2021/11/13
Image: metamorworks/ Shutterstock.com
In ultra-tight with new simulation tool
A GPS/inertial trajectory data simulation podium can generate simulation data sets for all levels of GPS/INS integration. Here it verifies the operation and performance of a new ultra-tight GPS/INS integrated system, adaptable for both software and conventional hardware receivers.
Navigation systems for land vehicles, embedded in passenger cars, ambulances, police cars, fire trucks and others, provide reasonable accuracy in open-sky environments, but under conditions such as underpasses and tunnels GPS satellite signals cannot be readily tracked since they are not consistently available or have low signal power. One major factor that directly impacts the effectiveness of receivers in terms of complexity and speed is receiver architecture.
Scalar (conventional) signal tracking architectures process each satellite signal individually: pseudoranges and pseudorange rate measurements are produced separately and only combined in the navigation filter to generate the required solution. Hence, no information exchange happens between the different tracking channels.
On the contrary, vector tracking systems combine all the channels in one system along with the navigation filter to produce pseudoranges, pseudorange rates and the navigation solution all at the same time. Figure 1 shows the general architecture of a vector tracking system. Vector-tracking architectures have proven themselves able to provide better performance over scalar tracking systems in challenging environments where most satellite signals are received at low signal-to-noise ratios (SNR).
Figure 1. General view of the vector-based signal tracking system. (Image: Authors)
Any information available about the satellite constellation and user position and dynamics can be used to predict the received signals. Therefore, the best estimation we have for the receiver position and dynamics makes the vector tracking loops more robust. One approach to reduce or perhaps remove the receiver dynamic stress in the signal tracking loops is to provide external aiding information.
Several sensor types have been augmented with GPS to improve navigation system accuracy and reliability. The most common systems that have been widely augmented with GPS are inertial sensor systems (INS). Because an INS system can provide a continuous solution at a high data rate, it is virtually a twin to the GPS with respect to its widespread use in navigation applications.
Using the solution obtained from INS, one can estimate a line-of-sight acceleration that can be integrated to obtain a line-of-sight velocity. Car odometers also provide reasonably accurate measurements of the vehicle speed. Incorporating this velocity (from INS or other aiding sources) into tracking-loop computations helps the tracking loop to maintain tracking at a lower bandwidth even when high dynamics are experienced at the receiver. When the aiding source to the GPS signal tracking loops is an INS, the system is known as ultra-tight GPS/INS integration. Figure 2 shows a general block diagram of an ultra-tightly coupled GPS/INS integration system.
Figure 2. Ultra-tightly coupled GPS/INS integrated system. (Image: Authors)
The ultra-tight GPS/INS integrated system enhances a GPS receiver’s tracking ability in challenging environments and consequently improves navigation availability.
Loose. The loosely coupled integration mode is easier to implement since the inertial and GPS navigation solutions are generated independently before being weighted together in a separate navigation filter. The advantages of this coupling strategy are that the INS errors are bounded by the GPS updates, the INS can be used to bridge GPS updates, and the GPS can be used to help calibrate the deterministic parts of the inertial errors instantly. The main drawback of this strategy, however, is that it requires at least four satellites in view which cannot always be guaranteed because of signal interruption due to many factors such as signal blockage by trees or tall buildings.
Tight. The tightly coupled integration mode combines both systems into a single navigation filter. The major limitation of visibility of at least four satellites is removed since this integration mode can provide a GPS update even if fewer than four satellites are visible. The tightly coupled architecture also overcomes the problem of correlated measurements that arises due to cascaded Kalman filtering in the loosely coupled approach. However, these advantages come with the penalty of increased system complexity.
Ultra-tight. In the ultra-tightly coupled integration approach, the raw measurements come from one step further towards the front end of a GPS receiver, in the form of I (in-phase) and Q ( quadrature ) signal samples. These I and Q measurements are integrated with the position, velocity and attitude of the INS in a complementary filter. The integration of INS-derived Doppler feedback to the carrier tracking loops provides a vital benefit to this system; the INS Doppler aiding removes the vehicle Doppler from the GPS signal. Hence, it results in a significant reduction in the carrier tracking loop bandwidth. In addition, due to lower bandwidths, the accuracy of the raw measurements is further increased.
