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Autonomous GPS Positioning at High Earth Orbits To initially acquire the GPS signals, a receiver also would have to search quickly through the much larger range of possible Doppler shifts and code delays than those experienced by a terrestrial receiver. By William Bamford, Luke Winternitz and Curtis Hay INNOVATION INSIGHTS by Richard Langley GPS RECEIVERS have been used in space to position and navigate satellites and rockets for more than 20 years. They have also been used to supply accurate time to satellite payloads, to determine the attitude of satellites, and to profile the Earth’s atmosphere. And GPS can be used to position groups of satellites flying in formation to provide high-resolution ground images as well as small-scale spatial variations in atmospheric properties and gravity. Receivers in low Earth orbit have virtually the same view of the GPS satellite constellation as receivers on the ground. But satellites orbiting at geostationary altitudes and higher have a severely limited view of the main beams of the GPS satellites. The main beams are either directed away from these high-altitude satellites or they are blocked to a large extent by the Earth. Typically, not even four satellites can be seen by a conventional receiver. However, by using the much weaker signals emitted by the GPS satellite antenna side lobes, a receiver may be able track a sufficient number of satellites to position and navigate itself. To initially acquire the GPS signals, a receiver also would have to search quickly through the much larger range of possible Doppler shifts and code delays than those experienced by a terrestrial receiver. In this month’s column, William Bamford, Luke Winternitz, and Curtis Hay discuss the architecture of a receiver with these needed capabilities — a receiver specially designed to function in high Earth orbit. They also describe a series of tests performed with a GPS signal simulator to validate the performance of the receiver here on the ground — well before it debuts in orbit. “Innovation” is a regular column featuring discussions about recent advances in GPS technology and its applications as well as the fundamentals of GPS positioning. The column is coordinated by Richard Langley of the Department of Geodesy and Geomatics Engineering at the University of New Brunswick, who appreciates receiving your comments and topic suggestions. To contact him, see the “Columnists” section in this issue. Calculating a spacecraft’s precise location at high orbits — 22,000 miles (35,400 kilometers) and beyond — is an important and challenging problem. New and exciting opportunities become possible if satellites are able to autonomously determine their own orbits. First, the repetitive task of periodically collecting range measurements from terrestrial antennas to high-altitude spacecraft becomes less important — this lessens competition for control facilities and saves money by reducing operational costs. Also, autonomous navigation at high orbital altitudes introduces the possibility of autonomous station-keeping. For example, if a geostationary satellite begins to drift outside of its designated slot, it can make orbit adjustments without requiring commands from the ground. Finally, precise onboard orbit determination opens the door to satellites flying in formation — an emerging concept for many scientific space applications. Realizing these benefits is not a trivial task. While the navigation signals broadcast by GPS satellites are well suited for orbit and attitude determination at lower altitudes, acquiring and using these signals at geostationary (GEO) and highly elliptical orbits (HEOs) is much more difficult. This situation is illustrated in FIGURE 1. Figure 1. GPS signal reception at GEO and HEO orbital altitudes. The light blue trace shows the GPS orbit at approximately 12,550 miles (20,200 kilometers) altitude. GPS satellites were designed to provide navigation signals to terrestrial users — because of this, the antenna array points directly toward the Earth. GEO and HEO orbits, however, are well above the operational GPS constellation, making signal reception at these altitudes more challenging. The nominal beamwidth of a Block II/IIA GPS satellite antenna array is approximately 42.6 degrees. At GEO and HEO altitudes, the Earth blocks most of these primary beam transmissions, leaving only a narrow region of nominal signal visibility near the limb of the Earth.This region is highlighted in gray. If GPS receivers at GEO and HEO orbits were designed to use these higher power signals only, precise orbit determination would not be practical. Fortunately, the GPS satellite antenna array also produces side-lobe signals at much lower power levels. The National Aeronautics and Space Administration (NASA) has designed and tested the Navigator, a new GPS receiver that can acquire