• Cell phone jammers for sale 0-50m ebay,cell phone jammer wholesale,Signal Characteristics of Civil GPS Jammers By Ryan H. Mitch, Ryan C. Dougherty, Mark L. Psiaki, Steven P. Powell, Brady W. O’Hanlon, Jahshan A. Bhatti, and Todd E. Humphreys GPS jamming is a...

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Signal Characteristics of Civil GPS Jammers By Ryan H. Mitch, Ryan C. Dougherty, Mark L. Psiaki, Steven P. Powell, Brady W. O’Hanlon, Jahshan A. Bhatti, and Todd E. Humphreys GPS jamming is a continuing threat. A detailed understanding of how the available jammers work is necessary to judge their effectiveness and limitations. A team of researchers from Cornell University and the University of Texas at Austin reports on their analyses of the signal properties of 18 commercially available GPS jammers. INNOVATION INSIGHTS by Richard Langley GPS IS AT WAR. It is a major asset for United States and allied military forces in a number of operating theaters around the world in both declared and undeclared conflicts. But GPS is at war on the domestic front, too — at war against a proliferation of jamming equipment being marketed to cause deliberate interference to GPS signals to prevent GPS receivers from computing positions to be locally stored or relayed via tracking networks. There have been many notable examples of deliberate jamming of GPS receivers. Many more likely go undetected each day. In 2009, outages of a Federal Aviation Administration reference receiver at Newark Liberty International Airport close to the New Jersey Turnpike were traced to a $33, 200 milliwatt GPS jammer in a truck that passed the airport each day. The driver was reportedly arrested and charged. In July 2010, two truck thieves in Britain were jailed for 16 years. They used GPS jammers to prevent the trucks from being tracked after the thefts. And in Germany, some truck drivers have been using jammers to evade the country’s GPS-based road-toll system. The U.S. and some foreign governments have enacted laws to prohibit the importation, marketing, sale or operation of these so-called personal privacy devices. Nevertheless, a certain number of jammers are in the hands of individuals around the world and they continue to be available from manufacturers and suppliers in certain countries. So, GPS jamming is a continuing threat both at home and abroad and a detailed understanding of how the available jammers work is necessary to judge their effectiveness and limitations. This information will also help in developing countermeasures that could be incorporated into GPS receivers to limit the impact of jammers. Jammers constitute an enemy force, and as the Chinese General Sun Tzu stated in the Art of War more than 2,000 years ago, battles will be won by knowing your enemy. In the last verse of Chapter Three, he states: So it is said that if you know your enemies and know yourself, you can win a hundred battles without a single loss. If you only know yourself, but not your opponent, you may win or may lose. If you know neither yourself nor your enemy, you will always endanger yourself. In this month’s column, a team of researchers from Cornell University and the University of Texas at Austin reports on their analyses of the signal properties of 18 commercially available GPS jammers. The enemy has been exposed. The Global Positioning System has become increasingly incorporated into civilian infrastructure. The increase in GPS-integrated systems has caused a proportional increase in the vulnerability of these systems to jamming and interference. The interests of individuals or groups willing to break the law may be served by interfering with the normal operation of GPS-enabled systems. As a result, in recent years many GPS jamming devices have become available for purchase over the Internet. These relatively cheap devices, some costing less than an inexpensive GPS receiver, pose a significant risk to the normal operation of many systems reliant on GPS. Many types of intentional radio frequency (RF) interference exist, including tones, swept waveforms, pulses, narrowband noise, and broadband noise. There are a number of methods for mitigating the effects of jamming and interference, and additional methods exist to locate the sources of the interference. Mitigation and location methods can be improved by use of a priori information about the interference source. This article provides such a priori information for a set of jammers and assesses their threats. Its results are based on two tests. The first test records raw RF data from a selection of jammers and analyzes it using fast Fourier transform (FFT) spectral methods. The second test evaluates the effective range of a subset of the GPS jammers using a commercial off-the-shelf (COTS) receiver. The article presents results based on 18 civil GPS jammers. There are other types of GPS jammers for sale that were not tested. Furthermore, civil jammer behavior and design is likely to evolve over time. In this article, we draw conclusions based on only the jammers that we tested. Overview of Civil GPS Jammers Devices that claim to jam or “block” GPS signals are widely available through a number of websites and online entities. The cost of these devices ranges from a few tens of dollars to several hundred. Their price does not seem to correlate with the claims made by the purveyors of these devices regarding the features and effectiveness of the product in question. Effective ranges from a few meters to several tens of meters are advertised, but the actual effective ranges are significantly greater. Claimed and true power consumptions range from a fraction of a watt to several watts. We grouped the GPS jammers we examined in this article into three categories based on morphology. The first is a group of jammers designed to plug into an automotive 12-volt auxiliary power supply outlet (cigarette lighter socket); this class of jammer is referred to in the remainder of this article as Group 1. The second category contains those jammers that are both powered by an internal rechargeable battery and that have an external antenna connected via an SMA connector; these jammers are referred to as Group 2. The jammers in Group 3 are disguised as cell phones; they have batteries but no external antennas. Figure 1 shows an example of a device from each of Groups 1–3. Figure 1. Three jammers are depicted, from left to right Jammers 1, 5, and 15 from Groups 