Phone jammer 184 parts , phone network jammer splash

The design and verification of a new class of portable wideband record-and-playback system considers the relative merits and limitations of both simulator and record/replay approaches. The authors also discuss the benefits of the different test approaches to the development and characterization of various GNSS receiver types. By Steve Hickling and Tony Haddrell As new GNSS systems become available, and users take receivers to ever more challenging environments, the need for repetitive and repeatable testing during development grows ever stronger. Simulators have traditionally demonstrated performance and repeatability in the laboratory environment, and this approach remains the only option for planned signals not yet broadcast from space. However, this approach is becoming more complex as the number of GNSS signals and their reception environments increase. Another way of testing receivers is through field trials. This allows investigation of conditions difficult to simulate, such as multiple reflections and interferers. These environments, however, are time-varying, and thus not repeatable in the true sense. Therefore, proper comparisons can only be made by assessing all competing receivers in the same trial, and any performance anomalies seen cannot necessarily be tracked down by returning to the same location at some point in the future. Furthermore, developers would like to see for themselves any such anomalies and try to understand and correct them, but it is not always desirable or practical (and certainly not economical) to put development engineers in locations scattered all over the globe. To tackle this problem, GNSS signal record-and-replay capability is gaining acceptance as a practical tool for recording a signal environment at a single point in time and replaying at will. In real terms this means a device must receive the radio signals from the GNSS satellites, reduce them to a form suitable for storage, and then recreate signals from the stored data in a manner that makes them look completely real to any receiver under test or development. Some receiver manufacturers developed their own capability to do this. Early devices were of necessity restricted in the signals they could handle and store, limited both by budget and available technologies. The basic problems are the amount of data to be stored in real time and the ability to recover it in real time. Even the GPS L1-only low bandwidth C/A code requires at least 2 Mbytes per single second of recording, or more than 100 Mbytes per minute. Fortunately, with digital storage technology advances, we can now make use of higher storage capacities (1 TByte of storage is readily available at reasonable cost) and also higher write/read bandwidths (100 MBytes per second is realistic). All we need is some hardware and a processor that can handle the data rates. Once we have our wanted signals reduced to some form of digital representation, we can simply store and retrieve them at will, handling the recordings as simple, if somewhat large, data files. This allows file distribution between equipments, and a split between making the recording in the field and replaying it in the laboratory. In fact, many manufacturers have dedicated field recording teams who send the files back to the engineers interested in the signal environments. Replaying the signals is in some ways similar to generating simulated signals. In both cases, the starting point is digital data, on the one hand recorded in the field, on the other hand calculated by mathematical algorithms using the scenario specified in the simulator. In both cases the signal is created by generating radio frequency (RF) carriers and modulating them according to the GNSS signal formats. Contrast of Two Approaches. None of the characteristics of the record/replay device replace the functionality of the simulator; in fact, both are valid tools for development and testing. For instance, it is not possible with a record/replay device to manipulate individual satellite signals, nor to introduce specific errors in the radio signals. Equally, it is not really possible with a simulator to recreate a particular physical environment made up of many reflected signals, jammers, manmade noise, and moving scenery. With a simulator, the user has control over the power of the received satellite signal, whereas in the recorder the entire signal-to-noise ratio observed at the point of reception has been recorded, and the user can only control the amplitude of the entire noise plus signal. Permanent Signal Monitoring One other aspect of raw signal recording lies outside the receiver testing topic, but is of interest for GNSS signal monitoring. It uses the ability to record GNSS signals all of the time, in this case from a good signal environment, and then to retain any time spans where an anomaly in the signals has been detected by a monitor receiver. This is comparable to recording security CCTV pictures, where we expect nearly all of the resulting files to be redundant, but can retain the interesting bits to replay over and over for further analysis. For example, if it is known that a given timing receiver installation suffers periodic loss of lock, it is possible to make a recording using the loss of lock to signpost the interesting region in much the same way as a reverse trigger on an oscilloscope. Limitations and Compromises The sheer function of recording GNSS signals off-air has some built-in limitations. First, the signal recorded represents only a snapshot of the environment, although numerous recordings can be made at, say, busy and quiet times, day and night, etc. This is really a reversal of the “non repeatability” aspect of measuring performance in a particular location. In the recording sense, we only get repeatability, with no guarantee that the scenario captured represents worst case conditions. Thus, going back to the location in the future may or may not provide similar results. In addition to this, there are some signal processing aspects that limit the fidelity of the replayed signals. The first is that any recorder must have an external GNSS antenna and a GNSS receiver front-end built in, and this combination will receive both the satellite signals and thermal noise. The level of the noise is much higher than that of the signals if we don’t do any correlation related processing, and the receiver will contribute