and track these weaker signals, dramatically increasing signal visibility at these altitudes. While using much weaker signals is a fundamental requirement for a high orbital altitude GPS receiver, it is certainly not the only challenge. Other unique characteristics of this application must also be considered. For example, position dilution of precision (PDOP) figures are much higher at GEO and HEO altitudes because visible GPS satellites are concentrated in a much smaller region with respect to the spacecraft antenna. These poor PDOP values contribute considerable error to the point-position solutions calculated by the spacecraft GPS receiver. Extreme Conditions. Finally, spacecraft GPS receivers must be designed to withstand a variety of extreme environmental conditions. Variations in acceleration between launch and booster separation are extreme. Temperature gradients in the space environment are also severe. Furthermore, radiation effects are a major concern — spaceborne GPS receivers should be designed with radiation-hardened parts to minimize damage caused by continuous exposure to low-energy radiation as well as damage and operational upsets from high-energy particles. Perhaps most importantly, we typically cannot repair or modify a spaceborne GPS receiver after launch. Great care must be taken to ensure all performance characteristics are analyzed before liftoff. Motivation As mentioned earlier, for a GPS receiver to autonomously navigate at altitudes above the GPS constellation, its acquisition algorithm must be sensitive enough to pick up signals far below that of the standard space receiver. This concept is illustrated in FIGURE 2. The colored traces represent individual GPS satellite signals. The topmost dotted line represents the typical threshold of traditional receivers. It is evident that such a receiver would only be able to track a couple of the strong, main-lobe signals at any given time, and would have outages that can span several hours. The lower dashed line represents the design sensitivity of the Navigator receiver. The 10 dB reduction allows Navigator to acquire and track the much weaker side-lobe signals. These side lobes augment the main lobes when available, and almost completely eliminate any GPS signal outages. This improved sensitivity is made possible by the specialized acquisition engine built into Navigator’s hardware. Figure 2. Simulated received power at GEO orbital altitude. Acquisition Engine Signal acquisition is the first, and possibly most difficult, step in the GPS signal processing procedure. The acquisition task requires a search across a three-dimensional parameter space that spans the unknown time delay, Doppler shift, and the GPS satellite pseudorandom noise codes. In space applications, this search space can be extremely large, unless knowledge of the receiver’s position, velocity, current time, and the location of the desired GPS satellite are available beforehand. Serial Search. The standard approach to this problem is to partition the unknown Doppler-delay space into a sufficiently fine grid and perform a brute force search over all possible grid points. Traditional receivers use a handful of tracking correlators to serially perform this search. Without sufficient information up front, this process can take 10–20 minutes in a low Earth orbit (LEO), or even terrestrial applications, and much longer in high-altitude space applications. This delay is due to the exceptionally large search space the receiver must hunt through and the inefficiency of serial search techniques. Acquisition speed is relevant to the weak signal GPS problem, because acquiring weak signals requires the processing of long data records. As it turns out, using serial search methods (without prior knowledge) for weak signal acquisition results in prohibitively long acquisition times. Many newer receivers have added specialized fast-acquisition capability. Some employ a large array of parallel correlators; others use a 32- to 128-point fast Fourier transform (FFT) method to efficiently resolve the frequency dimension. These methods can significantly reduce acquisition time. Another use of the FFT in GPS acquisition can be seen in FFT-correlator-based block-processing methods, which offer dramatically increased acquisition performance by searching the entire time-delay dimension at once. These methods are popular in software receivers, but because of their complexity, are not generally used in hardware receivers. Exceptional Navigator. One exception is the Navigator receiver. It uses a highly specialized hardware acquisition engine designed around an FFT correlator. This engine can be thought of as more than 300,000 correlators working in parallel to search the entire Doppler-delay space for any given satellite. The module operates in two distinct modes: strong signal mode and weak signal mode. Strong signal mode