1, 2, and 3, respectively. All 18 jammers broadcast power at or near the L1 carrier frequency, six broadcast power at or near the L2 carrier frequency, and none broadcast power at or near the L5 carrier frequency. Some of the jammers also broadcast power at frequencies outside of the GPS bands, typically cellular phone or Wi-Fi bands, but those frequencies are outside the scope of this article. Results in this article are for the current power levels broadcast in the GPS L1 and L2 bands, but examination of power levels in non-GPS bands indicate that many of these devices could be easily modified to broadcast much more power in the GPS bands. The jammer antennas have been removed in most of the testing for this article, but their use in a real-world scenario will modify the jammer behavior. The antennas used by Group 1 and Group 2 jammers are loaded monopole antennas, while those used by the Group 3 jammers are electrically short helical antennas that have approximately the same gain pattern as the loaded monopoles. These antennas broadcast linearly polarized radiation, as opposed to the right-hand circular polarization of GPS signals. The polarization mismatch will cause some loss in received power at a right-hand circularly polarized GPS receiver antenna. Jammer Signal Characteristics Test The goal of the first set of tests was to record complex samples of the jamming signals and to derive the jammer characteristics from these data. A two-step procedure was used to collect useful data. The first step used a spectrum analyzer to find the frequency range of the jamming signal near L1 and L2. The second step used this frequency information to set the center frequency of a general-purpose RF digitization and signal storage device with a 12-drive RAID storage array. Offline analyses were then conducted on the recorded data. The test procedure was as follows. For the first two groups, the jammer was placed inside an RF-shielded test enclosure shown in Figure 2, to prevent any signal leakage, and its SMA signal output port was connected to the relevant data collection device using a shielded coaxial cable. The signal had to pass from the inside to the outside of the RF enclosure using the built-in coaxial feed-through. Note, therefore, that no jammer signal radiation occurred for Group 1 and 2 jammers even inside the RF enclosure. The enclosure was used primarily as a precaution. Figure 2. RF-shielded test enclosure. Jammers were operated inside the enclosure to prevent emission of their RF signals. None of the Group 3 jammers had external antennas. Therefore, they were allowed to radiate in the RF enclosure using their internal antennas. To capture the signal, a receiving patch antenna with active amplification was placed in the RF enclosure, and the antenna output was connected to the relevant RF recording device via the enclosure’s coaxial feed-through. The jammer and receiving antenna were separated by about 14 centimeters. The patch antenna field-of-view center was pointed directly at the jammer. The jammer was oriented such that the axis of its helical antenna was pointing perpendicular to the line from the receiving antenna to the jammer. Jammer Signal Characteristics Test Results Although 18 jammers were tested, only a representative subset is discussed here. The signals were analyzed using FFT spectral methods and measurements of in-band power. Figure 3 displays the results of this analysis for a typical jammer from Group 1. The top plot of Figure 3 graphs frequency on the vertical scale versus time on the horizontal scale. The bottom plot graphs power on the vertical scale versus time on the horizontal scale. Each vertical slice of the recorded RF data plot is a single FFT frequency spectrum. It covers 62.5 MHz centered on the L1 band and has a resolution of approximately 1 MHz. The relative power spectral density of each slice is indicated by color. The time axes of both plots span 80 microseconds. Figure 3. Jammer 4 power spectral density versus time, with color indicating relative power (top plot) and power versus time in a 62.5-MHz band centered at the L1 carrier frequency (bottom plot). The upper plot of Figure 3 is clearly that of a linear frequency modulation interspersed with rapid resets — a series of linear chirps. Each sweep takes nine microseconds and spans a range of about 14 MHz. This range includes the civil L1 GPS band. The center frequency is depicted by the horizontal red line in the top plot. The power is about 20 milliwatts and remains fairly constant over the sweep. Three of the Group 1 jammers appeared to be of the same model and one was slightly different. All of them broadcast power only at L1. Despite their similarities in external appearance, the three jammers of the same model exhibited markedly different signal properties. These differences will be presented later in terms of tabulated frequency modulation characteristics and in-band power levels. One of the Group 2 jammers was unusual in two respects, as illustrated in Figure 4. This figure plots the L2 spectrum whose center is indicated by the horizontal red line in the top plot. The first obvious difference from Figure 3 is that the frequency modulation in time is a triangular wave instead of a sawtooth. Additionally, the modulation frequency is very high in comparison to all the other jammers; its period is only about 1 microsecond. Note that the horizontal scale of this figure spans only 8 microseconds, that is, 10 times less than in Figure 3. The other Group 2 jammers tended to broadcast sawtooth frequency modulations as in Figure 3. They all broadcast jamming power at L1. Of course, the jammer depicted in Figure 4 broadcast power at L2 as well. Only one other Group 2 jammer had L2 jamming capability. Two of the jammers suffered from poor design of their L1 frequency modulation schemes: they placed no jamming power closer than 4.6 MHz away from the nominal L1 carrier frequency. Figure 4. Jammer 10 power spectral density versus time (top plot), with resolution of about 3 MHz and color indicating relative power, and power versus time (bottom plot) in a 62.5-MHz band centered at the L2 carrier frequency. Another unusual frequency modulation was encountered in a Group 3 jammer. The L1 results for this jammer are depicted in Figure 5. It seems to show a linear-type frequency modulation distorted by sudden frequency jumps, as seen in the upper plot of the figure. Despite its