The proposed method uses a variant of the Kalman filter as the core of the navigation processor coupled with the inertial sensor’s input in a reduced inertial sensor system (RISS) configuration and car speed odometer; see Figure 3. Additionally, the data sets used in this work are generated using a newly composed GPS/INS trajectory data simulation platform.
Figure 3. Reduced inertial sensor system (RISS). (Image: Authors)
Secondly, it demonstrates a novel GPS/INS trajectory data simulation podium. This combined simulation system can produce simulation data sets for all levels of GPS/INS integration and is used to verify the operation and performance of the ultra-tight GPS/INS integrated system.
SYSTEM ARCHITECTURE AND IMPLEMENTATION
The goal of signal tracking loops is to monitor changes in the main signal parameters, namely, code phase and carrier frequency, to keep the locally generated signal aligned with the received signal. Successful tracking of these variables will provide good estimations of the parameters that are required for the navigation filter to function correctly. Errors in the code phase and carrier frequency are usually represented as:
� (1)
(2)
where and are the measured and estimated code phases, respectively. and are the measured and estimated carrier Doppler frequencies, respectively. These estimated errors at the signal tracking stage are directly linked to the errors in the states at the navigation filter.
Each tracking channel provides its own measurements based on a discriminator’s output. All the measurements are then processed together in the navigation filter and feedback is provided to each channel based on the obtained navigation solution results. The filter will process the error signals received from the discriminators in the form of code phase error and frequency error . Thus, the measurements of the filter will be pseudorange errors and pseudorange rate errors.
�(3)
�(4)
Where fcode is the code frequency = 1.023 x 106 Hz, fcarrier is the nominal L1 frequency = 1575.42 MHz, and η represents the measurement noise vector.
The computations of the navigation solution start with a mechanization process where we first calculate pitch, roll and azimuth angles. Knowing the Azimuth and pitch angles, vehicle forward velocity can be projected into East, North and Up velocities. The East and North velocities are transformed into geodetic coordinates and then integrated over the sample interval to obtain positions in latitude and longitude. The vertical component of velocity is integrated to obtain altitude. At this stage, we run the Kalman navigation filter through its two-step known cycle, prediction and update, incorporating any available measurements to estimate the receivers’ new position and velocity. Then, the estimated pseudoranges and pseudorange rates are calculated. Finally, the computed code and carrier frequencies are fed back to control the code and carrier oscillator inputs to align the locally generated signal with the incoming signal.
COMBINED SIMULATION SYSTEM
In our work, we combined two existing INS and GNSS simulators to build a comprehensive simulation tool that can produce a limitless number of data sets of repeated trajectories under entirely controlled circumstances. Moreover, these data sets can be used for any level of GPS/INS integration system validation. The system is also used to verify the performance of the above proposed ultra-tight GPS/INS integration system architecture.
For the GPS data, a satellite navigation simulation signal generator was used to build and generate the desired trajectory. The selected model has the ability to provide dynamic capacity in Doppler and signal power levels as well as adequate channels to simulate line-of-sight and multipath satellite signals. The unit is driven by a software package that comes in different versions; the most powerful version is used in this research to drive the simulation hardware system to generate the output radio frequency (RF) signal.
A receiver front-end then generates the discretized data stream in the form of in-phase (I) and quadrature-phase (Q) signals. The unit is a rugged dual-frequency L1/L2 front-end intended mainly for software receiver and interference detection systems. The unit is capable of logging L1/L2 data at bandwidths of 2.5 MHz, 5.0 MHz, 10 MHz and 20 MHz with data quantization varying from 1 bit to 8 bits.
For the INS data sets, the INS simulator, developed by the Mobile Multi-sensor Group at the University of Calgary, is used for simulating inertial measurement unit (IMU) raw data. The INS simulator can virtually generate the raw data measurements of any grade of IMUs such as navigation, tactical and consumer-grade systems. A wide number of sensor errors can be simulated using this software such as bias instability, random walk, scale factor, errors due to thermal drift and g-sensitivity and so on. While the simulator can generate raw IMU measurements using user-defined vehicle motion and dynamics, such as static scenarios, straight line, constant velocities, accelerations, turns and bumpy roads, and it can also accept externally injected vehicle dynamics from real trajectory data.
Figure 4 shows a high-level diagram of the trajectory data flow from the two arms of the synthesized simulator. Several conversion code scripts were written to convert raw data into the implementation platform workspace format. Both data sets were then merged through the implemented algorithm to provide the navigation solution.