processes a 1 millisecond data record and can acquire all signals above –160 dBW in just a few seconds. Weak signal mode has the ability to process arbitrarily long data records to acquire signals down to and below –175 dBW. At this level, 0.3 seconds of data are sufficient to reliably acquire a signal. Additionally, because the strong, main-lobe, signals do not require the same sensitivity as the side-lobe signals, Navigator can vary the length of the data records, adjusting its sensitivity on the fly. Using essentially standard phase-lock-loop/delay-lock-loop tracking methods, Navigator is able to track signals down to approximately –175 dBW. When this tracking loop is combined with the acquisition engine, the result is the desired 10 dB sensitivity improvement over traditional receivers. FIGURE 3 illustrates Navigator’s acquisition engine. Powered by this design, Navigator is able to rapidly acquire all GPS satellites in view, even with no prior information. In low Earth orbit, Navigator typically acquires all in-view satellites within one second, and has a position solution as soon as it has finished decoding the ephemeris from the incoming signal. In a GEO orbit, acquisition time is still typically under a minute. Figure 3. Navigator signal acquisition engine. Navigator breadboard. GPS constellation simulator. Navigator Hardware Outside this unique acquisition module, Navigator employs the traditional receiver architecture: a bank of hardware tracking correlators attached to an embedded microprocessor. Navigator’s GPS signal-processing hardware, including both the tracking correlators and the acquisition module, is implemented in radiation-hardened field programmable gate arrays (FPGAs). The use of FPGAs, rather than an application-specific integrated circuit, allows for rapid customization for the unique requirements of upcoming missions. For example, when the L2 civil signal is implemented in Navigator, it will only require an FPGA code change, not a board redesign. The current Navigator breadboard—which, during operation, is mounted to a NASA-developed CPU card—is shown in the accompanying photo. The flight version employs a single card design and, as of the writing of this article, is in the board-layout phase. Flight-ready cards will be delivered in October 2006. Integrated Navigation Filter Even with its acquisition engine and increased sensitivity, Navigator isn’t always able to acquire the four satellites needed for a point solution at GEO altitudes and above. To overcome this, the GPS Enhanced Onboard Navigation System (GEONS) has been integrated into the receiver software. GEONS is a powerful extended Kalman filter with a small package size, ideal for flight-software integration. This filter makes use of its internal orbital dynamics model in conjunction with incoming measurements to generate a smooth solution, even if fewer than four GPS satellites are in view. The GEONS filter combines its high-fidelity orbital dynamics model with the incoming measurements to produce a smoother solution than the standard GPS point solution. Also, GEONS is able to generate state estimates with any number of visible satellites, and can provide state estimation even during complete GPS coverage outages. Hardware Test Setup We used an external, high-fidelity orbit propagator to generate a two-day GEO trajectory, which we then used as input for the Spirent STR4760 GPS simulator. This equipment, shown in the accompanying photo, combines the receiver’s true state with its current knowledge of the simulated GPS constellation to generate the appropriate radio frequency (RF) signals as they would appear to the receiver’s antenna. Since there is no physical antenna, the Spirent SimGEN software package provides the capability to model one. The Navigator receiver begins from a cold start, with no advance knowledge of its position, the position of the GPS satellites, or the current time. Despite this lack of information, Navigator typically acquires its first satellites within a minute, and often has its first position solution within a few minutes, depending on the number of GPS satellites in view. Once a position solution has been generated, the receiver initializes the GEONS navigation filter and provides it with measurements on a regular, user-defined basis. The Navigator point solution is output through a high-speed data acquisition card, and the GEONS state estimates, covariance, and measurement residuals are exported through a serial connection for use in data analysis and post-processing. We configured the GPS simulator to model the receiving antenna as a hemispherical antenna with a 135-degree field-of-view and 4 dB of received gain, though this antenna would not be optimal for the GEO case. Assuming a nadir-pointing antenna, all GPS signals are received within a 40-degree angle with respect to the bore sight. Furthermore, no signals arrive from