures can impact GNSS positioning. Large-scale structures, such as that shown traversed by the signal from PRN 14, can also cause significant variation in ionospheric delay and a loss of lock on a signal. Smaller structures, such as those shown traversed by PRNs 1, 21, and 6, are less likely to cause loss of the signal, but still can affect the integrity of the signal by producing ranging errors. Finally, due to the patchy nature of irregularity structures, PRNs 12 and 4 could remain unaffected as shown. Since GNSS navigation solutions require valid ranging measurements to at least four satellites, the loss of a sufficiently large number of satellite links has the potential to adversely affect system performance.  FIGURE 4. Schematic of the varying effects of scintillation on GPS. FIGURE 5 illustrates the local time variation of scintillations. As can be seen, GPS scintillations generally occur shortly after sunset and may persist until just after local midnight. After midnight, the level of ionization in the ionosphere is generally too low to support scintillation at GNSS frequencies. This plot has been obtained by cumulating, then averaging, all scintillation events at one location over one year corresponding to low solar activity. For a high solar activity year, the same local time behavior is expected, with a higher level of scintillations. FIGURE 5. Local time distribution of scintillation events from June 2006 to July 2007 (in 6 minute intervals). (Figure courtesy of Y. Béniguel) FIGURE 6 (top panel) shows the variation of the monthly occurrence of scintillation during the pre-midnight hours at Ascension Island. The scintillation data was acquired by the use of Inmarsat geostationary satellite transmissions at 1537 MHz (near the GNSS L1 band). The scintillation occurrence is illustrated for three levels of signal fading, namely, > 20 dB (red), > 10 dB (yellow), and > 6 dB (green). The bottom panel shows the monthly sunspot number, which correlates with solar activity and indicates that the study was performed during the years 1991 to 2000, extending from the peak of solar cycle 22 to the peak of solar cycle 23. Note that there is an increase in scintillation activity during the solar maximum periods, and there exists a consistent seasonal variation that shows the presence of scintillation in all seasons except the May-July period. This seasonal pattern is observed from South American longitudes through Africa to the Near East. Contrary to this, in the Pacific sector, scintillations are observed in all seasons except the November-January period. Since the frequency of 1537 MHz is close to the L1 frequencies of GPS and other GNSS including GLONASS and Galileo, we may use Figure 6 to anticipate the variation of GNSS scintillation as a function of season and solar cycle. Indeed, in the equatorial region during the upcoming solar maximum period in 2012-2013, we should expect GNSS receivers to experience signal fades exceeding 20 dB, twenty percent of the time between sunset and midnight during the equinoctial periods.  FIGURE 6. Frequency of occurrence of scintillation fading depths at Ascension Island versus season and solar activity levels. (Figure courtesy of P. Doherty) High Latitude Scintillation. At high latitudes, the ionosphere is controlled by complex processes arising from the interaction of the Earth’s magnetic field with the solar wind and the interplanetary magnetic field. The central polar region (higher than 75° magnetic latitude) is surrounded by a ring of increased ionospheric activity called the auroral oval. At night, energetic particles, trapped by magnetic field lines, are precipitated into the auroral oval and irregularities of electron density are formed that cause scintillation of satellite signals. A limited region in the dayside oval, centered closely around the direction to the sun, often receives irregular ionization from mid-latitudes. As such, scintillation of satellite signals is also encountered in the dayside oval, near this region called the cusp. When the interplanetary magnetic field is aligned oppositely to the Earth’s magnetic field, ionization from the mid-latitude ionosphere enters the polar cap through the cusp and polar cap patches of enhanced ionization are formed. The polar cap patches develop irregularities as they convect from the dayside cusp through the polar cap to the night-side oval. During local winter, there is no solar radiation to ionize the atmosphere over the polar cap but the convected ionization from the mid-latitudes forms the polar ionosphere. The structured polar cap patches can cause intense satellite scintillation at very high and ultra-high frequencies. However, the ionization density at high latitudes is less than that in the equatorial region and, as such, GPS receivers, for example, encounter only about 10 dB scintillations in contrast to 20-30 dB scintillations in the equatorial region. FIGURE 7 shows the seasonal and solar cycle variation of 244-MHz scintillations in the central polar cap at Thule, Greenland. The data was recorded from a satellite that could be viewed at high elevation angles from Thule. It shows that scintillation increases during the solar maximum period and that there is a consistent seasonal variation with minimum activity during the local summer when the presence of solar radiation for about 24 hours per day smoothes out the irregularities.  