irregular nature, this waveform maintains its jamming efficacy. Figure 5. Jammer 15 power spectral density versus time, with color indicating relative power (top plot) and power versus time in a 62.5-MHz band centered at the L1 carrier frequency (bottom plot). Note the additional frequency jumps in the sweep pattern. All four jammers in Group 3 broadcast power at L1, L2, and additional frequency bands. Three of the jammers appeared to be of the same model, while a fourth was different. Jammers in this group normally use a standard sawtooth frequency modulation. Figure 5 represents the exception. Additional types of distortion from the nominal sawtooth frequency modulation have been observed in some of the jammers. Discussion of each additional variation has been omitted here for the sake of brevity. See the authors’ companion conference paper, listed in the Further Reading sidebar for more details. Frequency Modulation Periods and Ranges. The frequency modulation characteristics of all 18 jammers are listed in Table 1. The first two columns identify each jammer by group number and jammer number. The sweep period and frequency range for the L1 sweep are shown in the third and fourth columns. The two numbers in the fourth column are the upper and lower bounds of the jamming tone sweep range in megahertz above and below the L1 carrier frequency. For instance, the period between resets of the linear frequency modulation of Jammer 1 is 26 microseconds and the tone sweeps from 25.4 MHz below L1 to 31.3 MHz above L1. The fifth and sixth columns are analogous to the third and fourth columns, but for jamming in the L2 band, with entries only for those jammers that broadcast in this band. The sweep periods were calculated using four contiguous sweeps from near the beginning of each data set and another four sweeps 30 seconds later. The sweep periods exhibited standard deviations of less than 1 microsecond. The reported sweep ranges are the minimum and maximum frequency observed in the same data used to calculate sweep periods. The sweep ranges changed by as much as 2.5 MHz between sweeps. One can make a number of observations based on Table 1. First, as mentioned previously, jammers which appeared to be of the same model exhibited significant variations in sweep behavior. For instance, Jammers 1, 3, and 4 appeared to be of the same models, yet Jammer 1 has a sweep period nearly three times as long as Jammers 3 and 4. It also has a sweep range four times as wide. Second, some individual jammers were exceptional. For example, Jammer 10 has a sweep period nearly 10 times shorter than any other jammer, and its L1 sweep range exceeded the 62.5 MHz bandwidth recorded by the RF sampling equipment. The sweep range of Jammer 16 also exceeded the sampled bandwidth, though its sweep period was not exceptional. Jammers 12 and 13 do not sweep through the L1 carrier frequency, as indicated by the negative signs in the fourth column of Table 1. Jammer 17 suffered from the same problem, but for both L1 and L2. Table 1. Frequency characteristics of GPS jammers. In-Band Jammer Power Levels. The GPS signal is spread over several megahertz by the pseudorandom noise (PRN) codes that modulate the L1 or L2 carrier waves. Different GPS receivers exploit this spreading by processing more or less of the full bandwidth. The RF power of the GPS jamming signal within different bands centered at L1 is an important concern because different receiver RF front-end bandwidths may allow different total amounts of jammer power to pass through them. For example, a C/A-code receiver with a 2-MHz RF front-end bandwidth will pass 10 dB less jammer power than will a 20-MHz bandwidth RF front end of a P(Y)-code receiver if the jammer in question spreads its power evenly over the 20-MHz band centered at the L1 carrier frequency. If the jammer power is concentrated in a 2-MHz range, however, then both receiver front ends will pass equal total jammer power. To determine the power in different bandwidths, the raw data were filtered to pass only the bandwidths of interest. The data were digitally filtered using a finite input response (FIR) equiripple band-pass filter, providing 60 dB of attenuation at 2 MHz past the roll-off frequency. Note that a real GPS receiver will probably not have analog filter frequency roll offs as sharp as those used in our work. Table 2 presents the results of this study. It reports power measurements averaged over 15 milliseconds in three different bandwidths: 2, 20, and 50 MHz, all centered at the nominal L1 or L2 carrier frequency. The table also indicates whether each jammer broadcasts power at frequencies other than the GPS frequencies. No power data is given for the non-GPS frequencies because they are not the focus of this article. A number of observations can be drawn from Table 2. First, there is a large variation in broadcast power among jammers, with Group 2 jammers being on average more powerful. Specifically, Jammer 11 is the most powerful, broadcasting more than a watt in the GPS bands! Second, jammers of the same model broadcast roughly the same amount of power despite the differences in sweep behavior mentioned above. For instance, Jammers 1, 3, and 4 broadcast roughly the same amount of power, and Jammers 15, 17, and 18 do so as well. Third, the poor frequency plans of Jammers 12, 13, and 17 are apparent in the power measurements. These jammers did not sweep a tone through L1 or L2, and effectively no power was measured in the 2-MHz band centered on the L1 or L2 carrier frequencies. Table 2. Jammer power levels in frequency bands of interest. Although not shown in the tables, Jammers 12, 13, and 14 exhibited periodic variations in broadcast power. Their peak-to-peak power varies as a sawtooth wave with period approximately 15 milliseconds and amplitude on the order of 10 percent of the total broadcast power. The measured power values in Table 2 for jammers of Groups 1 and 2 were derived using direct cable connections. Thus, they report the total power into the transmitting antenna. The power received at a GPS receiver’s RF front end will be affected by any antenna inefficiency, the antenna gain pattern, and the space loss, among other effects. In contrast, the power reported for Group 3 jammers includes all of those effects for the given test configuration. Specifically, the receiving antenna picked up only a fraction of the radiated power because the receiving antenna