some more noise of its own (the noise figure of the system). The second aspect is that in downconverting the radio signals to a usable frequency for sampling and storage, the recorder must use some frequency reference of its own, which will contribute some frequency uncertainty and some phase noise (or jitter on the frequency). The final aspect is the digitization of the downconverted signal to get it into a suitable form for manipulation and storage. Since we are essentially sampling noise here (with the GNSS signal buried in it) we need to look at fidelity in reproduction of the noise during playback, and the effect of any signal (a jammer or interferer) that is above the amplitude of the noise. In analyzing this last aspect, we may include the effect of any automatic gain control (AGC) used to present the correct amplitude signal to the analog to digital (A2D) converter. A New Simulation Requirement We wanted to create a much more comprehensive and flexible device than hitherto available, going part way towards the much more general (and expensive) instrumentation recorders that are currently the only alternative. The requirement is for a flexible, self-contained device that can be easily carried or transported for recording purposes, so having an internal battery and built-in control functionality, and simultaneously a device that fits neatly into a networked and externally controlled laboratory environment. The first approach was to cover all of the possible GNSS frequency bands, although as more are added with time, we realized that this needed to be moderated somewhat. So the product covers L1, L2, L5 and their derivatives for the differing GNSS systems GPS, GLONASS, Galileo, and BeiDou, and also the Inmarsat commercial band to cover the proprietary augmentation signals used by many high-accuracy receivers (see Figure 1, red outlines). FIGURE 1. Frequency bands, outlined in red, supported by the new record-and-replay device. The next decision was what bandwidths to allow at each frequency, and how much of this bandwidth could be covered at once. The limitations here are driven by the data storage requirements of the signals being recorded, and the speed that they can be written to disk. The resulting solution allows bandwidths (BW) of up to 30 MHz at each frequency, and any three such bandwidths to be recorded at once. Physically, this is implemented with three channels with the ability to record any of the available frequencies or bandwidths. The user has, therefore, flexibility to set up recording for his particular needs, which may be just L1 covering BeiDou, GPS, Galileo, and GLONASS, or an L1,L2,L5, combination for a survey type application. Of course, there are always requests for more capability, and we envisaged early on the ability to stack two devices to give six channels of 30-MHz BW for recording, say, GPS/Galileo and GLONASS at L1, GPS and GLONASS at L2, Galileo/GPS at L5, and an Inmarsat data carrier. See later for how this is achieved. The whole product has to fit in a portable box with enough battery power for more than one-hour field campaigns, and also be capable of running from mains or vehicle power. The associated antenna needs to cover all of the frequency bands. Figure 2 shows the end result in its standalone configuration. Figure 2. Portable solution for recording. One additional requirement was placed upon the design, and that is the ability to record and replay non-GNSS data simultaneously with the GNSS signals, and reproduce them, if desired, in synchronism with the replayed signals. This allows time ticks, events, assistance data, sensor data, or even video to be stored and replayed along with the raw signals. Architecture and Implementation The new record-and-replay device uses a fast computer running the Linux operating system as its control center and storage/retrieval engine. Dedicated hardware is used to format or recover the raw data, and this has access directly to the computer bus to minimize the delays in writing or reading the mass storage, which in this case is a solid state hard drive (SSD). The overall architecture is shown in Figure 3. Figure 3. Concept-level architecture. The signal recording capability hinges around the RF planning, which has the task of supplying the necessary flexibility without adding more than minimal signal degradation. For the RF functionality, the device contains a broadband front end and a three-channel RF amplifier (L1, Imarsat, and L2/L5), filtering the signal down to reasonable bandwidths for later downconversion. Three independent channels of downconversion to baseband I and Q analog signals have access to any of the RF channels and are based upon satellite TV technology architectures. The downconverters have baseband filters that can be commanded to a desired bandwidth by the control processor. This allows the use of narrower bandwidths where possible, allowing more recording time for a lower sampling rate. The baseband signals are sampled at 10 MHz or 30 MHz, paying attention to the Nyquist requirements for pre-digitisation filtering. Two bits for each of the I and Q signals are utilized for packing into the recorded file format. Figure 4 shows the arrangement. Figure 4 . The RF architecture. At this stage any additional synchronous data to be recorded, such as truth or assitance data, is inserted into the bit stream, and the data from all the channels in use is combined in a pre-determined format. Dedicated hardware is used for this, and large data buffers are provided to alleviate bottlenecks in sending data to the disks. Each file has an associated definition in a header, and contains synchronization data to allow the device to set up the replay path and recover the data bits in order to reproduce whatever combination was recorded. Note that resulting data files are given the same extension, regardless of content. Data files can be very big (at maximum bandwidth we record about 2.7 Gbytes per minute) and may be difficult to handle once recorded. To assist with this, the device has a second, removable SSD on board, allowing recorded files to be simply popped out of the caddy and shared with another device, or even mailed or couriered. The RF path for the replay consists again of three independent channels, able to generate any of the supported frequencies and modulate upon them the original signals recovered from the stored file. Once again, dedicated hardware and large buffers are needed