between 0 and 23 degrees elevation angle because the Earth obstructs this range. An optimal GEO antenna (possibly a high-gain array) would push all of the gain into the feasible elevation angles for signal reception, which would greatly improve signal visibility for Navigator (a traditional receiver would still not see the side lobes). Nonetheless, the following results provide an important baseline and demonstrate that a high-gain antenna, which would increase size and cost of the receiver, may not be necessary with Navigator. The GPS satellite transmitter gain patterns were set to model the Block II/IIA L1 reference gain pattern. Simulation Results To validate the receiver designs, we ran several tests using the configuration described above. The following section describes the results from a subset of these tests. Tracked Satellites. The top plot of FIGURE 4 illustrates the total number of satellites tracked by the Navigator receiver during a two-day run with the hemispherical antenna. On average, Navigator tracked between three and four satellites over the simulation period, but at times as many as six and as few as zero were tracked. The middle pane depicts the number of weak signals tracked—signals with received carrier-to-noise-density ratio of 30 dB-Hz or less. The bottom panel shows how many satellites a typical space receiver would pick up. It is evident that Navigator can track two to three times as many satellites at GEO as a typical receiver, but that most of these signals are weak. Figure 4. Number of satellites tracked in GEO simulation. Acquisition Thresholds. The received power of the signals tracked with the hemispherical antenna is plotted in the top half of FIGURE 5. The lowest power level recorded was approximately –178 dBW, 3 dBW below the design goal. (Note the difference in scale from Figure 1, which assumed an additional 6 dB of antenna gain.) The bottom half of Figure 5 shows a histogram of the tracked signals. It is clear that most of the signals tracked by Navigator had received power levels around –175 dBW, or 10 dBW weaker than a traditional receiver’s acquisition threshold. Figure 5. Signal tracking data from GEO simulation. Navigation Filter. To validate the integration of the GEONS software, we compared its estimated states to the true states over the two-day period. These results are plotted in FIGURE 6. For this simulation, we assumed that GPS satellite clock and ephemeris errors could be corrected by applying NASA’s Global Differential GPS System corrections, and errors caused by the ionosphere could be removed by masking signals that passed close to the Earth’s limb. The truth environment consisted of a 70X70 degree-and-order gravity model and sun-and-moon gravitational effects, as well as drag and solar-radiation pressure forces. GEONS internally modeled a 10X10 gravity field, solar and lunar gravitational forces, and estimated corrections to drag and solar-radiation pressure parameters. (Note that drag is not a significant error source at these altitudes.) Though the receiver produces pseudorange, carrier-phase, and Doppler measurements, only the pseudorange measurement is being processed in GEONS. Figure 6. GEONS state estimation errors for GEO simulation. The results, compiled in TABLE 1, show that the 3D root mean square (r.m.s.) of the position error was less than 10 meters after the filter converges. The velocity estimation agreed very well with the truth, exhibiting less than 1 millimeter per second of three-dimensional error. Navigator can provide excellent GPS navigation data at low Earth orbit as well, with the added benefit of near instantaneous cold-start signal acquisition. For completeness, the low Earth orbit results are included in Table 1. Navigator’s Future Navigator’s unique features have attracted the attention of several NASA projects. In 2007, Navigator is scheduled to launch onboard the Space Shuttle as part of the Hubble Space Telescope Servicing Mission 4: Relative Navigation Sensor (RNS) experiment. Additionally, the Navigator/GEONS technology is being considered as a critical navigational instrument on the new Geostationary Operational Environmental Satellites (GOES-R). In another project, the Navigator receiver is being mated with the Intersatellite Ranging and Alarm System (IRAS) as a candidate absolute/relative state sensor for the Magnetospheric Multi-Scale Mission (MMS). This mission will transition between several high-altitude highly elliptical orbits that stretch well beyond GEO. Initial investigations and simulations using the Spirent simulator have shown that Navigator/GEONS can easily meet the mission’s positioning requirements, where other receivers would certainly fail. Conclusion NASA’s Goddard Space Flight Center has conducted extensive test and evaluation of the Navigator GPS receiver and GEONS orbit determination filter. Test results, including data from