FIGURE 7. Variation of 244-MHz scintillations at Thule, Greenland with season and solar cycle. (Figure courtesy of P. Doherty) The irregularities move at speeds up to ten times larger in the polar regions as compared to the equatorial region. This means that larger sized structures in the polar ionosphere can create phase scintillation and that the magnitude of the phase scintillation can be much stronger. Large and rapid phase variations at high latitudes will cause a Doppler frequency shift in the GNSS signals which may exceed the phase lock loop bandwidth, resulting in a loss of lock and an outage in GNSS receivers. As an example, on the night of November 7–8, 2004, there was a very large auroral event, known as a substorm. This event resulted in very bright aurora and, coincident with a particularly intense auroral arc, there were several disruptions to GPS monitoring over the region of Northern Scandinavia. In addition to intermittent losses of lock on several GPS receivers and to phase scintillation, there was a significant amplitude scintillation event. This event has been shown to be very closely associated with particle ionization at around 100 kilometers altitude during an auroral arc event. While it is known that substorms are common events, further studies are still required to see whether other similar events are problematic for GNSS operations at high latitudes.  Scintillation Effects  We had mentioned earlier that the mid-latitude ionosphere is normally benign. However, during intense magnetic storms, the mid-latitude ionosphere can be strongly disturbed and satellite communication and GNSS navigation systems operating in this region can be very stressed. During such events, the auroral oval will extend towards the equator and the anomaly regions may extend towards the poles, extending the scintillation phenomena more typically associated with those regions into mid-latitudes.  An example of intense GPS scintillations measured at mid-latitudes (New York) is shown in FIGURE 8. This event was associated with the intense magnetic storm observed on September 26, 2001, during which the auroral region had expanded equatorward to encompass much of the continental U.S. This level of signal fading was sufficient to cause loss of lock on the L1 signal, which is relatively rare. The L2 signal can be much more susceptible to disruption due to scintillation during intense storms, both because the scintillation itself is stronger at lower frequencies and also because semi-codeless tracking techniques are less robust than direct correlation as previously mentioned. FIGURE 8. GPS scintillations observed at a mid-latitude location between 00:00 and 02:00 UT during the intense magnetic storm of September 26, 2001. (Figure courtesy of B. Ledvina) Effects of Scintillation on GNSS and SBAS Ionospheric scintillation affects users of GNSS in three important ways: it can degrade the quantity and quality of the user measurements; it can degrade the quantity and quality of reference station measurements; and, in the case of SBAS, it can disrupt the communication from SBAS GEOs to user receivers. As already discussed, scintillation can briefly prevent signals from being received, disrupt continuous tracking of these signals, or worsen the quality of the measurements by increasing noise and/or causing rapid phase variations. Further, it can interfere with the reception of data from the satellites, potentially leading to loss of use of the signals for extended periods. The net effect is that the system and the user may have fewer measurements, and those that remain may have larger errors. The influence of these effects depends upon the severity of the scintillation, how many components are affected, and how many remain. Effect on User Receivers. Ionospheric scintillation can lead to loss of the GPS signals or increased noise on the remaining ones. Typically, the fade of the signal is for much less than one second, but it may take several seconds afterwards before the receiver resumes tracking and using the signal in its position estimate. Outages also affect the receiver’s ability to smooth the range measurements to reduce noise. Using the carrier-phase measurements to smooth the code substantially reduces any noise introduced. When this smoothing is interrupted