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Photo: peeterv/iStock/Getty Images Plus/Getty Images Complexity and Context: Key Challenges of Multisensor Positioning By Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London The next generation of navigation and positioning systems must provide greater accuracy and reliability in a range of challenging environments to meet the needs of a variety of mission-critical applications. No single navigation technology is robust enough to meet these requirements on its own, so a multisensor solution is required. Four key challenges must be met: complexity, context, ambiguity, and environmental data handling. Although many new navigation and positioning methods have been developed in recent years to address GNSS shortcomings in terms of signal penetration and interference vulnerability, little has been done to bring them together into a robust, reliable, and cost-effective integrated system. New positioning techniques investigated over the past 15 years include:Wi-Fi; ultra-wideband; phone signals; television and other signals of opportunity; Bluetooth; lasers, and dead reckoning; pedestrian dead reckoning (PDR) using step detection; pedestrian and activity-based map matching; magnetic anomaly matching; and GNSS shadow matching. There have also been improvements to existing technologies: visual navigation, dead-reckoning algorithms, micro-electro-mechanical systems, inertial sensing with cold-atom technology, nuclear magnetic resonance gyros, distance-measuring equipment, Loran, Doppler with Iridium, multiple GNSS constellations, network assistance, and augmentation by commercial pseudolite systems. In the next generation, a universal navigation system might be expected to provide position within 3 meters at any location with a very high reliability. No single positioning technology is capable of meeting the most demanding application requirements. Radio signals may or may not be subject to obstruction, attenuation, reflection, jamming, and/or interference. Known environmental features, such as signs, buildings, terrain height variation, and magnetic anomalies, may or may not be available for positioning. The system could be stationary, carried by a pedestrian, or on any type of land, sea, or air vehicle. Furthermore, for many applications, the environment and host behavior are subject to change. A multisensor solution is thus required. A robust, reliable, and cost-effective integrated system must meet four key challenges: Complexity. How to find the necessary expertise to integrate a diverse range of technologies, how to combine technologies from different organizations that wish to protect their intellectual property, how to incorporate new technologies and methods without having to redesign the whole system, and how to share development effort over a range of different applications. Context. How to ensure that the navigation system configuration is optimized for the operating environment and host vehicle (or pedestrian) behavior when both are subject to change. Ambiguity. How to handle multiple hypotheses, including measurements of non-unique environmental features, pattern-matching fixes where the measurements match the database at multiple locations, and uncertain signal properties, such as whether reception is direct or non-line-of-sight (NLOS). Environmental Data Handling. How to gather, distribute, and store the information needed to identify signals and environmental features and define their points of origin or spatial variation. Complexity Achieving robust positioning in challenging environments potentially requires a large number of subsystems. For example, Figure 1 shows the possible components of a pedestrian navigation system using sensors found in a typical smartphone. Figure 2 shows possible components of a car navigation system using equipment already common on cars and other suitable low-cost sensors. Some technologies are common to the two platforms, while others differ. Figure 1. Potential components of a pedestrian navigation system using smartphone sensors. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figure 2. Potential components of a car navigation system using commonly available equipment and other low-cost sensors. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Any multisensor navigation or positioning system needs integration algorithms to obtain the best overall position solution from the constituent subsystems. These algorithms must not only input and combine measurements from a wide range of subsystems, but also calibrate systematic errors in those subsystems. Designing the integration algorithms therefore requires expertise in all of the subsystems, which can be difficult to establish in a single organization. The more subsystems there are, the more of a problem this is. The expert knowledge problem is compounded by the fact that different modules in an integrated navigation system are often supplied by different organizations, who may be reluctant to share necessary design information if this is considered to be intellectual property that must be protected. In a typical smartphone, one company supplies the GNSS chip, another supplies the Wi-Fi positioning service, a third organization supplies the mapping, the network operator provides the phone-signal positioning, a fifth company provides the inertial and magnetic sensors, and a sixth company produces the operating system. Because of lack of cooperation between these different organizations, useful information gets lost. For example, GNSS pseudo-range measurements are not normally available to application developers. A further issue is reconfigurability. To minimize development costs, manufacturers share algorithms and software across different products, incorporating different subsystems. They also want to minimize the cost of adding new sensors to a product to improve performance. Similarly, researchers want to compare different combinations of subsystems. However, with