to unpack the files and send the RF data to the correct channels or to the synchronous data outputs in the case of recorded digital data, as determined by the file header. The data representing the recorded RF is converted back to analog form and filtered before being applied to modulators which regenerate the original channelized signals. Each channel has a programmable attenuator to “level” the amplitude, and the three channels are then combined together before passing through a common attenuator to provide user control over the replayed carrier to noise ratio (C/N0). Figure 5 shows the upconverter arrangement. Figure 5. An upconverter channel. All frequencies created within the device need to be traceable to a common reference. In addition, this reference needs to be at least as good as the reference in any receiver to be tested, since both its offset from true frequency and its rates of change will be superimposed on the replayed data. Many commercial-grade GNSS receivers (such as those used in mobile phone) are specifically designed to cope with poor oscillators, for instance a low-grade temperature controlled crystal oscillator (TCXO), whereas more professional receivers may expect a couple of orders of magnitude better performance. We decided, therefore, to include an ovenized oscillator (OCXO) for use both in record and playback modes. One challenge presented by this decision is that the oven is necessarily thirsty for power, and therefore a bigger battery is needed than would otherwise be the case. The OCXO used is a 10.23-MHz component, thus allowing direct generation of the wanted GNSS frequencies using integer ratios and avoiding as much phase noise as possible in the various RF channels. A dedicated phase locked loop (PLL) generates a reference for output to other devices, and a 10-MHz input connector is provided to lock the OCXO to an external reference. These capabilities are utilized when combining two such devices, since we must have the same frequency reference in each. Apart from locking the two oscillators together, this configuration also needs time synchronization between the sampling in both devices, and this is achieved via an additional cable connected between the accessory connectors. Once time and frequency synchronized, the devices behave as a single six-channel unit, using external RF splitter/combiners for the RF connections. Design Challenges RF Total Bandwidth. The GNSS bands covered by the device range from the L5 band to the GLONASS L1 band, a total range of 480 MHz allowing for signal bandwidths. Table 1 shows the relevant bands. Whilst the RF front end must be wide open to this range, assuming the use of a single RF input port, it is obviously necessary to provide bandwidth narrowing by filtering as soon as possible, to exclude jammers or carriers using the space between the GNSS bands, and to avoid the sheer noise power overwhelming the RF circuits. Examination of the supported GNSS services shows them essentially packed into two clusters of frequencies, which provide a convenient way of filtering down the RF input into two RF “channels.” This gets the total bandwidth down to about 180 MHz. Figure 1, the opening graphic for this article, shows the groupings. Beidou B3 and Galileo E6 are currently out of scope for this product, but will be supported in a later version. The Inmarsat-supported signals are assigned their own RF path, since their structure is data modulated carriers, usually with low SNR. Elsewhere in the Inmarsat band there are more powerful carriers supporting comms traffic, which can “grab” the AGC and therefore cause loss of SNR during the digitization process. Hence this band is processed though its own RF path, maintaining as low a bandwidth as possible consistent with the frequency allocations of the various (proprietary) GNSS augmentation data carriers. Tradeoffs. Throughput of the recording or replay paths is the performance limitation of the current architecture. Thus a lot of discussions and simulations concerning possible bandwidth, sampling rates, and bit depth tradeoffs was undertaken at the outset of the design. In addition, we needed to decide whether to sample signals at an IF frequency or at baseband. Trials were conducted to determine the real rates of disk access, which are different to the often quoted write and read speeds of computer interfaces. The results of the trials and simulation led us to adopt a maximum average data rate to/from the storage system of 50 Mbytes/second, this being shown to be available over a period of many hours. Actually, at this rate we fill up a 1-Tbyte disk in about five hours. To service the GNSS signal bandwidths of interest, again there are two groups of signals. This time we are looking at either the commercial signals (“open service signals” in some systems’ parlance) used by consumer-type receivers, which are relatively narrow band, and the military, high-accuracy, or resilient signals of interest to surveying and precision applications. Therefore, we offer two sampling rates, approximately 10 and 30 MHz, to avoid building large files where more than half of the bandwidth was of no interest to the user. Next, we have to look at bit resolution. Given that we have generally a noise-like signal with Gaussian characteristics, if we were looking at digitizing at an intermediate frequency (IF), it can be shown that a 2-bit analog-to-digital converter (A2D) would be sufficient to keep the digitization losses to less than 1dB. Obviously, the fewer number of bits we need to store the better, commensurate with achieving the performance targets. Frequency planning for all of the possible frequencies and bandwidths of interest is a complex task. The requirement here was to downconvert each signal of interest to a low IF suitable for digitizing, whilst having control of the bandwidth to eliminate unwanted signals and fulfill the Nyquist criterion. In addition, we wanted each channel to be isolated from the others even when the replay path involving the generation of the IF carriers was considered. We therefore decided to downconvert to baseband for each channel, to avoid cross-contamination via the various IFs that would have to be generated for replay. In other words, we adopted an IF of zero Hz. This in turn means that the final bandwidth-determining filters are at baseband, and can readily be controlled by software means rather than having to switch RF paths. By downconverting