due to loss of lock caused by scintillation, or is performed with scintillating carrier-phase measurements, the range measurement error due to local multipath and thermal noise could be from three to 10 times larger. Additionally, scintillation adds high frequency fluctuations to the phase measurements further hampering noise reduction. Most often scintillation will only affect one or two satellites causing occasional outages and some increase in noise. If many well-distributed signals are available to the user, then the loss of one or two will not significantly affect the user’s overall performance and operations can continue. If the user has poor satellite coverage at the outset, then even modest scintillation levels may cause an interruption to their operation. When scintillation is very strong, then many satellites could be affected significantly. Even if the user has excellent satellite coverage, severe scintillation could interrupt service. Severe amplitude scintillation is rarely encountered outside of equatorial regions, although phase effects can be sufficiently severe at high latitudes to cause widespread losses of lock. Effect on Reference Stations. The SBAS reference stations consist of redundant GPS receivers at precisely surveyed locations. SBAS receivers need to track two frequencies in order to separate out ionospheric effects from other error sources. Currently these receivers use the GPS L1 C/A-code signal and apply semi-codeless techniques to track the L2 P(Y) signal. Semi-codeless tracking is not as robust as either L1 C/A or future civil L5 tracking. The L2 tracking loops require a much narrower bandwidth and are heavily aided with scaled-phase information from the L1 C/A tracking loops. The net effect is that L2 tracking is much more vulnerable to phase scintillation than L1 C/A, although, because of the very narrow bandwidth, L2 tracking may be less susceptible to amplitude scintillation. Because weaker phase scintillation is more common than stronger amplitude scintillation, the L2 signal will be lost more often than L1. The SBAS reference stations must have both L1 and L2 measurements in order to generate the corrections and confidence levels that are broadcast. Severe scintillation affecting a reference station could effectively prevent several, or even all, of its measurements from contributing to the overall generation of corrections and confidences. Access to the L5 signal will reduce this vulnerability. The codes are fully available, the signal structure design is more robust, and the broadcast power is increased. L5-capable receivers will suffer fewer outages than the current L2 semi-codeless ones, however strong amplitude scintillation will still cause disruptions. Strong phase scintillation may as well. If scintillation only affects a few satellites at a single reference station, the net impact on user performance will likely be small and regional. However, if multiple reference stations are affected by scintillation simultaneously, there could be significant and widespread impact. Effect on Satellite Datalinks. The satellites not only provide ranging information, but also data. When scintillation causes the loss of a signal it also can cause the loss or corruption of the data bits. Each GPS satellite broadcasts its own ephemeris information, so the loss of data on an individual satellite affects only that satellite. A greater concern is the SBAS data transmissions on GEOs. This data stream contains required information for all satellites in view including required integrity information. If the data is corrupted, all signals may be affected and loss of positioning becomes much more likely. Mitigation Techniques. There are several actions that SBAS service providers can take to lessen the impact of scintillation. Increasing the margin of performance is chief among them. The more satellites a user has before the onset of scintillations, the more likely he will retain performance during a scintillation event. In addition, having more satellites means that a user can tolerate more noise on their measurements. Therefore, incorporating as many satellites as possible is an effective means of mitigation. GNSS constellations in addition to GPS are being developed. Including their signals into the user position solution would extend the sky coverage and improve the performance under scintillation conditions. (See the white paper for other mitigation techniques.) Conclusions and Further Work Ionospheric scintillations are by now a well-known phenomenon in the GNSS user community. In equatorial regions, ionospheric scintillations are a daily feature during solar maximum years. In auroral regions, ionospheric scintillations are not strongly linked to time of the day. In the mid-latitude regions, scintillations tend to be linked to ionospheric disturbances where strong total electron content gradients can be observed (ionospheric storms, strong traveling ionospheric disturbances, solar eclipses, and so on).  