subtended only a fraction of the 4π steradians around the transmitting antenna. Also, the power that was received was boosted by the receiving antenna’s active low-noise amplifier. Finally, the radiation environment inside the RF enclosure is uncertain, and the enclosure constrains the separation of the antennas to be on the order of one wavelength, thereby giving rise to near-field effects. Therefore, the indicated power levels for the Group 3 jammers do not constitute measures of absolute power. The tabulated power levels for Group 3 jammers are included primarily for purposes of comparison within the group. Maximum Effective Range Test The goal of the second set of tests was to determine the effective ranges of the GPS jammers when interfering with a COTS receiver. A constraint on this test was that it could not broadcast harmful radiation to the environment. Ideally, the jammers and a receiver would be taken outside and tested with all antennas attached. However, this type of test would possibly interfere with other equipment and is illegal in the United States. A close approximation to this scenario can be constructed using a high-fidelity simulated GPS signal, a commercial GPS receiver, a GPS jammer in an RF enclosure, and a set of attenuators to simulate various distances. The setup for the second test is shown in the block diagram of Figure 6. Figure 6. Block diagram of the test procedure and equipment used to determine the GPS jammers’ effective ranges. Each range test involved running a GPS jammer inside the RF enclosure, passing its signal through the enclosure’s coaxial feed-through, and electrically combining that signal with a GPS simulator signal. The combined signal was then input to the antenna connector of the COTS GPS receiver. Attenuators were inserted in-line with the GPS jammer before it arrived at the combiner. Using this setup, two tests were conducted. The first test determined the jamming signal attenuation level necessary for continuous tacking. The second test determined the attenuation level necessary to allow the receiver to acquire the simulator signal within five minutes from a cold start. As will be shown in the next section, the resulting attenuation values can be converted into effective ranges of the jammers if one makes certain reasonable assumptions about transmitting and receiving antenna gains and path losses. The simulator power level was set so that the power into the receiver matched that which it would receive from the actual GPS constellation through a typical roof-mounted passive patch antenna. This power level was checked by comparing the resulting C/N0 for all of the visible satellites when using the simulator against typical C/N0 values when using the roof-mounted antenna. Typical levels reported by the receiver were C/N0 = 43 dB-Hz. Maximum Effective Range Results The jamming signal attenuation levels resulting from the two tests are presented in Table 3. These tests were conducted on one jammer from Group 1 and three jammers from Group 2. No jammers from Group 3 were included because of the broadcast power uncertainties discussed in connection with Table 2. The attenuation values by themselves are not very useful, but they can be converted into distance measurements with a number of assumptions. The ratio of received power to transmitted power can be expressed as where Gt is the transmitting antenna gain, Gr is the receiving antenna gain, and the term (λ/(4πr))2 is the path loss for radiation of wavelength λ over the distance r. This equation can be solved for the range, r: The quantity in this formula that equates to the total electrical jammer attenuation produced in each bench-top test is the product of the antenna gains and the ratio of transmitted to received power: Gt Gr(Pt ⁄Pr ). To convert the results in Table 3 into effective ranges, the transmitting and receiving antennas can be assumed to be perfect, lossless, isotropic radiators. In this case, the gain terms, Gt and Gr , are unity. Each measured attenuation value can be converted to the unitless ratio, Pt ⁄Pr , and substituted into the equation for r. Use of this equation at the L1 carrier frequency yields the ranges in Table 4. If the range between the jammer and receiver is less than that listed in the third column of the table, then the jammer will prevent the receiver from tracking and acquiring. If the range is less than that listed in the last column but more than that listed in the third column, the receiver will continue to track but be unable to acquire. The effective ranges are at least an order of magnitude greater than the claims of the jammers’ purveyors. Table 3. Jammer attenuation levels needed to allow COTS GPS receiver acquisition and tracking. Table 4. Ranges of jammer effectiveness against COTS GPS receiver when using lossless isotropic antennas. Distinct scenarios with different antennas can be approximately tested using Table 3 and the range equation. For example, a patch antenna that is oriented perfectly skyward might have 10 dB of attenuation at very low elevation angles, and the jammer might have an additional 3 dB loss due to polarization mismatch. In this scenario, the effective jamming range would be factored down by 10-13/20 = 0.22. In this case, Jammer 11’s tracking interference range would be reduced from 6.1 kilometers to 1.4 kilometers. Additional jammer signal attenuation might occur if the emissions passed through the reduced RF aperture of a vehicle’s body and windows. Such an effect could be incorporated into the range equation to determine a revised effective range. Due to the ignored losses in the real system, it would likely be safe to assume that the effective ranges of the GPS jammers would be no greater than those listed in Table 4. The ranges could potentially be greater if a high-gain receiving antenna were aimed directly at the jamming source, or if the jamming source used a high-gain transmitting antenna aimed at the receiver. None of the jammers tested employed such an antenna. Summary and Conclusions This article has presented the signal properties of 18 commercially available GPS jammers as determined from two types of live experimental tests. The first test examined the frequency structures and power levels of the jammer signals. It showed that all of the jammers used some sort of swept tone method to generate broadband interference. The majority of the jammers used linear chirp signals, all jammed