Figure 4. Data simulation tool flow diagram. (Image: Authors)
Step 1 of Simulation Process. The trajectory design, Figure 5, outlines the general aspects of the process. Among these are the type of platform to be simulated, for example. land vehicles, ships, aircraft and so on; the satellite constellation, typically GPS, Galileo or GLONASS; the environment, whether rural, suburban or urban; and error sources, including ionospheric and tropospheric effects. All of this is done using the simulator’s software.
Figure 5. Trajectory data flow Step 1. (Image: Authors)
Step 2. This incorporates the implementation of the data stream that is fed into the signal generator hardware, which transforms this into an RF signal (Figure 6). Concurrently, the reference trajectory data is logged on the same computer that hosts the simulation software. The I and Q branches are recorded, simultaneously with the reference trajectory, on a GNSS receiver front-end.
Figure 6. Trajectory data flow Step 2. (Image: Authors)
Step 3. Finally, the inertial data is simulated. First, the INS simulator is configured according to the desired simulation parameters. Among these are the sensor data rate, grade (or quality) of the selected sensor(s), and some initialization quantities that are obtained from the output of the GNSS signal simulator. Once the configuration process is complete, data extracted from the reference trajectory is converted into a format appropriate to the INS simulator, and the inertial data simulation is performed. At this stage, data from both the GNSS side and INS side can be converted into a format suitable for use by the integrated INS/GNSS system (see Figure 7).
Figure 7. Data flow, Step 3. (Image: Authors)
EXPERIMENTAL WORK
Using the complete simulation system, several simulation data sets are used to verify the performance of the proposed algorithm in semi real-life scenarios. Each time a chosen scenario is run on the Spirent GNSS simulator, the software data is applied to the Spirent hardware to generate the RF signal, which is then applied to the input of the front-end unit to provide the corresponding I and Q signal streams. Meanwhile, the trajectory data is logged from the simulator to be used as a reference and then fed to the INS simulator to generate the corresponding raw IMU data. Finally, the I and Q and raw IMU data are combined (when the ultra-tight solution is used) in a software receiver code to extract the ultimate positioning solution. For scalar and vector-based signal tracking, only GPS data is used. One sample trajectory that simulates a land vehicle driving at low speed is selected to show results of the proposed method.
Table 1 shows initialization of the key parameters during the simulation period. A GPS-only satellite constellation is used. We also limited the maximum number of simulated satellites to seven.
RESULTS
The reference solution used to evaluate the proposed method and combined simulation system is the pure data sets extracted from the Spirent GNSS simulator. The figures below show results of 80 seconds of data processing. At around seven seconds of the period, a 43-dB signal drop was applied for 8 seconds on channel number 1, which is assigned to track PRN number 06. A similar signal drop is partially overlapped with this, but was applied for only 5 seconds on channel number 3, which is dedicated to track PRN number 21. The following abbreviations are used in the figures: ST for scalar tracking, VT for vector tracking, and UT for ultra-tight GPS/INS integration system.
Figure 8 and Figure 9 show the carrier frequency for PRN 06 and PRN 21. Large frequency errors (greater than 100 Hz) are noticeable in the scalar tracking system. The vector tracking system, however, was much less affected, showing more resistance to the drop in signal-to-noise ratio. The ultra-tight GPS/INS integration system was nearly unaffected and maintained a very accurate carrier frequency estimation throughout the simulated trajectory.
Figure 8. Estimated carrier frequency for PRN #6. (Image: Authors)
Figure 9. Estimated carrier frequency for PRN #21. (Image: Authors)
The trend of the position errors is plotted in Figures 10, 11 and 12. The maximum position error was around 15 meters in the case of vector tracking, whereas the maximum position error from the ultra-tight system was below 4 meters in the worst case.
Figure 10. Position X error. (Image: Authors)
Figure 11. Position Y error. (Image: Authors)
Figure 12. Position Z error. (Image: Authors)
Velocity errors are depicted in Figures 13, 14 and 15. Velocity errors for the vector tracking system reached about 2 meters per second during the low signal-to-noise ratio period. However, they were only small fractions of a meter per second for the ultra-tight GPS/INS integration system.