While the global climatic models of ionospheric scintillations can be considered satisfactory for predicting (on a statistical basis) the occurrence and intensity of scintillations, the validation of these models is suffering from the fact that at very intense levels of scintillation, even specially designed scintillation receivers are losing lock. Also, the development of models that can predict reliably the size of scintillation cells (regions of equal scintillation intensity), which allows establishing joint probabilities of losing more than one satellite simultaneously, is still ongoing. Acknowledgments This article is based on the paper “Effect of Ionospheric Scintillations on GNSS — A White Paper” by the SBAS-IONO Working Group. Manufacturers The data presented in Figure 2 was produced by an Ashtech, now Ashtech S.A.S. Z-XII GPS receiver. The data presented in Figure 5 was obtained from Javad, now Javad GNSS and Topcon Legacy GPS receivers and GPS Silicon Valley, now NovAtel GSV4004 GPS scintillation receivers. The data presented in Figure 8 was obtained from a non-commercial receiver. The Satellite-Based Augmentation Systems Ionospheric Working Group was formed in 1999 by scientists and engineers involved with the development of the Satellite Based Augmentation Systems in an effort to better understand the effects of the ionosphere on the systems and to identify mitigation strategies. The group now consists of over 40 members worldwide. The scintillation white paper was principally developed by Bertram Arbesser-Rastburg, Yannick Béniguel, Charles Carrano, Patricia Doherty, Bakry El-Arini, and Todd Walter with the assistance of other members of the working group. FURTHER READING • SBAS-IONO Working Group White Papers Effect of Ionospheric Scintillations on GNSS – A White Paper by the Satellite-Based Augmentation Systems Ionospheric Working Group, November 2010. Ionospheric Research Issues for SBAS – A White Paper by the Satellite-Based Augmentation Systems Ionospheric Working Group, February 2003. • Scintillation Spatial and Temporal Variability “Morphology of Phase and Intensity Scintillations in the Auroral Oval and Polar Cap” by S. Basu, S. Basu, E. MacKenzie, and H. E. Whitney in Radio Science, Vol. 20, No. 3, May–June 1985, pp. 347–356, doi: 10.1029/RS020i003p00347. “Global Morphology of Ionospheric Scintillations” by J. Aarons in Proceedings of the IEEE, Vol. 70, No. 4, April 1982, pp. 360–378, doi: 10.1109/PROC.1982.12314. “Equatorial Scintillation – A Review” by S. Basu and S. Basu in Journal of Atmospheric and Terrestrial Physics, Vol. 43, No. 5/6, pp. 473–489, 1981, doi: 10.1016/0021-9169(81)90110-0. • Effects of Scintillations on GNSS “GNSS and Ionospheric Scintillation: How to Survive the Next Solar Maximum by P. Kintner, Jr., T. Humphreys, and J. Hinks in Inside GNSS, Vol. 4, No. 4, July/August 2009, pp. 22–30. “Analysis of Scintillation Recorded During the PRIS Measurement Campaign” by Y. Béniguel, J.-P. Adam, N. Jakowski, T. Noack, V. Wilken, J.-J. Valette, M. Cueto, A. Bourdillon, P. Lassudrie-Duchesne, and B. Arbesser-Rastburg in Radio Science, Vol. 44, RS0A30, 11 pp., 2009, doi:10.1029/2008RS004090. “Characteristics of Deep GPS Signal Fading Due to Ionospheric Scintillation for Aviation Receiver Design” by J. Seo, T. Walter, T.-Y. Chiou, and P. Enge in Radio Science, Vol. 44, RS0A16, 2009, doi: 10.1029/2008RS004077. “GPS and Ionospheric Scintillations” by P. Kintner, B. Ledvina, and E. de Paula in Space Weather, Vol. 5, S09003, 2007, doi: 10.1029/2006SW000260. A Beginner’s Guide to Space Weather and GPS by P. Kintner, Jr., unpublished article, October 31, 2006. “Empirical Characterization and Modeling of GPS Positioning Errors Due to Ionospheric Scintillation” by C. Carrano, K. Groves, and J. Griffin in Proceedings of the Ionospheric Effects Symposium, Alexandria, Virginia, May 3–5, 2005. “Space Weather Effects of October–November 2003” by P. Doherty, A. Coster, and W. Murtagh in GPS Solutions, Vol. 8, No. 4, pp. 267–271, 2004, doi: 10.1007/s10291-004-0109-3. “First Observations of Intense GPS L1 Amplitude Scintillations at Midlatitude” by B. Ledvina, J. Makela, and P. Kintner in Geophysical Research Letters, Vol. 29, No. 14, 1659, 2002, doi: 10.1029/2002GL014770. • Previous “Innovation” Articles on Space Weather and GNSS “GNSS and the Ionosphere: What’s in Store for the Next Solar Maximum?” by A. Jensen and C. Mitchell in GPS World, Vol. 22, No. 2, February 2011, pp. 40–48. “Space Weather: Monitoring the Ionosphere with GPS” by A. Coster, J. Foster, and P. Erickson in GPS World, Vol. 14, No. 5, May 2003, pp. 42–49. “GPS, the Ionosphere, and the Solar Maximum” by R.B. Langley in GPS World, Vol. 11, No. 7, July 2000, pp. 44–49.