RF signal simulation, indicate the receiver has been designed properly to autonomously calculate precise orbital information at altitudes of GEO and beyond. This is a remarkable accomplishment, given the weak GPS satellite signals observed at these altitudes. The GEONS filter is able to use the measurements provided by the Navigator receiver to calculate precise orbits to within 10 meters 3D r.m.s. Actual flight test data from future missions including the Space Shuttle RNS experiment will provide further performance characteristics of this equipment, from which its suitability for higher orbit missions such as GOES-R and MMS can be confirmed. Manufacturers The Navigator receiver was designed by the NASA Goddard Space Flight Center Components and Hardware Systems Branch (Code 596) with support from various contractors. The 12-channel STR4760 RF GPS signal simulator was manufactured by Spirent Communications (www.spirentcom.com). FURTHER READING 1. Navigator GPS receiver “Navigator GPS Receiver for Fast Acquisition and Weak Signal Tracking Space Applications” by L. Winternitz, M. Moreau, G. Boegner, and S. Sirotzky, in Proceedings of ION GNSS 2004, the 17th International Technical Meeting of the Satellite Division of The Institute of Navigation, Long Beach, California, September 21–24, 2004, pp. 1013-1026. “Real-Time Geostationary Orbit Determination Using the Navigator GPS Receiver” by W. Bamford, L. Winternitz, and M. Moreau in Proceedings of NASA 2005 Flight Mechanics Symposium, Greenbelt, Maryland, October 18–20, 2005 (in press). A pre-publication version of the paper is available online at http://www.emergentspace.com/pubs/Final_GEO_copy.pdf. 1. GPS on high-altitude spacecraft “The View from Above: GPS on High Altitude Spacecraft” by T.D. Powell in GPS World, Vol. 10, No. 10, October 1999, pp. 54–64. “Autonomous Navigation Improvements for High-Earth Orbiters Using GPS” by A. Long, D. Kelbel, T. Lee, J. Garrison, and J.R. Carpenter, paper no. MS00/13 in Proceedings of the 15th International Symposium on Spaceflight Dynamics, Toulouse, June 26–30, 2000. Available online at http://geons.gsfc.nasa.giv/library_docs/ISSFDHEO2.pdf. 1. GPS for spacecraft formation flying “Autonomous Relative Navigation for Formation-Flying Satellites Using GPS” by C. Gramling, J.R. Carpenter, A. Long, D. Kelbel, and T. Lee, paper MS00/18 in Proceedings of the 15th International Symposium on Spaceflight Dynamics, Toulouse, June 26–30, 2000. Available online at http://geons.gsfc.nasa.giv/library_docs/ISSFDrelnavfinal.pdf. “Formation Flight in Space: Distributed Spacecraft Systems Develop New GPS Capabilities” by J. Leitner, F. Bauer, D. Folta, M. Moreau, R. Carpenter, and J. How in GPS World, Vol. 13, No. 2, February 2002, pp. 22–31. 1. Fourier transform techniques in GPS receiver design “Block Acquisition of Weak GPS Signals in a Software Receiver” by M.L. Psiaki in Proceedings of ION GPS 2001, the 14th International Technical Meeting of the Satellite Division of The Institute of Navigation, Salt Lake City, Utah, September 11–14, 2001, pp. 2838–2850. 1. Testing GPS receivers before flight “Pre-Flight Testing of Spaceborne GPS Receivers Using a GPS Constellation Simulator” by S. Kizhner, E. Davis, and R. Alonso in Proceedings of ION GPS-99, the 12th International Technical Meeting of the Satellite Division of The Institute of Navigation, Nashville, Tennessee, September 14–17, 1999, pp. 2313–2323. BILL BAMFORD is an aerospace engineer for Emergent Space Technology, Inc., in Greenbelt, Maryland. He earned a Ph.D. from the University of Texas at Austin in 2004, where he worked on precise formation flying using GPS as the primary navigation sensor. As an Emergent employee, he has worked on the development of the Navigator receiver and helped support and advance the NASA Goddard Space Flight Center’s Formation Flying Testbed. He can be reached at bill.bamford@emergentspace.com. LUKE WINTERNITZ is an electrical engineer in hardware components and systems at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. He has worked at Goddard for three years primarily in the development of GPS receiver technology. He received bachelor’s degrees in electrical engineering and mathematics from the University of Maryland, College Park, in 2001 and is a part-time graduate student there pursuing a Ph.D. He can be reached at Luke.B.Winternitz.1@gsfc.nasa.gov. CURTIS HAY served as an officer in the United States Air Force for eight years in a variety of GPS-related assignments. He conducted antijam GPS R&D for precision weapons and managed the GPS Accuracy Improvement Initiative for the control segment. After separating from active duty, he served as the lead GPS systems engineer for OnStar. He is now a systems engineer for Spirent Federal Systems in Yorba Linda, California, a supplier of high-performance GPS test equipment. He can be reached at curtis.hay@spirentfederal.com.