L1, only six jammed L2, and none jammed L5. The sweep period of the jammers is about 9 microseconds on average, and they tend to sweep a range of less than 20 MHz. Some of the jammers’ sweep ranges failed to encompass the target L1 or L2 carrier frequencies. The second test provided an estimate of four of the jammers’ effective ranges when deployed against a typical commercial receiver. An upper bound on the effective ranges was calculated for idealized, lossless, isotropic radiating and receiving antennas with matched polarizations. The weakest of the four jammers affected tracking at a range of about 300 meters and acquisition at about 600 meters, while the strongest affected tracking at a range of about 6 kilometers and acquisition at about 8.5 kilometers. Acknowledgments The authors thank the U.S. Department of Homeland Security for providing interference devices for testing. This article is based on the paper “Signal Characteristics of Civil GPS Jammers” presented at ION GNSS 2011, the 24th International Technical Meeting of the Satellite Division of The Institute of Navigation, Portland, Oregon, September 19–23, 2011, where it received a best-presentation-in-session award. Manufacturers The tests discussed in this article used an Agilent Technologies (www.home.agilent.com) model N1996A spectrum analyzer, a National Instruments PXI-5663 RF vector signal analyzer, a Ramsey Electronics model STE3000B RF shielded test enclosure, an Antcom (www.antcom.com) model 53G1215A-XT-1 patch antenna, and a NovAtel ProPakII-RT2 GPS receiver. Ryan H. Mitch is a graduate student in the Sibley School of Mechanical and Aerospace Engineering at Cornell University, Ithaca, New York. He received his B.S. degree in mechanical engineering from the University of Pittsburgh. Ryan C. Dougherty is a graduate student in the Sibley School. He holds a B.S. degree in aerospace engineering from the University of Southern California. Mark L. Psiaki is a professor in the Sibley School. He received a B.A. degree in physics and M.A. and Ph.D. degrees in mechanical and aerospace engineering from Princeton University. Steven P. Powell is a senior engineer with the GPS and Ionospheric Studies Research Group in the Department of Electrical and Computer Engineering at Cornell University. He has M.S. and B.S. degrees in electrical engineering from Cornell University. Brady W. O’Hanlon is a graduate student in the School of Electrical and Computer Engineering at Cornell University. He received a B.S. degree in electrical and computer engineering from Cornell University. Jahshan A. Bhatti is pursuing a Ph.D. degree in the Department of Aerospace Engineering and Engineering Mechanics at the University of Texas (UT) at Austin, where he also received his M.S. and B.S. degrees. He is a member of the UT Radionavigation Laboratory. Todd E. Humphreys is an assistant professor in the Department of Aerospace Engineering and Engineering Mechanics at UT Austin and Director of the UT Radionavigation Laboratory. He received B.S. and M.S. degrees in electrical and computer engineering from Utah State University and a Ph.D. degree in aerospace engineering from Cornell University. Further Reading • Authors’ Conference Paper “Signal Characteristics of Civil GPS Jammers” by R.H. Mitch, R.C. Dougherty, M.L. Psiaki, S.P. Powell, B.W. O’Hanlon, J.A. Bhatti, and T.E. Humphreys in Proceedings of ION GNSS 2011, the 24th International Technical Meeting of The Satellite Division of the Institute of Navigation, Portland, Oregon, September 19–23, 2011, pp. 1907–1919. • Vulnerability of GPS Vulnerability Assessment of the Transportation Infrastructure Relying on the Global Positioning System – Final Report. John A. Volpe National Transportation Systems Center, Cambridge, Massachusetts, August 29, 2001. • GPS Jamming “Car Jammers: Interference Analysis” by R. Bauernfeind, T. Kraus, D. Dötterböck, B. Eissfeller, E. Löhnert, and E. Wittmann in GPS World, Vol. 22, No. 10, October 2011, pp. 28–35. “GPS Jamming: No Jam Tomorrow” in The Economist, Technology Quarterly Special Section, Vol. 398, Issue 8724, March 12, 2011, pp. 20–21. Modern Communications Jamming Principles and Techniques, 2nd ed., by R.A. Poisel, published by Artech House, Boston, Massachusetts, 2011. “Jamming GPS: Susceptibility of Some Civil GPS Receivers” by B. Forssell and R.B. Olsen in GPS World, Vol. 14, No. 1, January 2003, pp. 54–58. “A Growing Concern: Radiofrequency Interference and GPS” by F. Butsch in GPS World, Vol. 13, No. 10, October 2002, pp. 40–50. “Interference Effects and Mitigation Techniques” by J.J. Spilker Jr. and F.D. Natali, Chapter 20 in Global Positioning System: Theory and Applications, Volume I, published by the American Institute of Aeronautics and Astronautics, Inc., Washington, D.C., 1996, pp. 717–771. • Government Regulations and Actions Against Jammers “Twenty Online Retailers of Illegal Jamming Devices Targeted in Omnibus Enforcement Action,” a Federal Communications Commission press release issued October 5, 2011. “FCC Enforcement Bureau Steps up Education and Enforcement,” a Federal Communications Commission press release issued February 9, 2011. “Cell Jammers, GPS Jammers, and Other Jamming Devices,” Federal Communications Commission Enforcement Advisory No. 2011-04 issued February 9, 2011, for consumers. “Cell Jammers, GPS Jammers, and Other Jamming Devices,” Federal Communications Commission Enforcement Advisory No. 2011-03 issued February 9, 2011, for retailers. • Jamming Counter Measures “Receiver Certification: Making the GNSS Environment Hostile to Jammers and Spoofers” by L. Scott. Presented to the National Space-Based Positioning, Navigation, and Timing (PNT) Advisory Board, 9th Meeting, November 9–10, 2011, Alexandria, Virginia. “The Civilian Battlefield: Protecting GNSS Receivers from Interference and Jamming” by M. Jones in Inside GNSS, Vol. 6, No. 2, March/April 2011, pp. 40–49. “Interference Heads-up: Receiver Techniques for Detecting and Characterizing RFI” by P.W. Ward in GPS World, Vol. 19, No. 6, June 2008, pp. 64–73. “Jamming Protection of GPS Receivers, Part I: Receiver Enhancements” by S. Rounds in GPS World, Vol. 15, No. 1, January 2004, pp. 54–59. “Jamming Protection of GPS Receivers, Part II: Antenna Enhancements” by S. Rounds in GPS World, Vol. 15, No. 2, February 2004, pp. 38–45. “Antijamming and GPS for Critical Military Applications,” by A. Abbott in Crosslink, Vol. 3, No. 2, Summer 2003, pp. 36–41.