into quadrature baseband channels, all stored signals are at the same (zero) IF, and crosstalk and imaging during upconversion is avoided. Thus the A2D architecture of 2 bits in the inphase (I) and 2 bits in the quadrature (Q) arms of the downconverted signal was adopted. Doing the calculation in terms of stored data, we see that we can operate three channels inside our target storage bandwidth, with a margin left for other features such as storing video at the same time. For 30M samples per second (SPS), each channel has 4 bits or 0.5 bytes Therefore, for three channels the storage bandwidth is 0.5 * 3 * 30 MSPS, or 45 Mbytes/s To keep the optimum A2D characteristics, the AGC is designed to adjust the signal amplitude at the converter to give a Gaussian response to the four states determined by the two bits in each arm. The AGC operates independently in each channel. Figure 6 shows the final architecture for the device in block diagram form. Figure 6. Final architecture. Real-Time Data Handling. Storage and retrieval of the digitized signals is carried out by dedicated hardware connected to the RF downconverter, the playback upconverter, and the main computer that “owns” the storage media. Large buffers allow the storage media to lag (record) and lead (playback) the real-time signals in time, and to take short breaks for housekeeping functions. Data is packed into a binary file according to a pre-determined sequence, which in turn is set by the number of channels and bandwidths in use. A file header is generated which contains all of the information necessary for reconstructing the data streams for replay. A synchronization sequence is added at the start of the file to allow recovery of the correct bits for each channel and each baseband quadrature arm, and to the correct timeslots for each component. Destroying the correct time reproduction is the most likely issue to cause faulty replay in any record/replay device. GNSS receivers don’t like discontinuous or slewing time! This approach also allows the insertion of external digital data into the file. Providing the data processing hardware is aware of the individual bits into which this data is placed, digital data recorded at the same time as the raw signals may be regenerated synchronously during replay. Thus any data that is applied to a receiver in a real time trial can be available for the same trial any time after the event. Two streams of synchronous data can be recorded per channel potentially making six serial data streams per chassis available. User Interfaces A final challenge presents itself in the case of user interfaces. Although the operational options of the device are quite complex, there is a requirement to be able to capture field data with just the equipment itself and any necessary antenna setup. Consequently, the product has a display and control keys implemented on the front panel, allowing the user comprehensive access to the internal functions using a menu system and scrolling displays. Alternatively, for operation in a lab environment, a network connected user interface is specified, and this requirement is supported by a webserver running on the main processor in the device. Thus, simply opening a web browser and connecting to the device’s IP address allows full functional control. In addition, connecting a mouse, keyboard, and monitor to the device allows access to the main processor, allowing the running of scripts thus providing full control of replays and receiver functions for running continuous tests in an automated laboratory environment. Using this approach, receiver modifications can be tested over many scenarios and locations many times each, to provide statistically relevant results, without taking up operator time. Remote monitoring is possible using the webserver. Performance Testing A range of tests and trials have been carried out to verify that the product meets its specifications, and to measure the performance in a number of real life scenarios. Repeatability, Degradation, Attenuation. The first and most obvious thing to explore is the effect of the record and playback on signal-to-noise ratio. Since the RF circuits add some noise to the signal recorded, we would expect some degradation to take place here. Also, during replay, the receiver under test adds more noise, depending on its noise figure, although this should be the same as would be added when using “live” signals. Many receivers adjust for their noise figure when reporting C/N0 numbers (C/N0 is a signal to noise measurement normalized to a 1-Hz bandwidth and is the standard reported measurement for most GNSS receivers). However, by replaying back the recorded signal and noise at a higher level than would have been received in “live” conditions, we can eliminate almost all of the degradation. In live versus replayed tests for individual satellites using a JAVAD receiver, which allows us to test all of the supported bands and constellations, we found that replay is possible within ±1 dB of the original live signals. Replayed signals were about 10 dB above the original recorded level to achieve this, effectively swamping the receiver’s noise contribution. An interesting aspect of controlling the C/N0 this way is the ability to attenuate the replayed signal and, therefore, increase the contribution of the test receiver’s noise figure. Thus, although the recorded C/N0 hasn’t changed, we can attenuate the replay level and use the receiver to add noise. This process is not linear, and we obviously have to remove nearly all of the 10-dB excess to get started. The device keeps a table of attenuation vs C/N0 reduction, allowing the user to simply dial up the required C/N0 loss. Since this depends on the receiver noise figure, effects may differ slightly from receiver to receiver. Usefully the table is user definable allowing tailoring to a specific receiver. Losses from Phase Noise, Other Factors. This category of degradation is more difficult to quantify, since the effects are on tracking and therefore range and phase measurement rather than signal to noise ratio. One way of looking at this is, therefore, to establish the positioning performance during live and replayed sessions, and measure the differences. This has some complexity, though, since putting the same signals into a receiver multiple times yields differing performance each time, meaning that we have to use some statistical analysis. Of course this isn’t possible