a conventional system architecture, modifications must be made throughout the integration algorithm each time a subsystem is added, removed, or replaced. The more subsystems there are, the more complex this task becomes. For a given application, different subsystems may also be used at different times. For example, a smartphone may use Wi-Fi positioning indoors and GNSS outdoors and may deploy different motion constraints and map matching algorithms, depending on whether the device is carried by a pedestrian or traveling in a car. Different integration algorithms for different configurations are more processor efficient, but also require more development effort. Conversely, an all-subsystem integration algorithm is quicker to develop, but can waste processing resources handling inactive subsystems. Modular Integration. The solution to these problems is a modular integration architecture, consisting of a universal integration filter module and a set of configuration modules, one for each subsystem. The integration filter module would be designed by data fusion experts without the need for detailed knowledge of the subsystems. It would accept a number of generic measurement types, such as position fixes and pseudo-ranges, with associated metadata. The configuration modules would be developed by the subsystem suppliers and would convert the subsystem measurements into a format understood by the filter module and supply the metadata. They would also mediate the feedback of information from the integration filter to the subsystems. The metadata comprises the additional information required to integrate the measurements such as the measurement type and any coordinate frame(s) used. a sensor identification number (to distinguish measurements of the same type from different sensors). statistical properties of the random and systematic measurement errors. identification numbers and locations of transmitters and other landmarks. A key advantage of this approach is that subsystems may be changed without the need to modify the integration filter. Provided the new subsystem is compatible, all that is needed is the corresponding configuration module. Figure 3 shows an example of a modular integration architecture for a combination of conventional GNSS positioning, GNSS shadow matching, Wi-Fi positioning, and PDR. As well as providing measurements and associated statistical data to the integration filter module, the configuration modules feedback relevant information to the subsystems. Shadow matching works by comparing measured and predicted signal availability over a number of candidate positions, so requires a search area to be specified using other positioning technologies. PDR uses information from other sensors, where available, to calibrate the coefficients of its step length estimation model and correct for heading drift. Conventional GNSS positioning can also benefit from position and velocity aiding to support acquisition and tracking of weak signals in indoor and urban environments. Figure 3. Modular integration of conventional GNSS, shadow matching, PDR, and Wi-Fi positioning for pedestrian navigation (different colors denote potentially different suppliers). (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) In principle, each subsystem configuration module could simply supply a position fix to the integration filter module with an associated error covariance. However, other forms of measurement generally give better results. For conventional GNSS positioning, the advantages of tightly coupled (range- domain) integration over loosely coupled (position-domain) are well known. PDR is a dead-reckoning technique, so measures distance traveled rather than position. Consequently, providing measurements of position displacement and direction can avoid cumulative errors in the measurement stream. GNSS shadow matching and some types of Wi-Fi positioning use the pattern-matching positioning method. This scores an array of candidate position solutions according to the match between the measured and predicted signal availability or signal strength. Although the output of these algorithms is in the position domain, a likelihood distribution can provide more information for the integration filter than a simple mean and covariance. Other navigation and positioning techniques generate further types of measurement, including velocity, attitude, specific force, angular rate, range rate, and bearings and elevations of features. The types of measurement depend on the positioning method. A universal integration filter must operate without prior knowledge of which measurements it must process and which states it must estimate. Consequently, it must reconfigure its measurement vector, state vector, and associated matrices according to the measurements available, using the metadata supplied by the configuration module. This capability is sometimes called “plug and play,” and a number of prototypes have been developed by different research groups. The integration filter must be capable of implementing either error-state or total-state integration, depending on the measurements available. In error-state integration, one of the subsystems, such as inertial navigation, provides a reference navigation solution. The integration filter estimates corrections to that solution using the measurements from other subsystems. In total-state integration, the integration filter estimates the position and velocity directly, and an additional configuration module provides information on the host vehicle (or pedestrian) dynamics. Modular integration algorithms could form part of a wider modular integrated navigation concept in which subsystem hardware and software is shared across a range of applications. Issues to Resolve A critical requirement for the successful implementation of modular integration is an open-standard interface for communication between the universal filter and configuration modules. This enables modules produced by different