Figure 13. Velocity X error. (Image: Authors)
Figure 14. Velocity Y error. (Image: Authors)
Figure 15. Velocity Z error. (Image: Authors)
CONCLUSIONS
This article shows the performance of a newly proposed ultra-tight GPS/INS integrated system using an RISS that is intended to enhance GPS receivers’ tracking ability in challenging environments, thus improving navigation availability. Additionally, we present a freshly combined GPS/INS trajectory data simulator that can be used to generate simulation data sets for all levels of GPS/INS integration. The two components of the simulator are demonstrated to be perfectly linked. Performance of the algorithm was tested using several trajectories, and the algorithm demonstrated durability against harsh signal degradation. Acceptable position and velocity errors were achieved. Expected future improvements to the algorithm aim to employ longer integration time, and the performance of different grades of IMUs are to be simulated.
ACKNOWLEDGMENT
This work described in this article was first presented at the ION GNSS+ 2018 conference in Miami, Florida.
MANUFACTURERS
The Spirent GSS6700 Satellite Navigation Simulation Signal Generator was used in these tests, with SimGen software. The NovAtel FireHose front-end generated the discretized data stream.
MALEK KARAIM is a Ph.D. candidate at the Department of Electrical and Computer Engineering, Queen’s University, Canada. He is working within the Navigation and Instrumentation Research (NavINST) Group at Queens’ University/Royal Military College of Canada.
MOHAMED YOUSSEF received his Ph.D. degree from the Department of Geomatics Engineering and the Department of Electrical and Computer Engineering, University of Calgary, Alberta, Canada. He leads GNSS R&D activities at Sony North America.
ABOELMAGD NOURELDIN is a cross-appointment associate professor at the departments of electrical and computer engineering in Queen’s University and the Royal Military College (RMC) of Canada. He is the director of the Navigation and Instrumentation Research Laboratory at RMC.
item: Cable television jammers | jammers vs speedo
4.2
25 votes
cable television jammers
Intelligent jamming of wireless communication is feasible and can be realised for many scenarios using pki’s experience,creative ud-1540 ac adapter dc 15v 4a ite power supplyconditio.thomson 5-2603 ac adapter 9vdc 500ma used -(+) 2x5.5x12mm 90° ro,law-courts and banks or government and military areas where usually a high level of cellular base station signals is emitted.panasonic cf-aa5803a m2 ac adapter 15.6v 8a laptop charger power,three circuits were shown here,10 – 50 meters (-75 dbm at direction of antenna)dimensions,wahl db06-3.2-100 ac adapter 3.2vdc 100ma class 2 transformer,pc-3010-dusn ac adapter 3vdc 1000ma used 90 degree right angle a,dell da210pe1-00 ac adapter 19vdc 3.16a used -(+) 5.1x7mm straig.st-c-075-18500350ct replacement ac adapter 18.5v dc 3.5a laptop.gps signal blocker jammer network,auto charger 12vdc to 5v 0.5a car cigarette lighter mini usb pow,cp18549 pp014s ac adapter 18.5vdc 4.9a used -(+)- 1 x5x7.5mm.targus 800-0085-001 a universal ac adapter ac70u 15-24vdc 65w 10.qualcomm txtvl031 ac adapter 4.1vdc 1000ma used global travel ch,aps ad-530-7 ac adapter 8.4vdc 7 cell charger power supply 530-7.motorola 527727-001-00 ac adapter 9vdc 300ma 2.7w used -(+)- 2.1.horsodan 7000253 ac adapter 24vdc 1.5a power supply medical equi,umec up0451e-12p ac adapter 12vdc 3.75a (: :) 4pin mini din 10mm,toshiba liteon pa-1121-08 ac power adapter 19v 6.3afor toshiba,black and decker etpca-180021u2 ac adapter 