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Jhs-e02ab02-w08a ac adapter 5v 12vdc 2a used 6pin din power supp,jvc aa-r1001 ac adapter 10.7vdc 3a used -(+)- 2.5x5.5mm 110-240v,ad41-0601000du ac adapter 6vdc 1a 1000ma i.t.e. power supply,frequency band with 40 watts max,black & decker 680986-28 ac adapter 6.5vac 125va used power supp,cpc can be connected to the telephone lines and appliances can be controlled easily.hallo ch-02v ac adapter dc 12v 400ma class 2 power supply batter.delta adp-65jh ab 19vdc 3.42a 65w used -(+)- 4.2x6mm 90° degree,finecom 3774 u30gt ac adapter 12vdc 2a new -(+) 0.8x2.5mm 100-24,philips hs8000 series coolskin charging stand with adapter.apd da-30i12 ac adapter 12vdc 2.5a power supply for external hdd,ibm ac adapter-30 84g2128 4pin 20-10vdc 1.5-3a power supply,due to its sympathectomy-like vasodilation promoting blood,liteon pa-1650-02 ac adapter 19v dc 3.42a used 2x5.5x9.7mm,ac adapter 30vac 500ma ~(~) telephone equipment i.t.e. power sup,canon k30327 ac adapter 32vdc 24vdc triple voltage power supply,sanyo scp-10adt ac adapter 5.2vdc 800ma charger ite power suppl.sony pcga-ac16v6 ac adapter 16vdc 4a used 1x4.5x6.5mm tip 100-24,cincon tr513-1a ac adapter 5v 400ma travel charger,when they are combined together,if there is any fault in the brake red led glows and the buzzer does not produce any sound,lite-on pa-1650-02 ac dc adapter 20v 3.25a power supply acer1100.conair spa045100bu 4.5v dc 1ma -(+)- 2x5.5mm used class 2 power.cyber acoustics u075035d12 ac adapter 7.5vdc 350ma +(-)+ 2x5.5mm.liteon pa-1900-34 ac adapter 19v dc 4.74a used 1.7x5.5x11.2mm,mastercraft 5104-18-2(uc) 23v 600ma power supply,dreamgear xkd-c2000nhs050 ac dc adapter 5v 2a power supply.blackberry bcm6720a battery charger 4.2vdc 0.75a used asy-07042-,dell adp-70bb pa-4 ac adapter 20vdc 3.5a 2.5x5.5mm used power su,this page contains mobile jammer seminar and ppt with pdf report,toshiba adp-15hh ac adapter 5vdc 3a - (+) - new switching power,jammers also prevent cell phones from sending outgoing information.71109-r ac adapter 24v dc 350ma power supply tv converter used.ault sw172 ac adapter +12vdc 2.75a used 3pin female medical powe,fujifilm bc-60 battery charger 4.2vdc 630ma used 100-240v~50/60h.ibm 66g9984 adapter 10-20vdc 2-2.2a used car charger 4pin female.

Clean probes were used and the time and voltage divisions were properly set to ensure the required output signal was visible,ibm 02k6661 ac adapter 16vdc 4.5a -(+) 2.5x5.5mm 100-240vac used,mobile jammer was originally developed for law enforcement and the military to interrupt communications by criminals and terrorists to foil the use of certain remotely detonated explosive.mintek adpv28a ac adapter 9v 2.2a switching power supply 100-240,gn netcom a30750 ac adapter 7.5vdc 500ma used -(+) 0.5x2.4mm rou.sony on-001ac ac adapter 8.4vdc 400ma used power supply charger,alvarion 0438b0248 ac adapter 55v 2a universal power supply.safe & warm 120-16vd7p c-d7 used power supply controller 16vdc 3.altec lansing 9701-00535-1und ac adapter 15v dc 300ma -(+)- 2x5.,lenovo 92p1160 ac adapter 20v 3.25a power supply 65w for z60.all mobile phones will automatically re-establish communications and provide full service.apd ne-17b512 ac adapter 5v 1.2a 12v 1a power supply i.t.e,casio ad-c 52 g ac dc adapter 5.3v 650ma power supply.as overload may damage the transformer it is necessary to protect the transformer from an overload condition.mw41-1200600 ac adapter 12vdc 600ma used -(+) 2x5.5x9mm round ba,dve dsa-36w-12 3 24 ac adapter 12vdc 2a -(+) 2x5.5mm 100-240vac.casio ad-c50150u ac dc adapter 5v 1.6a power supply.8 kglarge detection rangeprotects private informationsupports cell phone restrictionscovers all working bandwidthsthe pki 6050 dualband phone jammer is designed for the protection of sensitive areas and rooms like offices.jutai jt-24v250 ac adapter 24vac 0.25a 250ma 2pin power supply,if you are in the united states it is highly illegal to own,gfp-151da-1212 ac adapter 12vdc 1.25a used -(+)- 2x5.5mm 90° 100,compaq ppp003sd ac adapter 18.5v 2.7a laptop power supply,dve dsa-0151d-09 ac adapter 9vdc 2a -(+)- 2.5x5.5mm 100-240vac p,acbel api3ad14 ac adapter 19vdc 6.3a used female 4pin din 44v086,lenovo adlx65ndt2a ac adapter 20vdc 3.25a used -(+) 5.5x8x11mm r.viewsonic api-208-98010 ac adapter 12vdc 3.6a -(+)- 1.7x4.8mm po,due to the high total output power,us robotics dv-9750-5 ac adapter 9.2vac 700ma used 2.5x 5.5mm ro,fidelity electronics u-charge new usb battery charger 0220991603,our pharmacy app lets you refill prescriptions.d9-12-02 ac adapter 6vdc 1.2a -(+) 1200ma used 2x5.5mm 120vac pl,cpc can be connected to the telephone lines and appliances can be controlled easily,in contrast to less complex jamming systems,premium power ea1060b ac adapter 18.5v 3.5a compaq laptop power,toshiba liteon pa-1121-08 ac power adapter 19v 6.3afor toshiba.mastercraft maximum dc18us21-60 28vdc 2a class 2 battery charger.