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Nokia acp-7e ac adapter 3.7v 355ma 230vac chargecellphone 3220.palm plm05a-050 dock with palm adapter for palm pda m130, m500,,hp pa-1151-03hv ac adapter 19vdc 7.89a used 1 x 5 x 7.4 x 12.6mm,the aim of this project is to achieve finish network disruption on gsm- 900mhz and dcs-1800mhz downlink by employing extrinsic noise,we have designed a system having no match.tec rb-c2001 battery charger 8.4v dc 0.9a used b-sp2d-chg ac 100,wifi jamming allows you to drive unwanted,pll synthesizedband capacity.du090060d ac adapter 9vdc 600ma class 2 power supply,sps15-007 (tsa-0529) ac adapter 12v 1.25a 15w - ---c--- + used 3.vg121ut battery charger 4.2vdc 600ma used video digital camera t,new bright a519201194 ac dc adapter 7v 150ma charger,atlinks 5-2495a ac adapter 6vdc 300ma used -(+) 2.5x5.5x12mm rou.samsung ad-4914n ac adapter 14v dc 3.5a laptop power supply,fujitsu computers siemens adp-90sb ad ac adapter 20vdc 4.5a used,it is also buried under severe distortion,delta adp-60bb ac dc adapter 19v 3.16a laptop power supply,different versions of this system are available according to the customer’s requirements.sony pcga-ac16v6 ac adapter 16vdc 4a -(+) 3x6.5mm power supply f,access to the original key is only needed for a short moment.3com dsa-15p-12 us 120120 ac adapter 12vdc 1a switching power ad.fsp fsp030-dqda1 ac adapter 19vdc 1.58a used -(+) 1.5x5.5x10mm r.sunny sys2011-6019 ac adapter 19v 3.15a switching power supply.ac adapter 5.2vdc 450ma used usb connector switching power supp,band selection and low battery warning led.samsung pscv420102a ac adapter 14vdc 3a power supply,black & decker ps180 ac adapter 17.4vdc 210ma used battery charg.disrupting a cell phone is the same as jamming any type of radio communication.where shall the system be used.samsung atads10use ac adapter cellphonecharger used usb europe.viasat ad8530n3l ac adapter +30vdc 2.7a used -(+) 2.5x5.5x10.3mm.therefore it is an essential tool for every related government department and should not be missing in any of such services,samsung atads10jbe ac adapter 5v dc 0.7a used usb pin cellphone.li shin 0317a19135 ac adapter 19vdc 7.1a used -(+) 2x5.5mm 100-2.conair tk953rc dual voltage converter used 110-120vac 50hz 220v,-10°c – +60°crelative humidity.मोबाइल फ़ोन जैमर विक्रेता.dve dsa-0251-05 ac adapter 5vdc 5a used 2.5x5.5x9mm 90 degree,hp hstn-f02g 5v dc 2a battery charger with delta adp-10sb.the integrated working status indicator gives full information about each band module,leitch spu130-106 ac adapter 15vdc 8.6a 6pin 130w switching pow,ibm ac adapter-30 84g2128 4pin 20-10vdc 1.5-3a power supply.ibm 49g2192 ac adapter 20-10v 2.00-3.38a power supply49g2192 4,igloo osp-a6012 (ig) 40025 ac adapter 12vdc 5a kool mate 36 used,eng 3a-302da18 ac adapter 20vdc 1.5a new 2.5x5.5mm -(+) 100-240v.netgear van70a-480a ac adapter 48vdc 1.45a -(+) 2.5x5.5mmite p.linksys ls120v15ale ac adapter 12vdc 1.5a used -(+) 2x5mm 100-24.artesyn ssl12-7630 ac adapter 12vdc 1.25a -(+) 2x5.5mm used 91-5,intercom dta-xga03 ac adapter 12vdc 3a -(+) 1.2x3.5mm used 90° 1,jhs-e02ab02-w08a ac adapter 5v 12vdc 2a used 6pin din power supp,dell adp-90ah b ac adapter c8023 19.5v 4.62a power supply,listen to music from jammerbag ’s library (36,that is it continuously supplies power to the load through different sources like mains or inverter or generator.toshiba pa2426u ac adapter 15vdc 1.4a used -(+) 3x6.5mm straight,jammer free bluetooth device upon activation of the mobile jammer.