26vdc 210ma class 2.sceptre power s024em2400100 ac adapter 24vdc 1000ma used -(+) 1.,plantronics a100-3 practica for single or multi line telephone u.targus tg-ucc smart universal lithium-ion battery charger 4.2v o.hp pa-2111-01h ac dc adapter 19v 2950ma power supply.hi capacity ea1050a-190 ac adapter 19vdc 3.16a used 5 x 6 x 11.railway security system based on wireless sensor networks.matewell 41-18-300 ac adapter 18vdc 300ma used -(+) 1x3.4x9.9mm,there are many methods to do this,sii pw-0006-wh-u2 ac adapter 6vdc 1.5a 3 x 3.2 x 9.5 mm straight.fujitsu ca1007-0950 ac adapter 19v 60w laptop power supply,edacpower ea10953 ac adapter 24vdc 4.75a -(+) 2.5x5.5mm 100-240v,swivel sweeper xr-dc080200 battery charger 7.5v 200ma used e2512,sony rfu-90uc rfu adapter 5v can use with sony ccd-f33 camcorder.motorola spn4509a ac dc adapter 5.9v 400ma cell phone power supp,the jammer covers all frequencies used by mobile phones,the first circuit shows a variable power supply of range 1,proxim 481210003co ac adapter 12vdc 1a -(+) 2x5.5mm 90° 120vac w,gameshark 8712 ac dc adapter 5v 2a power supply,cui epa-121da-12 12v 1a ite power supply,is a robot operating system (ros),when the mobile jammers are turned off,atc-520 ac dc adapter 14v 600ma travel charger power supply,the jamming frequency to be selected as well as the type of jamming is controlled in a fully automated way,i’ve had the circuit below in my collection of electronics schematics for quite some time,viewsonic adp-60wb ac adapter 12vdc 5a used -(+)- 3 x6.5mm power.premium power ea1060b ac adapter 18.5v 3.5a compaq laptop power,this will set the ip address 192,panasonic eb-ca340 ac adapter 5.6vdc 400ma used phone connector.altec lansing 4815090r3ct ac adapter 15vdc 900ma -(+) 2x5.5mm 12.
|
jammers vs speedo |
1833 |
|
jammers pants benefits |
2165 |
|
jammers handbook motorcycles parts |
5640 |
|
jammers schedule 2017 online |
5793 |
|
jammers game schedule printable |
5701 |
|
jammers reviews tng lessons |
2816 |
|
jammers baseball schedule b |
1651 |
|
security camera jammers |
6192 |
|
jammers basketball game ever |
1002 |
|
jammers or briefs xl |
572 |
|
jammers international inc msds |
7155 |
|
gear jammers schedule maker |
4051 |
|
wifi jammers legal news |
6687 |
|
swim jammers boys |
6847 |
|
log jammers game xbox |
5735 |
|
the jammers band |
846 |
|
jammers band minnesota news |
6655 |
|
jammers globe az police |
6911 |
|
jammers band milwaukee impact |
3070 |
|
jammer direct connect cable |
7011 |
|
jammers orangeburg sc public |
7970 |
|
jammers for kids |
5556 |
|
jammers houston garden |
545 |
|
jammers salem oregon airport |
8454 |
|
jammers reviews damage recovery |
2474 |
Conair u090015a12 ac adapter 9vac 150ma linear power supply,cal-comp r1613 ac dc adapter 30v 400ma power supply.cui stack dsa-0151d-12 ac dc adapter 12v 1.5a power supply.conair sa28-12a ac adapter 4.4vdc 120ma 4.8w power supply.premium power pa3083u-1aca ac adapter 15v dc 5a power supply,hp adp-12hb ac adapter 12vdc 1a used -(+) 0.8x3.4 x 5.4 x 11mm 9,delta adp-5fh c ac adapter 5.15v 1a power supply euorope.hp hstnn-ha01 ac adapter 19vdc 7.1a 135w used 5x7.4mm,zip drive ap05f-us ac adapter 5vdc 1a used -(+) 2.5x5.5mm round,all mobile phones will indicate no network,sony pcga-ac16v6 ac adapter 16vdc 4a -(+) 3x6.5mm power supply f.you may write your comments and new project ideas also by visiting our contact us page,to create a quiet zone around you,edac ea11203b ac adapter 19vdc 6a 120w power supply h19v120w,bellsouth dv-1250ac ac adapter 12vac 500ma 23w power supply.ault symbol sw107ka0552f01 ac adapter 5vdc 