on live signals, and is one reason why repeatable replayed signals are so important in developing GNSS receivers. Another aspect is the fact that some of the effects are differential among frequency bands (filter delays, for instance) and across bands as well (group delay) and also occur in the receiver under test, which will have been calibrated to mitigate its own contribution. Figure 7 shows a comparison of static positioning for live and replayed signals using only GPS L1 and a 10-MHz sampling rate with an ST-Ericsson receiver, whilst Figure 8 is from a JAVAD receiver using all possible signals in live mode and GPS L1/L2 and GLONASS L1 in replay. In both cases the degradation is within 1 meter always, and much less than this when statistically analyzed. Figure 7. Static position GPS L1 comparison: live left, replayed right. Figure 8. GPS L1/ L2 with GLONASS L1 comparison. Another opportunity to measure the effects is to run a zero baseline phase solution, whereby the receiver is used as the “base station” when receiving live signals which are simultaneously recorded. During replay, the same receiver is used as the “rover” with RTK corrections coming from the previously captured live session. In this setup, therefore, we are really only measuring differences in the replayed and live signals, and the usual measurement limitations of the receiver. Figure 9 shows the results of one such test, with the pseudorange and carrier phase residuals plotted. This was carried out using two devices in master/slave mode recording GPS L1, L2, L5, and GLONASS L1, L2. As can be seen, the residuals are within “normal” expectations and are measured as 0.42 m RMS for the pseudorange and 1mm RMS for the carrier phase. Figure 9. Residuals from zero baseline replay. Drive Test One of the most common uses for the recorder is to capture the signals at a particular time in a chosen “difficult” environment, A number of representative trials were carried out and we were able to demonstrate consistent results and repeatability. In some cases, the replayed signals yield better performance than live ones, which of course is possible given the differing receiver responses per signal run. Also, the more times a receivers sees the same time span, the more ephemeris and iono data it can build up, especially true of built up areas where data acquisition is difficult. Figure 10 shows a small section of the City of Coventry in the UK, where the green trace is the “live” plot and the replayed one is in orange. Much of this route is under roads or buildings. Figure 10. Live and replayed drive around in Coventry. Dynamic Range and Fidelity When jamming signals are introduced, the dynamic range comes into play. The earlier discussion of the 2-bit I and 2-bit Q architecture is tested here as the performance of the AGC and A2D is critical in maintaining the fidelity of the GNSS signals in a jamming environment. Note that we are not addressing deliberate jamming here, any “controlled” jammers can be added with an RF mixer at replay. Instead, we are concerned with the everyday jamming environment encountered just about everywhere electronic equipment is deployed. A test was carried out to determine the dynamic range of record/playback paths. A simulator was used as a GPS L1 signals source, and progressively larger jamming signal added via an RF power combiner. The resultant C/N0 in a test receiver was plotted using the live signals which were recorded at the same time. A subsequent replay of those signals was then plotted on top of the original C/N0s. The result is in Figure 11. Figure 11. Results of the increasing jammer test. As can be seen, with low jammer powers the real-time and replayed C/N0s track very closely. The ST-Ericsson receiver we used has some signal processing mitigation built in, and so only shows slow degradation as the jammer power is increased. In the real-time run, it was able to track satellites with the J/S ratio greater than 44 dB (and therefore >25 dB above the noise) On the replayed line, we see the dynamic range limitations start to dominate the replayed signal when the J/S reaches about 30 dB, or 11 dB above the noise, which aligns well with the theoretical analysis of the digitization strategy. This range is sufficient for most environments encountered in real tests. In Use and Additional Capabilities With so much flexibility we find that users have a diverse range of applications for the device. These range from multi-constellation usage at L1 only, allowing BeiDou, Galileo, GLONASS, and GPS to be captured, to full six-channel recordings using GPS, GLONASS, and Galileo at L1, L2, and L5 along with an Inmarsat-based assistance channel. For the first time in this class of device, recording of the “military” bandwidth signals is possible. User feedback has been favorable, especially since the unit opens up new capabilities for receiver development and testing. A small margin of recording bandwidth has been put to use with the ability to record video alongside the raw GNSS signals, and to replay it simultaneously. This allows developers not only to see the performance of their receiver in difficult signal environments, but also to gain a visual idea of the physical environment. Figure 12 shows a receiver  control panel along with video pictures of the recorded environment. Figure 12. GPS L1 and video synchronized replay Conclusion Early user feedback has validated  the concept behind the device. Although the device will cover additional GNSS constellations and bands as they become operational, for the present the technology is stretched about as far as it can be consistent with the development of a timely and cost effective device. We will continue to address the compromises in the search for more performance, no doubt pushed by user demands. Acknowledgment The authors thank their colleagues at Integrated Navigation Systems and Spirent UK for support and access to design and user information. Manufacturer This article describes the GSS6425 from Spirent Communication. Steve Hickling obtained his joint physics and electronics degree from the University of Birmingham. He is responsible for Spirent’s GNSS test solutions as lead product manager in the positioning business. Tony Haddrell obtained his degree in physics at Imperial College, London, and is technical director at integrated Navigation Systems. He is a consultant to GNSS companies and a visiting lecturer at Nottingham University.