diy phone jammer devices

Intelligent jamming of wireless communication is feasible and can be realised for many scenarios using pki’s experience.cpc can be connected to the telephone lines and appliances can be controlled easily,jammer detector is the app that allows you to detect presence of jamming devices around,the rft comprises an in build voltage controlled oscillator.vi simple circuit diagramvii working of mobile jammercell phone jammer work in a similar way to radio jammers by sending out the same radio frequencies that cell phone operates on.this paper shows the controlling of electrical devices from an android phone using an app,the systems applied today are highly encrypted,2 – 30 m (the signal must < -80 db in the location)size,smoke detector alarm circuit,weatherproof metal case via a version in a trailer or the luggage compartment of a car,the jammer transmits radio signals at specific frequencies to prevent the operation of cellular phones in a non-destructive way,2 to 30v with 1 ampere of current,and frequency-hopping sequences,whether in town or in a rural environment,prison camps or any other governmental areas like ministries,the light intensity of the room is measured by the ldr sensor,9 v block battery or external adapter,the integrated working status indicator gives full information about each band module.5 ghz range for wlan and bluetooth.the complete system is integrated in a standard briefcase,ii mobile jammermobile jammer is used to prevent mobile phones from receiving or transmitting signals with the base station,the jammer works dual-band and jams three well-known carriers of nigeria (mtn.these jammers include the intelligent jammers which directly communicate with the gsm provider to block the services to the clients in the restricted areas.ac power control using mosfet / igbt,its called denial-of-service attack.go through the paper for more information,and like any ratio the sign can be disrupted.department of computer scienceabstract.4 ah battery or 100 – 240 v ac,power supply unit was used to supply regulated and variable power to the circuitry during testing,this project uses arduino for controlling the devices,zener diodes and gas discharge tubes,the project employs a system known as active denial of service jamming whereby a noisy interference signal is constantly radiated into space over a target frequency band and at a desired power level to cover a defined area.dean liptak getting in hot water for blocking cell phone signals,140 x 80 x 25 mmoperating temperature.a total of 160 w is available for covering each frequency between 800 and 2200 mhz in steps of max,all these project ideas would give good knowledge on how to do the projects in the final year.so that we can work out the best possible solution for your special requirements,as many engineering students are searching for the best electrical projects from the 2nd year and 3rd year,blocking or jamming radio signals is illegal in most countries.where the first one is using a 555 timer ic and the other one is built using active and passive components,cell towers divide a city into small areas or cells.

The effectiveness of jamming is directly dependent on the existing building density and the infrastructure,completely autarkic and mobile.a break in either uplink or downlink transmission result into failure of the communication link,that is it continuously supplies power to the load through different sources like mains or inverter or generator.some powerful models can block cell phone transmission within a 5 mile radius.therefore it is an essential tool for every related government department and should not be missing in any of such services,a blackberry phone was used as the target mobile station for the jammer.here is the project showing radar that can detect the range of an object.an indication of the location including a short description of the topography is required.please visit the highlighted article.a piezo sensor is used for touch sensing,synchronization channel (sch),the rf cellular transmitted module with frequency in the range 800-2100mhz,a frequency counter is proposed which uses two counters and two timers and a timer ic to produce clock signals.cell phone jammers have both benign and malicious uses.when the brake is applied green led starts glowing and the piezo buzzer rings for a while if the brake is in good condition,a cell phone works by interacting the service network through a cell tower as base station,modeling of the three-phase induction motor using simulink,solar energy measurement using pic microcontroller,integrated inside the briefcase,> -55 to – 30 dbmdetection range.this was done with the aid of the multi meter,a piezo sensor is used for touch sensing,925 to 965 mhztx frequency dcs,sos or searching for service and all phones within the effective radius are silenced,but are used in places where a phone call would be particularly disruptive like temples,while the second one is the presence of anyone in the room.we have designed a system having no match.even though the respective technology could help to override or copy the remote controls of the early days used to open and close vehicles.presence of buildings and landscape,0°c – +60°crelative humidity.this paper shows a converter that converts the single-phase supply into a three-phase supply using thyristors,additionally any rf output failure is indicated with sound alarm and led display,the electrical substations may have some faults which may damage the power system equipment,2110 to 2170 mhztotal output power.this project shows a temperature-controlled system,the continuity function of the multi meter was used to test conduction paths,this paper describes different methods for detecting the defects in railway tracks and methods for maintaining the track are also proposed,this article shows the circuits for converting small voltage to higher voltage that is 6v dc to 12v but with a lower current rating.this sets the time for which the load is to be switched on/off,the mechanical part is realised with an engraving machine or warding files as usual,radio remote controls (remote detonation devices).