organizations to work together. To realize the full benefits of modular integration, in terms of interoperability and software re-use, there should be a single standard covering the consumer, professional, research, and military user communities and spanning all of the application domains air, sea, land, indoor, underwater, and so forth. A standard developed by one group in isolation is unlikely to meet the needs of the whole navigation and positioning community, while the development of multiple competing standards defeats the main purpose of modular integration. This interface should be defined in terms of fundamental measurement types, such as position, velocity, and the ranges, bearings, and elevations of signals and features. However, there are many different coordinate systems that may be used and positioning may be in 2 or 3 dimensions, while ranging measurements may be true ranges or pseudoranges. Ranging and angular positioning measurements may be differenced across transmitters or landmarks, differenced across receivers or sensors, or double differenced across both. A universal interface must support every measurement type that requires different processing by the filter module. However, it need not support formats that are easily convertible. Thus, there is no need to support both the north, east, down, and east, north, up conventions. There are two main approaches to defining the fundamental measurement types: A minimal number of very generic measurement types with metadata used to describe how these should be processed by the integration filter. A large number of more specific measurement types for which the processing methodology is already known. For each measurement type, an error specification must be defined. For error sources assumed to be white, a standard deviation or power spectral density (PSD) is required. For correlated errors, such as biases, information on the time correlation is required alongside variances and covariance information. The interface standard should include every conceivable error source. Unused errors can simply be zeroed. The filter module should then use the error specification to determine which error sources to model and how. Obtaining reliable navigation sensor error specifications can be difficult. Manufacturers often provide only limited information, while performance in the field can be different from that in the laboratory due to vibration and electromagnetic interference. For new positioning techniques, the error behavior may not be fully understood, while complex error behavior can be difficult to measure. Adaptive estimation techniques provide only a partial solution. Even where the error behavior is well known, it can be too complex to practically model within the estimation algorithm. This could represent a fifth challenge. For subsystems used as the reference in an error-state integration filter, such as an inertial navigation system (INS), the errors will typically be correlated across the different components of the subsystem navigation solution, for example position, velocity, and attitude. Furthermore, to represent the error behavior within an integration algorithm, it is necessary to model the error properties of the underlying sensors, accelerometers and gyroscopes in the case of inertial navigation. Thus, it is likely that additional compound measurement types for reference system data will be needed. For pseudorange measurements, an issue to consider is the synchronization of different transmitter and receiver clocks. Clocks in receivers for different types of signal, such as GNSS and Loran, may or may not be synchronized with each other. Also, the transmitter clocks are typically synchronized in groups. For example, the GPS satellite clocks are synchronized with each other, as are the GLONASS satellite clocks, but GLONASS is not currently synchronized with GPS. For optimal integration of pseudoranges from different sources, this information must be conveyed to the integration filter. The interface standard for communication between the filter and configuration modules must also support feedback of information from the integration filter to the subsystems, via the configuration modules. The integrated position, velocity, and attitude solution, with its associated error covariance, is useful for aiding many different subsystems. Therefore, a generic standard for this should be defined. Conversely, the feedback to the subsystems of calibration parameters estimated by the integration algorithm is sensor specific, so should be incorporated in the definitions of the fundamental measurement types. The user requirements, such as accuracy, integrity, continuity, solution availability, update rate, and power consumption, can vary greatly between applications. For example, accuracy is important for surveying, integrity for civil aviation, solution availability for many military applications, and power consumption for many consumer applications. This impacts the design of the whole navigation system. Different modules could be used for different applications. However, it is more efficient if the components adapt to different environments. Figure 4 shows how requirements information can be disseminated in a modular integrated navigation system. Figure 4. Modular integration architecture incorporating requirements. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) An open-standard interface specification should be able to handle any conceivable navigation and positioning system. However, it is more efficient if the components adapt to different environments. Similarly, there will be differences in the error magnitudes that an integration filter can handle and in its capability to handle non-Gaussian error distributions. Variations in fault detection and integrity monitoring capability can also be expected. Consequently, there must be a capability specification for each filter module and a protocol for handling mismatches between the measurements and the filter module, and a means to certify that a filter module actually has the claimed capabilities. (Further discussion of modular integration may be found in our IEEE/ION PLANS 2014 paper, “The Four Key Challenges of Advanced Multisensor Navigation and Positioning,” and the Journal of Navigation paper, “The Complexity Problem in Future Multisensor Navigation and Positioning Systems: A Modular Solution.”) Context Context is the environment that a navigation system operates in and the behavior of its host vehicle or user. Examples include a pedestrian walking (behavior) in an urban street (environment), a car driving at highway speeds on an open road, and an airliner flying high above an ocean. Context is critical to the operation of a navigation or positioning system. The environment affects the types of signals available. For example, GNSS reception is poor indoors while Wi-Fi is not widely available outside towns and cities. In underwater environments, most radio signals cannot propagate so acoustic signals are used instead. Processing techniques can also be context dependent. For example, in open environments, non-line-of-sight (NLOS) reception of GNSS signals or multipath interference may be detected using consistency checking techniques based on sequential elimination. However, in dense urban areas, more sophisticated algorithms are required and may be enhanced using 3D city models. GNSS shadow matching only works in outdoor urban environments. Navigation using environmental feature matching is inherently context-dependent as different types of feature are available in different environments. Suitable algorithms, databases, and sensors must be selected. For example, terrain referenced navigation (TRN) uses radar or laser scanning in the air, sonar or echo sounding at sea, and barometric pressure on land. Map matching requires different approaches for cars, trains, and pedestrians. Similarly, algorithms and databases for image-based navigation depend on the types of feature available, which vary with the environment. Behavioral context is also important and can contribute additional information to the navigation solution. For example, cars normally remain on the road, effectively removing one dimension from the position solution. Their wheels also impose constraints on the way they can move, reducing the number of inertial sensors required to measure their motion. Similarly, PDR using step detection depends inherently on the characteristics of human walking. Using PDR for vehicle navigation or vehicle motion constraints for pedestrian navigation will produce errors. Host vehicle behavior is also important for tuning the dynamic model within a total-state navigation filter and for detecting faults through discrepancies between measured and expected behavior. Within a GNSS receiver, the behavior can be used to set tracking loop bandwidths and coherent correlator accumulation intervals, and to predict the temporal variation of multipath errors. The antenna placement on a vehicle or person can also affect performance. Historically, context was implicit; a navigation system was designed to be used in a particular type of vehicle, handling its associated behavior and environments. However, many navigation systems now need to operate in a variety of different contexts. For example, a smartphone moves between indoor and outdoor environments and can be stationary, on a pedestrian, or in a vehicle. Similarly, a small surveillance drone may operate from above, amongst buildings, or even indoors. At the same time, most of the new positioning techniques developed to enable navigation in challenging environments, are context-dependent. To make use of these techniques in practical applications (as opposed to research demonstrators), it is necessary to know the context. Context-Adaptive Navigation The solution to the problem of using context-dependent navigation techniques in variable-context applications is context-adaptive navigation. As shown in  Figure 5, the navigation system detects the current environmental and behavioral context and, in real time, reconfigures its algorithms accordingly. For example, different radio positioning signals and techniques may be selected, inertial sensor data may be processed in different ways, different map-matching algorithms may be selected, and the tuning of the integration algorithms may be varied. Figure 5. A context-adaptive navigation system. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Previous work on context-adaptive navigation and positioning focused on individual subsystems and concerned either behavioral or environmental context, not both. For example, there has been substantial research into classifying pedestrian motion using inertial sensors to enable PDR algorithms using step detection to estimate the distance travelled from the detected motion. The context information may also be used for non-navigation purposes. Typically, orientation-independent signals are generated from the accelerometer and gyro outputs. Statistics such as the mean, standard deviation, root mean squared (RMS), inter-quartile range, mean absolute deviation, maximum−minimum, maximum magnitude, number of zero crossings, and number of mean crossings are then determined from a few seconds of data. Frequency-domain statistics may also be used. Finally, a pattern recognition algorithm is used to match these parameters to the stored characteristics of different combinations of activity types and sensor locations. Detection of road-induced vibration using accelerometers has been used to determine whether or not a land vehicle is stationary, while a calibrated yaw-axis gyro can be used to determine when a vehicle is travelling in a straight line. Indoor and outdoor environments may be distinguished using GNSS carrier-power-to-noise-density ratio (C/N0 ) measurements. Wi-Fi signals might also be used for environmental context detection. Context Detection Experiments We have conducted a number of different context-detection experiments using GNSS, Wi-Fi, and accelerometers. Full details are presented in our ION GNSS+ 2013 paper, “Context Detection, Categorization and Connectivity for Advanced Adaptive Integrated Navigation,” and in our PLANS 2014 paper. Here, some highlights from the results are presented. GNSS. GNSS data was collected at five locations inside and immediately outside UCL’s Grant Museum of Zoology; these are shown in Figure 6. C/N0 measurement data was collected from all GPS and GLONASS signals received by a Samsung Galaxy S3 Android smartphone. About 60 seconds of data was collected at each site. Figure 7 presents histograms of the C/N0 measurements and Table 1 lists the means and standard deviations. Figure 6. Locations for the GNSS indoor/outdoor context detection experiment. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figure 7. GNSS C/N0 measurement distributions at sites inside and immediately outside UCL’s Grant Museum of Zoology. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Table 1. Means and standard deviations of GNSS C/N0 measurements inside and outside UCL’s Grant Museum of Zoology. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) As expected, the average received C/N0 is lower indoors than outdoors and lower deep indoors than near the entrance. Furthermore, the standard deviation of the C/N0 measurements is larger outdoors than indoors and also larger near the entrance to the building than deep indoors. Thus, both the mean and the standard deviation of the measured C/N0 across all GNSS satellites tracked are useful both for detecting indoor and outdoor contexts and for distinguishing between different types of indoor environment. Indoor/Outdoor Detection, Wi-Fi. Tests in and around several UCL buildings have shown no clear relationship between Wi-Fi SNRs and environmental context. However, as the environment changes, there is a rapid change in the Wi-Fi SNRs over a few epochs. For a user moving from inside to outside of a particular building, those signals which originate inside go from strong to weak, while many of those from neighboring buildings become stronger. Consequently, Wi-Fi signals could potentially be used to detect context changes instead of the absolute context. This is useful for improving the overall robustness of context determination. To test this, Wi-Fi data was collected using a Samsung Galaxy S3 smartphone along a route with both indoor and outdoor sections and a context-change score calculated from the last six epochs of data at 1-second intervals. Context-change score results are presented in Figure 8. The large blue blocks indicate when the user was outside and the smaller blue block shows when the user was in the building’s basement, a very different Wi-Fi environment. As can be seen, there are clear peaks in the “context change” score whenever the user moves between indoor and outdoor contexts. However, there are also peaks when the user enters and leaves the basement, so the technique is sensitive to false positives and must be combined with other context detection techniques to be used reliably. Figure 8. Context-change score computer from Wi-Fi SNR measurements. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Behavioral Detection, Accelerometers. The use of accelerometers to detect behavioral context is well established. However, by looking at the vibration spectra, more information can be extracted. For these experiments, specific force data was collected using an Xsens MTi-G IMU/GNSS device, the mean subtracted to remove most of the gravity, and a discrete Fourier transform obtained using the MATLAB function fft. Figures 9 and 10 respectively show the vibration spectra of the specific force magnitude for an IMU on a table and held by a stationary pedestrian. The table spectrum is approximately white, whereas the pedestrian data shows peaks between 6 and 10 Hz. Figure 9. IMU spectra on a table. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figure 10. IMU spectra, stationary pedestrian. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figures 11 and 12 respectively show the vibration spectra of a stationary Vauxhall Insignia car, and a stationary urban electric train. Here, the individual accelerometer spectra are shown. In each case, the x-axis was pointing forward, the y-axis to the right and the z-axis down. The car exhibits a lot of vibration at frequencies above 10 Hz due to its engine, whereas the dominant train vibration peak is around 1.5 Hz, with smaller peaks at 15 Hz, 25 Hz, 33 Hz, and 50 Hz, the mains power frequency. Thus, the two vehicles are very different from each other and also from the pedestrian. Figure 13 then shows the vibration spectrum of the car moving on a high-speed road. As might be expected, there is much more vibration when moving with broad peaks below 15 Hz due to road vibration and above 15 Hz due to engine vibration. Figure 11. Specific force frequency spectrum of a stationary car. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figure 12. Specific force frequency spectrum of a stationary train. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Figure 13. Specific force frequency spectrum of a car traveling on a high- speed road. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Finally, Figure 14 shows the vibration spectra on an escalator at an underground rail station. The IMU was in the trouser pocket of a pedestrian. Vibration at a range of frequencies below 30 Hz can be seen and it was observed that the resonant frequencies vary between individual escalators. Figure 14. Specific force frequency spectrum on an escalator. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Issues to Resolve Despite the work done with individual sensors, a multisensor integrated navigation system that adapts to both environmental and behavioral context remains at the concept stage. Realizing this in a practical system requires both effective context determination and a set of context categories standardized across the whole navigation and positioning community. The first step in the standardization process is to establish a framework suitable for navigation and positioning. Each context category must map to a configuration of the navigation system; otherwise, it serves no purpose. Multiple categories may map to the same configuration as different navigation systems will respond to different context information. In an autonomous context-adaptive navigation system, the context categories must also be distinguishable from each other. Figure 15 shows the relationships in a five-attribute framework, comprising environment class, environment type, behavior class, vehicle type, and activity type. The environmental and behavioral contexts are treated separately because they perform fundamentally different roles in navigation. Environmental context concerns the availability of signals and other features that may be used for determining position whereas behavioral context is concerned with motion. Figure 15. Proposed attributes of a context category. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Context may be considered at different levels. Sometimes it is sufficient to consider broad classes such as indoor or aircraft. In other cases, more detail is needed, specifying the type of indoor environment or the type of aircraft. Therefore, a two-level categorization framework, comprising class and type is proposed. The behavioral context comprises the vehicle type and the activity undertaken by that vehicle. A common set of classes containing separate vehicle and activity types is thus proposed. For pedestrian navigation, different parts of the body move quite differently, so the sensor location on the body is analogous to the vehicle type. The broad classes of environmental and behavioral context are relatively obvious. We therefore propose that the community adopts the classes in Table 2. Standardization at the type level requires further research to determine: which context categories a navigation system needs to distinguish between in order to optimally configure itself; which context categories may be distinguished reliably by context detection and determination algorithms. Table 2. Proposed environment and behavior classes. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Effective Context Determination. The reliability of current context detection techniques is typically 90−99%, with some context categories easier to detect than others. For the purposes of controlling a navigation system, this is relatively poor. Furthermore, context detection research projects have typically considered a much smaller range of context categories than a practical context-adaptive navigation system would need. Generally, the more categories there are, the harder it is to distinguish between them. To make context determination reliable enough for context- adaptive navigation to be practical, a new approach is needed. Firstly, the context should be detected using as much information as possible, maximizing both the range of sensors used and the number of parameters derived from each sensor. Environmental context detection experiments have largely focused on GNSS and Wi-Fi signals. Other types of radio signal; environmental features detected using cameras, laser scanners, radar, or sonar; ambient light; sounds; odors; magnetic anomalies, and air pressure could all be used. Context may also be inferred by comparing the position solution with a map, provided both are sufficiently accurate. Behavioral context detection experiments have generally used inertial sensors. As shown earlier, this could be taken further by analyzing different frequency bands and, where possible, separating the forward, transverse, and vertical components. Other motion sensing techniques, such as visual odometry and wheel-speed odometry could be used. Context information, such as vehicle type, can also be determined from the velocity, attitude, and acceleration solutions. Considering every combination of environment type, vehicle type (or pedestrian sensor location), and activity type produces potentially tens of thousands of different context categories — too many to practically distinguish using context detection techniques alone. However, the number of context categories that must be considered may be reduced substantially by using association, scope, and connectivity information, making the determination process much more reliable. Association is the connection between the different attributes of context. Certain activities are associated with certain vehicle types and certain behaviors are associated with certain environments; an airliner flies, while a train does not, and flying takes place in the air, not at the bottom of the sea.  For a particular application, the scope defines each context category to be required, unsupported, or forbidden. This enables forbidden context categories to be eliminated from the context determination process and required categories to be treated as more likely than unsupported categories. Connectivity describes the relationship between context categories. If a direct transition between two categories can occur, they are connected. Otherwise, they are not. Thus, stationary vehicle behavior is connected to pedestrian behavior, whereas moving vehicle behavior is not because a vehicle must normally stop to enable a person to get in or out. Context connectivity is directly analogous to the road link connectivity used in map matching and a similar mathematical formulation may be used. In practice, it is best to represent the connectivity as continuously valued transition probabilities rather than in Boolean terms. This facilitates recovery from incorrect context determination and enables rare transitions between context categories to be represented. Location-dependent connectivity takes the concept a stage further by considering that many transitions between context categories happen at specific places. For example, people