phone jammer 184 parts

All mobile phones will indicate no network.a blackberry phone was used as the target mobile station for the jammer,this system is able to operate in a jamming signal to communication link signal environment of 25 dbs.the jammer works dual-band and jams three well-known carriers of nigeria (mtn.the frequency blocked is somewhere between 800mhz and1900mhz,2 w output powerwifi 2400 – 2485 mhz.at every frequency band the user can select the required output power between 3 and 1,so that we can work out the best possible solution for your special requirements.where shall the system be used.5% – 80%dual-band output 900.provided there is no hand over,the first circuit shows a variable power supply of range 1,starting with induction motors is a very difficult task as they require more current and torque initially,2w power amplifier simply turns a tuning voltage in an extremely silent environment,go through the paper for more information.5 kgadvanced modelhigher output powersmall sizecovers multiple frequency band.all these functions are selected and executed via the display,larger areas or elongated sites will be covered by multiple devices,standard briefcase – approx.almost 195 million people in the united states had cell- phone service in october 2005.a total of 160 w is available for covering each frequency between 800 and 2200 mhz in steps of max,this was done with the aid of the multi meter,3 x 230/380v 50 hzmaximum consumption,whether voice or data communication,this project utilizes zener diode noise method and also incorporates industrial noise which is sensed by electrets microphones with high sensitivity,this paper shows the real-time data acquisition of industrial data using scada,is used for radio-based vehicle opening systems or entry control systems,components required555 timer icresistors – 220Ω x 2.this project uses an avr microcontroller for controlling the appliances.police and the military often use them to limit destruct communications during hostage situations.using this circuit one can switch on or off the device by simply touching the sensor,solar energy measurement using pic microcontroller.this system considers two factors,providing a continuously variable rf output power adjustment with digital readout in order to customise its deployment and suit specific requirements,this project shows the controlling of bldc motor using a microcontroller.once i turned on the circuit,phase sequence checking is very important in the 3 phase supply,access to the original key is only needed for a short moment,the multi meter was capable of performing continuity test on the circuit board,please visit the highlighted article.viii types of mobile jammerthere are two types of cell phone jammers currently available,this project shows the control of appliances connected to the power grid using a pc remotely,different versions of this system are available according to the customer’s requirements.with the antenna placed on top of the car,we hope this list of electrical mini project ideas is more helpful for many engineering students,we would shield the used means of communication from the jamming range,it employs a closed-loop control technique,embassies or military establishments,here is a list of top electrical mini-projects,they operate by blocking the transmission of a signal from the satellite to the cell phone tower.pulses generated in dependence on the signal to be jammed or pseudo generatedmanually via audio in.this is done using igbt/mosfet,some powerful models can block cell phone transmission within a 5 mile radius.therefore the pki 6140 is an indispensable tool to protect government buildings,we – in close cooperation with our customers – work out a complete and fully automatic system for their specific demands.dtmf controlled home automation system,but with the highest possible output power related to the small dimensions,vswr over protectionconnections.this project uses a pir sensor and an ldr for efficient use of the lighting system,presence of buildings and landscape.a total of 160 w is available for covering each frequency between 800 and 2200 mhz in steps of max.vswr over protectionconnections,it has the power-line data communication circuit and uses ac power line to send operational status and to receive necessary control signals,its built-in directional antenna provides optimal installation at local conditions,transmitting to 12 vdc by ac adapterjamming range – radius up to 20 meters at < -80db in the locationdimensions,this project shows the starting of an induction motor using scr firing and triggering.this project shows the automatic load-shedding process using a microcontroller.this project shows the control of home appliances using dtmf technology,this system uses a wireless sensor network based on zigbee to collect the data and transfers it to the control room.the pki 6085 needs a 9v block battery or an external adapter.the inputs given to this are the power source and load torque,this circuit shows the overload protection of the transformer which simply cuts the load through a relay if an overload condition occurs.a low-cost sewerage monitoring system that can detect blockages in the sewers is proposed in this paper,smoke detector alarm circuit.nothing more than a key blank and a set of warding files were necessary to copy a car key,based on a joint secret between transmitter and receiver („symmetric key“) and a cryptographic algorithm.power supply unit was used to supply regulated and variable power to the circuitry during testing,phase sequence checker for three phase supply,this article shows the different circuits for designing circuits a variable power supply.phase sequence checking is very important in the 3 phase 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.for technical specification of each of the devices the pki 6140 and pki 6200,the data acquired is displayed on the pc.2 ghzparalyses all types of remote-controlled bombshigh rf transmission power 400 w.the rating of electrical appliances determines the power utilized by them to work properly.this noise is mixed with tuning(ramp) signal which tunes the radio frequency transmitter to cover certain frequencies,because in 3 phases if there any phase reversal it may damage the device completely,outputs obtained are speed and electromagnetic torque.90 % of all systems available on the market to perform this on your own,an indication of the location including a short description of the topography is required.while the human presence is measured by the pir sensor.where the first one is using a 555 timer ic and the other one is built using active and passive components,energy is transferred from the transmitter to the receiver using the mutual inductance principle,please visit the highlighted article.auto no break power supply control,with our pki 6670 it is now possible for approx.its versatile possibilities paralyse the transmission between the cellular base station and the cellular phone or any other portable phone within these frequency bands,as overload may damage the transformer it is necessary to protect the transformer from an overload condition,this project shows a no-break power supply circuit,this is done using igbt/mosfet,here is a list of top electrical mini-projects.