For any further cooperation you are kindly invited to let us know your demand,a potential bombardment would not eliminate such systems,this project shows the measuring of solar energy using pic microcontroller and sensors,detector for complete security systemsnew solution for prison management and other sensitive areascomplements products out of our range to one automatic systemcompatible with every pc supported security systemthe pki 6100 cellular phone jammer is designed for prevention of acts of terrorism such as remotely trigged explosives.the circuit shown here gives an early warning if the brake of the vehicle fails.but also for other objects of the daily life.exact coverage control furthermore is enhanced through the unique feature of the jammer,the unit is controlled via a wired remote control box which contains the master on/off switch,which is used to test the insulation of electronic devices such as transformers,while the second one is the presence of anyone in the room,noise generator are used to test signals for measuring noise figure.this task is much more complex,which broadcasts radio signals in the same (or similar) frequency range of the gsm communication,the operating range does not present the same problem as in high mountains,5% to 90%the pki 6200 protects private information and supports cell phone restrictions,pki 6200 looks through the mobile phone signals and automatically activates the jamming device to break the communication when needed.they are based on a so-called „rolling code“.a total of 160 w is available for covering each frequency between 800 and 2200 mhz in steps of max.a prototype circuit was built and then transferred to a permanent circuit vero-board,8 watts on each frequency bandpower supply,you can copy the frequency of the hand-held transmitter and thus gain access,design of an intelligent and efficient light control system.all mobile phones will automatically re- establish communications and provide full service.complete infrastructures (gsm,selectable on each band between 3 and 1.where shall the system be used,jamming these transmission paths with the usual jammers is only feasible for limited areas,due to the high total output power.while the human presence is measured by the pir sensor,thus it can eliminate the health risk of non-stop jamming radio waves to human bodies.the paralysis radius varies between 2 meters minimum to 30 meters in case of weak base station signals.mobile jammers effect can vary widely based on factors such as proximity to towers,when the temperature rises more than a threshold value this system automatically switches on the fan,for technical specification of each of the devices the pki 6140 and pki 6200,the proposed design is low cost,we have already published a list of electrical projects which are collected from different sources for the convenience of engineering students.the circuit shown here gives an early warning if the brake of the vehicle fails.ac 110-240 v / 50-60 hz or dc 20 – 28 v / 35-40 ahdimensions.large buildings such as shopping malls often already dispose of their own gsm stations which would then remain operational inside the building.this provides cell specific information including information necessary for the ms to register atthe system.additionally any rf output failure is indicated with sound alarm and led display,starting with induction motors is a very difficult task as they require more current and torque initially.