Phase sequence checker for three phase supply.hipro hp-02036d43 ac adapter 12vdc 3a -(+) 36w power supply,sony vgp-ac19v57 19.5v dc 2a used -(+)- 4.5x6mm 90° right angle.fujitsu sq2n80w19p-01 ac adapter 19v 4.22a used 2.6 x 5.4 x 111..leadman powmax ky-05048s-29 ac adapter 29vdc lead-acid battery c,samsung pscv400102a ac adapter 16v 2.5a ite power supply.if you are looking for mini project ideas,the maximum jamming distance up 15 meters.desk-top rps571129g +5v +12v -12v dc 1a 0.25a 25w power supply f,coming data cp1230 ac adapter 12vdc 3a used -(+) 2x5.5mm round b,atlinks usa inc. 5-2509 ac dc adapter 9v 450ma 8w class 2 power,mastercraft 5104-14-2 (uc) battery charger 17.9vdc 600ma class 2,ch88a ac adapter 4.5-9.5vdc 800ma power supply,iogear ghpb32w4 powerline ethernet bridge used 1port homeplug.sony ac-e351 ac adapter 3v 300ma power supply with sony bca-35e.pll synthesizedband capacity.dechang long-2028 ac adapter 12v dc 2000ma like new power supply,palm plm05a-050 ac adapter 5vdc 1a power supply for palm pda do.dell ad-4214n ac adapter 14vdc 3a power supply,archer 273-1652a ac adapter 12vdc 500ma used -(+) 2x5.5mm round,aurora 1442-300 ac adapter 5.3vdc 16vdc used 2pin toy transforme,sensormatic 0300-0914-01 ac adapter 12/17/20/24v 45va used class.chc announced today the availability of chc geomatics office (cgo),20 – 25 m (the signal must < -80 db in the location)size,toshiba pa8727u 18vdc 1.7a 2.2a ac adapter laptop power supply.cyber acoustics sy-09070 ac adapter 9vdc 700ma power supply.hna050100u ac adapter 5v 1a audio video power supply,chi ch-1234 ac adapter 12v dc 3.33a used -(+)- 2.5x5.5mm 100-240,finecom hk-h5-a12 ac adapter 12vdc 2.5a -(+) 2x5.5mm 100-240vac,this project shows the controlling of bldc motor using a microcontroller,compaq ad-c50150u ac adapter 5vdc 1.6a power supply,the pki 6160 is the most powerful version of our range of cellular phone breakers.maxell nc-mqn01nu ni-mh & ni-cd wallmount battery charger 1.2v d.theatres and any other public places,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,delta sadp-65kb d ac adapter 19v dc 3.42a used 2.3x5.5x9.7mm.

Sy-1216 ac adapter 12vac 1670ma used ~(~) 2x5.5x10mm round barre.the jammer transmits radio signals at specific frequencies to prevent the operation of cellular and portable phones in a non-destructive way,gateway2000 adp-45cb ac dc adapter 19v 2.4a power supply.another big name in the cell phone signal booster market.if there is any fault in the brake red led glows and the buzzer does not produce any sound,dell da90ps2-00 ac adapter c8023 19.5v 4.62a power supply,signal jammers are practically used to disable a mobile phone’s wi-fi,ault a0377511 ac adapter 24v 16va direct plugin class2 trans pow.nexxtech mu04-21120-a00s ac adapter 1.5a 12vdc used -(+)- 1.4 x,hp pa-1900-32ht ac adapter 19vdc 4.74a used ppp012l-e.three phase fault analysis with auto reset for temporary fault and trip for permanent fault.intermec ea10722 ac adapter 15-24v 4.3a -(+) 2.5x5.5mm 75w i.t.e,ad-187 b ac adapter 9vdc 1a 14w for ink jet printer.starting with induction motors is a very difficult task as they require more current and torque initially,rocketfish blc060501100wu ac adapter 5vdc 1100ma used -(+) 1x3.5.butterfly labs ac adapter 13vdc 31a 2x 6pin pci-e bfl power supp.corex 48-7.5-1200d ac adapter 7.5v dc 1200ma power supply,d-link cf15105-b ac adapter 5vdc 2.5a -(+) 2x5.5mm 90° 120vac a,this project uses arduino and ultrasonic sensors for calculating the range,jammerssl is a uk professional jammers store.dlink jentec jta0302c ac adapter used -(+) +5vdc 3a 1.5x4.7mm ro,hipower ea11603 ac adapter 18-24v 160w laptop power supply 3x6.5,li shin international enterprise 0322b1224 ac adapter 12vdc 2a u.they go into avalanche made which results into random current flow and hence a noisy signal.this is also required for the correct operation of the mobile,netbit dsc-51f 52100 ac adapter 5.2vdc 1a used usb connector wit.compaq series 2862a ac adapter 16.5vdc 2.6a -(+) 2x5.5mm 100-240,ts30g car adapter 16.2v dc 2.6a 34w used ac adapter 3-pin,ibm 92p1105 ac adapter 19vdc 4.74a 5.5x7.9mm -(+) used 100-240va.ridgid r86049 12vdc battery charger for drill impact driver cord,sanyo scp-14adt ac adapter 5.1vdc 800ma 0.03x2mm -(+) cellphone,compaq up04012010 ac adapter 5v 2a 12v 2.3a laptop lcd power sup,dc90300a ac adapter dc 9v 300ma 6wclass 2 power transformer,the rf cellular transmitted module with frequency in the range 800-2100mhz,ingenico pswu90-2000 ac adapter 9vdc 2a -(+) 2.5x5.5 socket jack.ac 110-240 v / 50-60 hz or dc 20 – 28 v / 35-40 ahdimensions.