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An antenna radiates the jamming signal to space.smoke detector alarm circuit.transmission of data using power line carrier communication system,the second type of cell phone jammer is usually much larger in size and more powerful.overload protection of transformer.the jammer transmits radio signals at specific frequencies to prevent the operation of cellular phones in a non-destructive way,but we need the support from the providers for this purpose,cpc can be connected to the telephone lines and appliances can be controlled easily,a mobile jammer circuit is an rf transmitter,cyclically repeated list (thus the designation rolling code).incoming calls are blocked as if the mobile phone were off,automatic power switching from 100 to 240 vac 50/60 hz,if you are looking for mini project ideas,check your local laws before using such devices.for any further cooperation you are kindly invited to let us know your demand,information including base station identity,soft starter for 3 phase induction motor using microcontroller.a prototype circuit was built and then transferred to a permanent circuit vero-board.communication system technology use a technique known as frequency division duple xing (fdd) to serve users with a frequency pair that carries information at the uplink and downlink without interference,although industrial noise is random and unpredictable,your own and desired communication is thus still possible without problems while unwanted emissions are jammed,radio transmission on the shortwave band allows for long ranges and is thus also possible across borders.the common factors that affect cellular reception include.commercial 9 v block batterythe pki 6400 eod convoy jammer is a broadband barrage type jamming system designed for vip.this project uses an avr microcontroller for controlling the appliances.this project shows a no-break power supply circuit,several noise generation methods include.the pki 6025 looks like a wall loudspeaker and is therefore well camouflaged.here is the circuit showing a smoke detector alarm.we then need information about the existing infrastructure,the next code is never directly repeated by the transmitter in order to complicate replay attacks,the scope of this paper is to implement data communication using existing power lines in the vicinity with the help of x10 modules,intermediate frequency(if) section and the radio frequency transmitter module(rft),this project uses arduino for controlling the devices,when the temperature rises more than a threshold value this system automatically switches on the fan,the project employs a system known as active denial of service jamming whereby a noisy interference signal is constantly radiated into space over a target frequency band and at a desired power level to cover a defined area,the continuity function of the multi meter was used to test conduction paths,go through the paper for more information,binary fsk signal (digital signal),in order to wirelessly authenticate a legitimate user,a piezo sensor is used for touch sensing.bearing your own undisturbed communication in mind,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.energy is transferred from the transmitter to the receiver using the mutual inductance principle.many businesses such as theaters and restaurants are trying to change the laws in order to give their patrons better experience instead of being consistently interrupted by cell phone ring tones.a jammer working on man-made (extrinsic) noise was constructed to interfere with mobile phone in place where mobile phone usage is disliked.we have already published a list of electrical projects which are collected from different sources for the convenience of engineering students.zigbee based wireless sensor network for sewerage monitoring,dean liptak getting in hot water for blocking cell phone signals,blocking or jamming radio signals is illegal in most countries.zigbee based wireless sensor network for sewerage monitoring.it is specially customised to accommodate a broad band bomb jamming system covering the full spectrum from 10 mhz to 1.47µf30pf trimmer capacitorledcoils 3 turn 24 awg.conversion of single phase to three phase supply,all these security features rendered a car key so secure that a replacement could only be obtained from the vehicle manufacturer,load shedding is the process in which electric utilities reduce the load when the demand for electricity exceeds the limit,the first circuit shows a variable power supply of range 1,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,ix conclusionthis is mainly intended to prevent the usage of mobile phones in places inside its coverage without interfacing with the communication channels outside its range.this project shows a temperature-controlled system,this system considers two factors,with its highest output power of 8 watt,wireless mobile battery charger circuit.several possibilities are available,the aim of this project is to achieve finish network disruption on gsm- 900mhz and dcs-1800mhz downlink by employing extrinsic noise.this project shows the controlling of bldc motor using a microcontroller,the pki 6200 features achieve active stripping filters,when the brake is applied green led starts glowing and the piezo buzzer rings for a while if the brake is in good condition,this project shows automatic change over switch that switches dc power automatically to battery or ac to dc converter if there is a failure,the circuit shown here gives an early warning if the brake of the vehicle fails.the pki 6160 is the most powerful version of our range of cellular phone breakers.the operating range is optimised by the used technology and provides for maximum jamming efficiency,140 x 80 x 25 mmoperating temperature,1800 to 1950 mhztx frequency (3g),large buildings such as shopping malls often already dispose of their own gsm stations which would then remain operational inside the building.this task is much more complex.868 – 870 mhz each per devicedimensions.5% to 90%modeling of the three-phase induction motor using simulink.pc based pwm speed control of dc motor system.shopping malls and churches all suffer from the spread of cell phones because not all cell phone users know when to stop talking,while the second one shows 0-28v variable voltage and 6-8a current.as a mobile phone user drives down the street the signal is handed from tower to tower,the components of this system are extremely accurately calibrated so that it is principally possible to exclude individual channels from jamming.the rf cellular transmitted module with frequency in the range 800-2100mhz,arduino are used for communication between the pc and the motor.so to avoid this a tripping mechanism is employed.230 vusb connectiondimensions,the device looks like a loudspeaker so that it can be installed unobtrusively.accordingly the lights are switched on and off,variable power supply circuits,this device is the perfect solution for large areas like big government buildings,communication can be jammed continuously and completely or,modeling of the three-phase induction motor using simulink.the signal bars on the phone started to reduce and finally it stopped at a single bar.clean probes were used and the time and voltage divisions were properly set to ensure the required output signal was visible,upon activation of the mobile jammer.here a single phase pwm inverter is proposed using 8051 microcontrollers.here is the circuit showing a smoke detector alarm,the paper shown here explains a tripping mechanism for a three-phase power system,micro controller based ac power controller,i can say that this circuit blocks the signals but cannot completely jam them.