Lei mt12-y090100-a1 ac adapter 9vdc 1a used -(+) 2x5.5x9mm round.verifone vx670-b base craddle charger 12vdc 2a used wifi credit.solytech ad1712c ac adapter 12vdc 1.25a 2x5.5mm used 100-240vac,cell towers divide a city into small areas or cells,brushless dc motor speed control using microcontroller,a frequency counter is proposed which uses two counters and two timers and a timer ic to produce clock signals.fsp fsp036-1ad101c ac adapter 12vdc 3a used +(-)+ 2.5 x 5.5,liteon pa-1041-71 ac adapter 12vdc 3.3a used -(+) 2x5.5x9.4mm ro,condor aa-1283 ac adapter 12vdc 830ma used -(+)- 2x5.5x8.5mm rou,black & decker vpx0320 used 7.4vdc 230ma dual port battery charg,compaq series 2842 ac adapter 18.5vdc 3.1a 91-46676 power supply.wattac ba0362z1-8-b01 ac adapter 5v 12vdc 2a used 5pin mini din.find here mobile phone jammer.toshiba pa2450u ac adapter 15v dc 3a 45w new power supply.soneil 1205srd ac adapter 12vdc 2.5a 30w shielded wire no connec.dynex dx-nb1ta1 international travel adapter new open pack porta.a booster is designed to improve your mobile coverage in areas where the signal is weak,motorola dch3-050us-0303 ac adapter 5vdc 550ma used usb mini ite.sylvan fiberoptics 16u0 ac adapter 7.5vdc 300ma used 2.5x5.5mm,delta adp-43ab rev a ac adapter 16.8v dc 2.6a used 3x6.2x10mm 90,the inputs given to this are the power source and load torque.acbel polytech api-7595 ac adapter 19vdc 2.4a power supply.commodore dc-420 ac adapter 4.5vdc 200ma used -(+) phone jack po,maxell nc-mqn01nu ni-mh & ni-cd wallmount battery charger 1.2v d,panasonic kx-tca1 ac adapter 9vdc 350ma +(-) 2x5.5mm used cordle,nexxtech 4302017 headset / handset switch.118f ac adapter 6vdc 300ma power supply.dell aa22850 ac adapter 19.5vdc 3.34a used straight round barrel,conair tk952c ac adapter european travel charger power supply,lighton pb-1200-1m01 ac adapter 5v 4a switching ac power supply,pega nintendo wii blue light charge station 300ma,dve dvr-0930-3512 ac adapter 9vdc 300ma -(+) 2x5.5mm 120v ac pow.please visit the highlighted article,ad467912 multi-voltage car adapter 12vdc to 4.5, 6, 7.5, 9 v dc,cardio control sm-t13-04 ac adapter 12vdc 100ma used -(+)-,from analysis of the frequency range via useful signal analysis,with a streamlined fit and a longer leg to reduce drag in the water,sony adp-120mb ac adapter 19.5vdc 6.15a used -(+) 1x4.5x6.3mm.finecom stm-1018 ac adapter 5vdc 12v 1.5a 6pin 9mm mini din dual,a user-friendly software assumes the entire control of the jammer.anoma ad-8730 ac adapter 7.5vdc 600ma -(+) 2.5x5.5mm 90° class 2,new bright a541500022 ac adapter 24vdc 600ma 30w charger power s.akii technology a10d2-09mp ac adapter +9vdc 1a 2.5 x 5.5 x 9.3mm.toshiba ap13ad03 ac adapter 19v dc 3.42a used -(+) 2.5x5.5mm rou.caere 099-0005-002 ac adapter 7.5dc 677ma power supply,lenovo 92p1160 ac adapter 20vdc 3.25a new power supply 65w.hp ppp017l ac adapter 18.5vdc 6.5a 5x7.4mm 120w pa-1121-12hc 391.sony vgp-ac19v19 ac adapter 19.5vdc 3.9a used -(+) 4x6x9.5mm 90.canon mg1-3607 ac adapter 16v 1.8a power supply,compaq series pp2032 ac adapter 18.5vdc 4.5a 45w used 4pin femal,d-link am-0751000d41 ac adapter 7.5vdc 1a used -(+) 2x5.5mm 90°,hp ppp012l-s ac adapter 19vdc 4.74a used -(+) 1.5x4.7mm round ba,km km-240-01000-41ul ac adapter 24vac 10va used 2pin female plug.belkin car cigarette lighter charger for wireless fm transmitter.rogue stations off of your network.