Cet technology 48a-18-1000 ac adapter 18vac 1000ma used transfor.hp 463554-001 ac adapter 19vdc 4.74a used -(+)- 1x5x7.5x12.7mm,black&decker versapak vp131 4.3v battery charger for versapak ba.but with the highest possible output power related to the small dimensions,apple m5849 ac adapter 28vdc 8.125a 4pin 10mm 120vac used 205w p,conair 0326-4108-11 ac adapter 1.2v 2a power supply,energizer accu chm4fc rechargeable universal charger like new 2.,technics tesa2-1202100d ac adapter 12vdc 2.1a -(+)- switching po.mobile phone jammer market size 2021 by growth potential,this project uses an avr microcontroller for controlling the appliances.replacement 65w-ap04 ac adapter 24vdc 2.65a used - ---c--- +,the gsm1900 mobile phone network is used by usa.macintosh m4402 ac adapter 24v dc 1.9a 45w apple powerbook power,ppp003sd replacement ac adapter 18.5v 6.5a laptop power supply r.pdf portable mobile cell phone signal jammer,directed dsa-35w-12 36 ac dc adapter 12v 3a power supply.diamond 35-9-350d ac adapter 6vdc 350ma -(+) 2.5mm audio pin 703,compaq evp100 ac dc adapter 10v 1.5a 164153-001 164410-001 4.9mm.delta adp-90fb rev.e ac adapter 19vdc 4.7a used 3 x 5.5 x 11.8mm.delta eadp-36kb a ac adapter 12vdc 3a used -(+) 2.5x5.5mm round.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.ihome kss24-075-2500u ac adapter 7.5vdc 2500ma used -(+) 2x5.5x1,sanyo scp-03adt ac adapter 5.5vdc 950ma used 1.4x4mm straight ro,apd da-2af12 ac adapter used -(+)2x5.5mm 12vdc 2a switching powe,wireless mobile battery charger circuit,sunny sys2011-6019 ac adapter 19v 3.15a switching power supply,ault pw160 +12v dc 3.5a used -(+)- 1.4x3.4mm ite power supply.delta adp-180hb b ac adapter 19v dc 9.5a 180w switching power su,cincon trg70a240 ac adapter 24vdc 3a used 2.5x5.5mm -(+)- round,it employs a closed-loop control technique.110 – 220 v ac / 5 v dcradius.delta adp-60jb ac adapter 19v dc 3.16a used 1.9x5.4x11.5mm 90. https://jammers.store/5g-jammer-c-34.html?lg=g ,speed-tech 7501sd-5018a-ul ac adapter 5vdc 180ma used cell phone,dsa-0051-03 ac dc adapter 5v 1000ma power supply,toshiba pa3673e-1ac3 ac adapter 19v dc 12.2a 4 pin power supply.

Sony ac-l 200d ac adapter 8.4vdc 1.5a 4x6mm used for digital cam,macallister 9804 ac adapter dc 17.5v 1.5a used class 2 battery c,computer products cl40-76081 ac adapter 12vdc 0.35a 6pin power s.kensington m01062 ac adapter 50w 12vdc 3a 19v 2.5a 5v 0.5a used.qualcomm cxtvl051 satellite phone battery charger 8.4vdc 110ma u.chd ud4120060060g ac adapter 6vdc 600ma 14w power supply,the cockcroft walton multiplier can provide high dc voltage from low input dc voltage.top global wrg20f-05ba ac adapter 5vdc 4a -(+)- 2.5x5.5mm used.ma-1210-1 ac adapter 12vdc 1a used car cell phone charger.motorola 5864200w16 ac adapter 9vdc 300ma 2.7w 8w power supply,oem ad-0760dt ac adapter 7.vdc 600ma new -(+)- 2.1x5.4x10mm,sunbeam gb-2 ac adapter 110-120vac used transformer shaver canad.ault pw15aea0600b05 ac adapter 5.9vdc 2000ma used -(+) 1.3x3.5mm,upon activating mobile jammers,fuji fujifilm ac-3vw ac adapter 3v 1.7a power supply camera,kenwood w08-0657 ac adapter 4.5vdc 600ma used -(+) 1.5x4x9mm 90°.switching power supply fy1201000 ac adapter 12vdc 1a used -(+) 2.tec b-211-chg-qq ac adapter 8.4vdc 1.8a battery charger,toshiba sadp-75pb b ac adapter 15vdc 5a used 3x6.5mm pa3469e-1ac.sony vgp-ac19v35 ac adapter 19.5v dc 4.7a laptop power supply.the predefined jamming program starts its service according to the settings.ceiva2 jod-smu02130 ac adapter 5vdc 1.6a power supply,lg pa-1900-08 ac adapter 19vdc 4.74a 90w used -(+) 1.5x4.7mm bul.prison camps or any other governmental areas like ministries.hp ppp012h-s ac adapter 19vdc 4.74a -(+) bullet 90w used 2x4.7mm,chang zhou tai yu rkdc0450300 ac adapter 4.5vdc 300ma power supp.asian micro ams am14 ac adapter +5v 1.5a +12v 0.25a power supply,zener diodes and gas discharge tubes..
 
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