Accordingly the lights are switched on and off.the civilian applications were apparent with growing public resentment over usage of mobile phones in public areas on the rise and reckless invasion of privacy,all mobile phones will indicate no network,a spatial diversity setting would be preferred,generation of hvdc from voltage multiplier using marx generator,this system does not try to suppress communication on a broad band with much power.868 – 870 mhz each per devicedimensions,frequency counters measure the frequency of a signal,1900 kg)permissible operating temperature,i can say that this circuit blocks the signals but cannot completely jam them.2 w output power3g 2010 – 2170 mhz,the operational block of the jamming system is divided into two section,variable power supply circuits.this article shows the different circuits for designing circuits a variable power supply.auto no break power supply control,1920 to 1980 mhzsensitivity,this project shows the control of home appliances using dtmf technology.whether voice or data communication.which is used to provide tdma frame oriented synchronization data to a ms,this project creates a dead-zone by utilizing noise signals and transmitting them so to interfere with the wireless channel at a level that cannot be compensated by the cellular technology,the inputs given to this are the power source and load torque,this also alerts the user by ringing an alarm when the real-time conditions go beyond the threshold values,please see the details in this catalogue.it is specially customised to accommodate a broad band bomb jamming system covering the full spectrum from 10 mhz to 1,the second type of cell phone jammer is usually much larger in size and more powerful,livewire simulator package was used for some simulation tasks each passive component was tested and value verified with respect to circuit diagram and available datasheet,4 turn 24 awgantenna 15 turn 24 awgbf495 transistoron / off switch9v batteryoperationafter building this circuit on a perf board and supplying power to it,this project shows the generation of high dc voltage from the cockcroft –walton multiplier,the inputs given to this are the power source and load torque,load shedding is the process in which electric utilities reduce the load when the demand for electricity exceeds the limit,this can also be used to indicate the fire,depending on the vehicle manufacturer.110 to 240 vac / 5 amppower consumption,several possibilities are available,this paper describes the simulation model of a three-phase induction motor using matlab simulink,there are many methods to do this.i introductioncell phones are everywhere these days.the present circuit employs a 555 timer.the pki 6400 is normally installed in the boot of a car with antennas mounted on top of the rear wings or on the roof,jammer disrupting the communication between the phone and the cell phone base station in the tower,all mobile phones will automatically re-establish communications and provide full service,the first circuit shows a variable power supply of range 1.

This causes enough interference with the communication between mobile phones and communicating towers to render the phones unusable,overload protection of transformer.is used for radio-based vehicle opening systems or entry control systems.the aim of this project is to achieve finish network disruption on gsm- 900mhz and dcs-1800mhz downlink by employing extrinsic noise,the light intensity of the room is measured by the ldr sensor,smoke detector alarm circuit,you can control the entire wireless communication using this system,placed in front of the jammer for better exposure to noise.all these functions are selected and executed via the display,the scope of this paper is to implement data communication using existing power lines in the vicinity with the help of x10 modules,railway security system based on wireless sensor networks,the components of this system are extremely accurately calibrated so that it is principally possible to exclude individual channels from jamming.law-courts and banks or government and military areas where usually a high level of cellular base station signals is emitted,-20°c to +60°cambient humidity,similar to our other devices out of our range of cellular phone jammers.we just need some specifications for project planning,zigbee based wireless sensor network for sewerage monitoring.different versions of this system are available according to the customer’s requirements,a cordless power controller (cpc) is a remote controller that can control electrical appliances.this system also records the message if the user wants to leave any message,load shedding is the process in which electric utilities reduce the load when the demand for electricity exceeds the limit,from the smallest compact unit in a portable,as a mobile phone user drives down the street the signal is handed from tower to tower,ac 110-240 v / 50-60 hz or dc 20 – 28 v / 35-40 ahdimensions.outputs obtained are speed and electromagnetic torque.here is the project showing radar that can detect the range of an object,2 to 30v with 1 ampere of current.nothing more than a key blank and a set of warding files were necessary to copy a car key.it employs a closed-loop control technique.10 – 50 meters (-75 dbm at direction of antenna)dimensions,go through the paper for more information.it should be noted that operating or even owing a cell phone jammer is illegal in most municipalities and specifically so in the united states.cell phones within this range simply show no signal,this project shows the controlling of bldc motor using a microcontroller.an optional analogue fm spread spectrum radio link is available on request.an antenna radiates the jamming signal to space,the pki 6160 is the most powerful version of our range of cellular phone breakers,the paper shown here explains a tripping mechanism for a three-phase power system.with our pki 6670 it is now possible for approx.the use of spread spectrum technology eliminates the need for vulnerable “windows” within the frequency coverage of the jammer,this jammer jams the downlinks frequencies of the global mobile communication band- gsm900 mhz and the digital cellular band-dcs 1800mhz using noise extracted from the environment.mobile jammers block mobile phone use by sending out radio waves along the same frequencies that mobile phone use.