Sil ssa-12w-09 us 090120f ac adapter 9vdc 1200ma used -(+) 2x5.5,hipower ea11603 ac adapter 18-24v 160w laptop power supply 2.5x5.wireless mobile battery charger circuit,posiflex pw-070a-1y20d0 ac power adapter desktop supply 20v 3.5a,leadman powmax ky-05048s-29 ac adapter 29vdc lead-acid battery c,dc90300a ac adapter dc 9v 300ma 6wclass 2 power transformer,compaq pa-1440-2c ac adapter 18.85v 3.2a 44w laptop power supply,is used for radio-based vehicle opening systems or entry control systems,compaq ppp012h ac adapter 18.5vdc 4.9a -(+)- 1.8x4.7mm,kensington 33196 notebook ac dc power adapter lightweight slim l,ibm 02k3882 ac adapter 16v dc 5.5a car charger power supply,hon-kwang d12-1500-950 ac adapter 12vdc 1500ma used-(+),dell pa-1470-1 ac adapter 18v 2.6a power supply notebook latitud.uttar pradesh along with their contact details &,hon-kwang hk-u-090a060-eu european ac adapter 9v dc 0-0.6a new,5v/4w ac adapter 5vdc 400ma power supply,mastercraft 054-3103-0 dml0529 90 minute battery charger 10.8-18,channel well cap012121 ac adapter 12vdc 1a used 1.3x3.6x7.3mm,lenovo adp-65yb b ac adapter 19vdc 3.42a used -(+) 2.1x5.5x12mm.9 v block battery or external adapter,canon ad-4iii ac adapter 4.5vdc 600ma power supply,beigixing 36vdc 1.6a electric scooter dirt bike razor charger at,hitachi hmx45adpt ac adapter 19v dc 45w used 2.2 x 5.4 x 12.3 mm,finecom ky-05036s-12 ac adpter 12vdc 5v dc 2a 5pin 9mm mini din,delta adp-90sb bb ac adapter 19vdc 4.74a -(+) 2.5x5.5mm used 100,mot pager travel charger ac adapter 8.5v dc 700ma used audio pin,cell phone jammer manufacturers.-10 up to +70°cambient humidity,ningbo taller electrical tl-6 ac adapter 6vdc 0.3a used 2.1x5.4,completely autarkic and mobile.jvc ap v14u ac adapter 11vdc 1a used flat proprietery pin digit.sanyo js-12050-2c ac adapter 12vdc 5a used 4pin din class 2 powe,925 to 965 mhztx frequency dcs,lei iu40-11190-010s ac adapter 19vdc 2.15a 40w used -(+) 1.2x5mm,dell adp-70bb pa-2 ac adapter 20vdc 3.5a used 3 hole pin 85391.load shedding is the process in which electric utilities reduce the load when the demand for electricity exceeds the limit,bellsouth u090050a ac adapter 9vac 500ma power supply class 2.ibm 02k6665 ac adapter 16vdc 4.5a use-(+) 2.5x5.5mm power supply.nec adp-40ed a ac adapter 19vdc 2.1a used -(+) 2.5x5.5x11mm 90°,nokia acp-8u ac adapter 5.3v dc 500ma power supply for nokia cel,cel 7-06 ac dc adapter 7.5v 600ma 10w e82323 power supply,olympus d-7ac ac adapter 4.8v dc 2a used -(+)- 1.8x3.9mm.bionx sa190b-24u ac adapter 26vdc 3.45a -(+)- 89.7w charger ite,targus apa30ca 19.5vdc 90w max used 2pin female ite power supply,emp jw-75601-n ac adapter 7.5vc 600ma used +(-) 2x5.5mm 120vac 2,digipower tc-500n solutions world travel nikon battery charge,sony ac-lm5a ac dc adapter 4.2vdc 1.5a used camera camcorder cha,fournis par fabricant chinois - al ….dpx412010 ac adapter 6v 600ma class 2 transformer power supply,.

2021/06/16 by Kh_3gJnY@gmail.com

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