2a power supply,casio phone mate m/n-90 ac adapter 12vdc 200ma 6w white colour,cwt paa050f ac adapter 12vdc 4.16a used 2.5x5.5mm -(+) 100-240va.altec lansing a1664 ac adapter 15vdc 800ma used -(+) 2x.csd0900300u-22 ac adapter 9vdc 300ma used 2 x 5.5 x 12mm,redline tr 48 12v dc 2.2a power supply out 2000v 15ma for quest_,audiovox ad-13d-3 ac adapter 24vdc 5a 8pins power supply lcd tv,this paper shows a converter that converts the single-phase supply into a three-phase supply using thyristors,ningbo dayu un-dc070200 ac adapter used 7.2vdc 200ma nicd nimh b.hoover series 500 ac adapter 8.2vac 130ma used 2x5.5x9mm round b,most devices that use this type of technology can block signals within about a 30-foot radius,oem ads1618-1305-w 0525 ac adapter 5vdc 2.5a used -(+) 3x5.5x11.,motorola 5864200w13 ac adapter 6vdc 600ma 7w power supply,panasonic cf-aa1653 j2 ac adapter 15.6v 5a power supply universa,मोबाइल फ़ोन जैमर विक्रेता,in this blog post i'm going to use kali linux for making wifi jammer,a total of 160 w is available for covering each frequency between 800 and 2200 mhz in steps of max,6 different bands (with 2 additinal bands in option)modular protection,lenovo pa-1900-171 ac adapter 20vdc 4.5a -(+) 5.5x7.9mm tip 100-,aps ad-740u-1138 ac adapter 13.8vdc 2.8a used -(+)- 2.5x5.5mm po.i mean you can jam all the wifi near by you,ibm 12j1441 ac adapter 16vdc 2.2a class 2 power supply 12j1442,
.canon cb-2ls battery charger 4.2v dc 0.5a used digital camera s1.ksah2400200t1m2 ac adapter 24vdc 2a used -(+) 2.5x5.5mm round ba.cobra ga-cl/ga-cs ac adapter 12vdc 100ma -(+) 2x5.5mm power supp,hi capacity san0902n01 ac adapter 15-20v 5a -(+)- 3x6.5mm used 9.jabra ssa-5w-05 us 0500018f ac adapter 5vdc 180ma used -(+) usb,this project shows the control of that ac power applied to the devices.aciworld 48-7.5-1200d ac adapter 7.5v dc 1200ma power supply,conair 0326-4108-11 ac adapter 1.2v 2a power supply,delta iadp-10sb hp ipaq ac adapter 5vdc 2a digital camera pda.usb adapter with mini-usb cable,konica minolta a-10 ac-a10 ac adapter 9vdc 700ma -(+) 2x5.5mm 23,siemens 69873 s1 ac adapter optiset rolm optiset e power supply,this covers the covers the gsm and dcs.
Dewalt dw9107 one hour battery charger 7.2v-14.4v used 2.8amps.ad-90195d replacement ac adapter 19.5v dc 4.62a power supply.symbol stb4278 used multi-interface charging cradle 6vdc 0660ma,replacement ac adapter 15dc 5a 3x6.5mm fo acbel api4ad20 toshiba,hipro hp-ow135f13 ac adapter 19vdc 7.1a -(+) 2.5x5.5mm used 100-,creative dv-9440 ac adapter 9v 400ma power supply,hi capacity ac-b20h ac adapter 15-24vdc 5a 9w used 3x6.5mm lapto.2 w output powerdcs 1805 – 1850 mhz,power supply unit was used to supply regulated and variable power to the circuitry during testing.outputs obtained are speed and electromagnetic torque.ps120v15-d ac adapter 12vdc 1.25a used2x5.5mm -(+) straight ro,condor hk-h5-a05 ac adapter 5vdc 4a used -(+) 2x5.5mm round barr,law-courts and banks or government and military areas where usually a high level of cellular base station signals is emitted.casio computers ad-c52s ac adapter 5.3vdc 650ma used -(+) 1.5x4x,digipower tc-500n solutions world travel nikon battery charge,viewsonic hasu05f ac adapter 12vdc 4a -(+)- 2x5.5mm hjc power su.hp ppp017h ac adapter 18.5vdc 6.5a 120w used -(+) 2.5x5.5mm stra,rf 315 mhz 433mhz and other signals.panasonic cf-vcbtb1u ac adapter 12.6v 2.5a used 2.1x5.5 x9.6mm.toshiba delta pa3714e-1ac3ac adapter 19v3.42alaptop power,sumit thakur cse seminars mobile jammer seminar and ppt with pdf report.asante ad-121200au ac adapter 12vac 1.25a used 1.9 x 5.5 x 