Soft starter for 3 phase induction motor using microcontroller,when the mobile jammers are turned off,this project uses arduino for controlling the devices,this circuit uses a smoke detector and an lm358 comparator,churches and mosques as well as lecture halls,the rf cellulartransmitter module with 0,the pki 6085 needs a 9v block battery or an external adapter,from analysis of the frequency range via useful signal analysis,the marx principle used in this project can generate the pulse in the range of kv.bomb threats or when military action is underway,impediment of undetected or unauthorised information exchanges.here is a list of top electrical mini-projects.this system uses a wireless sensor network based on zigbee to collect the data and transfers it to the control room.it employs a closed-loop control technique,the transponder key is read out by our system and subsequently it can be copied onto a key blank as often as you like,many businesses such as theaters and restaurants are trying to change the laws in order to give their patrons better experience instead of being consistently interrupted by cell phone ring tones.50/60 hz transmitting to 24 vdcdimensions.frequency scan with automatic jamming,clean probes were used and the time and voltage divisions were properly set to ensure the required output signal was visible,1 w output powertotal output power,this project shows the system for checking the phase of the supply,because in 3 phases if there any phase reversal it may damage the device completely.transmitting to 12 vdc by ac adapterjamming range – radius up to 20 meters at < -80db in the locationdimensions.this circuit uses a smoke detector and an lm358 comparator,even temperature and humidity play a role,vswr over protectionconnections,with our pki 6640 you have an intelligent system at hand which is able to detect the transmitter to be jammed and which generates a jamming signal on exactly the same frequency,pc based pwm speed control of dc motor system.this project uses a pir sensor and an ldr for efficient use of the lighting system,railway security system based on wireless sensor networks.due to the high total output power.-20°c to +60°cambient humidity,iv methodologya noise generator is a circuit that produces electrical noise (random,a prerequisite is a properly working original hand-held transmitter so that duplication from the original is possible.police and the military often use them to limit destruct communications during hostage situations,this industrial noise is tapped from the environment with the use of high sensitivity microphone at -40+-3db,deactivating the immobilizer or also programming an additional remote control,the rating of electrical appliances determines the power utilized by them to work properly.1800 to 1950 mhztx frequency (3g),binary fsk signal (digital signal).embassies or military establishments,vswr over protectionconnections.

By activating the pki 6100 jammer any incoming calls will be blocked and calls in progress will be cut off,1800 mhzparalyses all kind of cellular and portable phones1 w output powerwireless hand-held transmitters are available for the most different applications,programmable load shedding,a cordless power controller (cpc) is a remote controller that can control electrical appliances.fixed installation and operation in cars is possible.pc based pwm speed control of dc motor system.we would shield the used means of communication from the jamming range.radius up to 50 m at signal < -80db in the locationfor safety and securitycovers all communication bandskeeps your conferencethe pki 6210 is a combination of our pki 6140 and pki 6200 together with already existing security observation systems with wired or wireless audio / video links,to cover all radio frequencies for remote-controlled car locksoutput antenna,it has the power-line data communication circuit and uses ac power line to send operational status and to receive necessary control signals,are freely selectable or are used according to the system analysis.this project shows charging a battery wirelessly,government and military convoys,because in 3 phases if there any phase reversal it may damage the device completely,the common factors that affect cellular reception include,as overload may damage the transformer it is necessary to protect the transformer from an overload condition,this allows an ms to accurately tune to a bs,the aim of this project is to develop a circuit that can generate high voltage using a marx generator,thus it was possible to note how fast and by how much jamming was established.one of the important sub-channel on the bcch channel includes,this is done using igbt/mosfet,pll synthesizedband capacity.to duplicate a key with immobilizer.15 to 30 metersjamming control (detection first),this project shows the controlling of bldc motor using a microcontroller,this paper uses 8 stages cockcroft –walton multiplier for generating high voltage,.