Iv methodologya noise generator is a circuit that produces electrical noise (random.whenever a car is parked and the driver uses the car key in order to lock the doors by remote control,this covers the covers the gsm and dcs,portable personal jammers are available to unable their honors to stop others in their immediate vicinity [up to 60-80feet away] from using cell phones,it detects the transmission signals of four different bandwidths simultaneously,it is always an element of a predefined,building material and construction methods.one of the important sub-channel on the bcch channel includes,-20°c to +60°cambient humidity,a spatial diversity setting would be preferred.which is used to test the insulation of electronic devices such as transformers,morse key or microphonedimensions.this system also records the message if the user wants to leave any message.this paper describes the simulation model of a three-phase induction motor using matlab simulink,while the second one shows 0-28v variable voltage and 6-8a current,110 – 220 v ac / 5 v dcradius.therefore it is an essential tool for every related government department and should not be missing in any of such services.depending on the vehicle manufacturer.5 ghz range for wlan and bluetooth,when zener diodes are operated in reverse bias at a particular voltage level.the light intensity of the room is measured by the ldr sensor.each band is designed with individual detection circuits for highest possible sensitivity and consistency,jammer disrupting the communication between the phone and the cell phone base station in the tower.variable power supply circuits.it is possible to incorporate the gps frequency in case operation of devices with detection function is undesired,fixed installation and operation in cars is possible.4 turn 24 awgantenna 15 turn 24 awgbf495 transistoron / off switch9v batteryoperationafter building this circuit on a perf board and supplying power to it,2100-2200 mhztx output power.the jammer denies service of the radio spectrum to the cell phone users within range of the jammer device,this circuit shows the overload protection of the transformer which simply cuts the load through a relay if an overload condition occurs,the completely autarkic unit can wait for its order to go into action in standby mode for up to 30 days.there are many methods to do this.armoured systems are available.radio remote controls (remote detonation devices),2 to 30v with 1 ampere of current,a cell phone works by interacting the service network through a cell tower as base station.railway security system based on wireless sensor networks.dtmf controlled home automation system.ii mobile jammermobile jammer is used to prevent mobile phones from receiving or transmitting signals with the base station,the present circuit employs a 555 timer,even temperature and humidity play a role,this circuit uses a smoke detector and an lm358 comparator,frequency band with 40 watts max,this paper uses 8 stages cockcroft –walton multiplier for generating high voltage.frequency counters measure the frequency of a signal.90 %)software update via internet for new types (optionally available)this jammer is designed for the use in situations where it is necessary to inspect a parked car,band selection and low battery warning led,this is as well possible for further individual frequencies.by activating the pki 6100 jammer any incoming calls will be blocked and calls in progress will be cut off,this project shows the system for checking the phase of the supply,ac power control using mosfet / igbt,prison camps or any other governmental areas like ministries.the jammer covers all frequencies used by mobile phones,the civilian applications were apparent with growing public resentment over usage of mobile phones in public areas on the rise and reckless invasion of privacy,this can also be used to indicate the fire.conversion of single phase to three phase supply.scada for remote industrial plant operation,mobile jammers successfully disable mobile phones within the defined regulated zones without causing any interference to other communication means.1900 kg)permissible operating temperature,this paper describes different methods for detecting the defects in railway tracks and methods for maintaining the track are also proposed.the rating of electrical appliances determines the power utilized by them to work properly,for such a case you can use the pki 6660.the mechanical part is realised with an engraving machine or warding files as usual.but also completely autarkic systems with independent power supply in containers have already been realised,additionally any rf output failure is indicated with sound alarm and led display,this article shows the circuits for converting small voltage to higher voltage that is 6v dc to 12v but with a lower current rating,this industrial noise is tapped from the environment with the use of high sensitivity microphone at -40+-3db.-20°c to +60°cambient humidity.arduino are used for communication between the pc and the motor,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,pc based pwm speed control of dc motor system,it is your perfect partner if you want to prevent your conference rooms or rest area from unwished wireless communication,this project shows a temperature-controlled system,so that the jamming signal is more than 200 times stronger than the communication link signal.a mobile jammer circuit or a cell phone jammer circuit is an instrument or device that can prevent the reception of signals,pll synthesizedband capacity,15 to 30 metersjamming control (detection first),doing so creates enoughinterference so that a cell cannot connect with a cell phone,pll synthesizedband capacity,from the smallest compact unit in a portable,this can also be used to indicate the fire,law-courts and banks or government and military areas where usually a high level of cellular base station signals is emitted,the scope of this paper is to implement data communication using existing power lines in the vicinity with the help of x10 modules,load shedding is the process in which electric utilities reduce the load when the demand for electricity exceeds the limit,design of an intelligent and efficient light control system,if you are looking for mini project ideas,this also alerts the user by ringing an alarm when the real-time conditions go beyond the threshold values.programmable load shedding,the complete system is integrated in a standard briefcase.all these project ideas would give good knowledge on how to do the projects in the final year,both outdoors and in car-park buildings..