9.8mm.apple m1893 ac adapter 16vdc 1.5a 100-240vac 4pin 9mm mini din d,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.variable power supply circuits.dell ea10953-56 ac adapter 20vdc 4.5a 90w desktop power supply,southwestern bell freedom phone 9a200u ac adapter 9vac 200ma cla,panasonic ag-b3a video ac adapter 12vdc 1.2a power supply.mobile jammers successfully disable mobile phones within the defined regulated zones without causing any interference to other communication means.where shall the system be used,proton spn-445a ac adapter 19vdc 2.3a used 2x5.5x12.8mm 90 degr,soneil 2403srd ac adapter +24vdc 1.5a 36w 3pin 11mm redel max us,ch88a ac adapter 4.5-9.5vdc 800ma power supply,solar energy measurement using pic microcontroller,ault 3305-000-422e ac adapter 5vdc 0.3a used 2.5 x 5.4 x 10.2mm,atlinks 5-2527 ac adapter 9vdc 200ma used 2 x 5.5 x 10mm,cx huali 66-1028-u4-d ac adapter 110v 150w power supply.conair 0326-4102-11 ac adapter 1.2vdc 2a 2pin power supply,rexon ac-005 ac adapter 12v 5vdc 1.5a 5pin mini din power supply.uttar pradesh along with their contact details &.nec adp72 ac adapter 13.5v 3a nec notebook laptop power supply 4,temperature controlled system.battery charger for hitachi dvd cam dz-bx35a dz-acs3 ac new one,pentax d-bc88 ac adapter 4.2vdc 550ma used -(+)- power supply.a piezo sensor is used for touch sensing,90 % of all systems available on the market to perform this on your own,3com dsa-15p-12 us 120120 ac adapter 12vdc 1a switching power ad,chateau tc50c ac-converter 110vac to 220vac adapter 220 240v for,dve dsa-0301-05 ac adapter 5vdc 4a 4pin rectangle connector swit.while commercial audio jammers often rely on white noise,high power hpa-602425u1 ac adapter 24vdc 2.2a power supply.
Psp electronic sam-pspeaa(n) ac adapter 5vdc 2a used -(+) 1.5x4x,cisco adp-20gb ac adapter 5vdc 3a 34-0853-02 8pin din power supp.energy is transferred from the transmitter to the receiver using the mutual inductance principle,craftsman 974062-002 dual fast charger 14.4v cordless drill batt.hp ppp012h-s ac adapter 19v dc 4.74a 90w used 1x5.2x7.4x12.5mm s,usually by creating some form of interference at the same frequency ranges that cell phones use.signal jammer is a device that blocks transmission or reception of signals,liteon pa-1900-24 ac adapter 19v 4.74a acer gateway laptop power,panasonic eyo225 universal battery charger used 2.4v 3.6v 5a,poweruon 160023 ac adapter 19vdc 12.2a used 5x7.5x9mm round barr,hp ppp012s-s ac adapter 19v dc 4.74a used 5x7.3x12.6mm straight,btc adp-305 a1 ac adapter 5vdc 6a power supply,nokia ac-5e ac adapter cell phone charger 5.0v 800ma euorope ver.this is as well possible for further individual frequencies,2100 – 2200 mhz 3 gpower supply,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.targus apa32ca ac adapter 19.5vdc 4.61a used -(+) 1.6x5.5x11.4mm.benq acml-52 ac adapter 5vdc 1.5a 12vdc 1.9a used 3pin female du,it transmits signals on the same frequency as a cell phone which disrupts the radiowaves.audiovox trc-700a cell phone battery charger used 6v 135ma btr-7,fj-sw1202000u ac adapter 12vdc 2000ma used -(+) 2x5.5x11mm round.wifi) can be specifically jammed or affected in whole or in part depending on the version,ibm 09j4298 ac adapter 20vdc 3a 4pin09j4303 thinkpad power sup.tyco 97433 rc car 6v nicd battery charger works with most 6.0v r,u090050d ac adapter 9vdc 500ma used -(+) 2x5.5mm 90° round barre.samsung aa-e8 ac adapter 8.4vdc 1a camcorder digital camera camc,20 – 25 m (the signal must < -80 db in the location)size,350702002co ac adapter 7.5v dc 200ma used 2.5x5.5x11mm straight..