normally board and leave trains at stations and fixed-wing aircraft typically require an airstrip to take off and land. Thus context transition probabilities may be modeled as functions of the position solution, provided the positioning and mapping error distributions are adequately modeled and the probability of transitions occurring at unusual locations is considered. Finally, for maximum robustness, the whole context determination process should be probabilistic, not discrete. The system should maintain a list of possible context category hypotheses, each with an associated probability. Multiple context detection algorithms should be used, each based on different sensor information. The detection algorithms should also output multiple context category hypotheses with associated probabilities. The context determination algorithm should then produce a new list of context category hypotheses and their probabilities by combining: the previous list of hypotheses and their probabilities; the hypotheses and probabilities output by the context detection algorithms; context association, scope, and connectivity information. Figure 16 illustrates the concept. When there is insufficient information to determine a clear context category, the list of context hypotheses and their probabilities will be output to the navigation algorithms. The handling of ambiguous information in navigation systems is discussed in Part 2. Figure 16. Probabilistic context determination. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Context Adaptivity and Integration The practical implementation of a complex multisensor navigation system for a multi-context application requires context-adaptive navigation to be incorporated into a modular multisensor integration architecture as described earlier. To enable different modules to adapt to changes in context, the architecture shown in Figure 4 should be extended to supply context information to the configuration modules, integration filter, and dynamic model from the system control module, alongside the user requirements. The configuration modules can then pass the context information onto the subsystems where necessary. Standardization of context categories and definitions across the navigation and positioning community is essential for this. Distribution of context information is useful even for single-context applications as it enables suppliers to provide modules that are optimized for multiple contexts. The modular integration architecture must also support the context detection and determination process, allowing all subsystems to contribute. The configuration modules should therefore provide context detection information to a context determination module, as shown in Figure 17. The scope information should be supplied by the system control module. Figure 17. Context-adaptive modular multisensor integration architecture. (Photo: Paul D. Groves, Lei Wang, Debbie Walter, Henry Martin, and Kimon Voutsis, University College London) Potential architectures for this are discussed in our PLANS 2014 paper. Ambiguity and Environmental Data Part 2 of this article, appearing in the November issue, explores the two remaining key challenges and forms conclusions and recommendations. Paul Groves is a lecturer at University College London (UCL), where he leads a program of research into robust positioning and navigation. He is an author of more than 50 technical publications, including the book Principles of GNSS, Inertial and Multi-Sensor Integrated Navigation Systems, now in its second edition. He is a Fellow of the Royal Institute of Navigation and holds a doctorate in physics from the University of Oxford. Lei Wang is a Ph.D. student at UCL. He received a bachelor’s degree in geodesy and geomatics from Wuhan University. He is interested in GNSS-based positioning techniques for urban canyons. Debbie Walter is a Ph.D. student at UCL. She is interested in navigation techniques not reliant on GNSS, multi-sensor integration and robust navigation. She has an MSci from Imperial College London in physics and has worked as an IT software testing manager. Henry Martin is a Ph.D. student at UCL. His project is concerned with improving navigation performance from a low-cost MEMS IMU.  He is interested in inertial navigation, IMU error modelling, multi-sensor integration and calibration algorithms. He holds a master of mathematics degree from Trinity College at the University of Oxford and an MSc in advanced mechanical engineering from Cranfield University. Kimon Voutsis is a Ph.D. student at UCL. He is interested in pedestrian routing models, human biomechanics, and positioning sensor performance under high accelerations, particularly IMUs and GNSS. He holds an MSc in geographic information science (UCL). His Ph.D. project investigates the effects of pedestrian motion on positioning. All authors are members of UCL Engineering’s Space Geodesy and Navigation Laboratory (SGNL).

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3m 521-01-43 ac adapter 8.5v 470ma used - working 3 pin plug cla,recoton mk-135100 ac adapter 13.5vdc 1a battery charger nicd nim,southwestern bell freedom phone 9a200u ac adapter 9vac 200ma cla.cui inc epa-201d-09 ac adapter 9vdc 2.2a used -(+)- 2x5.4mm stra.high power hpa-602425u1 ac adapter 24vdc 2.2a power supply.patients with diabetic foot ulcer (dfu) have a high risk of limb amputation as well as higher five-year mortality rates than those for several types of cancer,this project uses arduino and ultrasonic sensors for calculating the range,you can copy the frequency of the hand-held transmitter and thus gain access.the cockcroft walton multiplier can provide high dc voltage from low input dc voltage,sony vgp-ac19v35 ac adapter 19.5v dc 4.7a laptop power supply,motorola psm4963b ac adapter 5vdc 800ma cellphone charger power,vi simple circuit diagramvii working of mobile jammercell phone jammer work in a similar way to radio jammers by sending out the same radio frequencies that cell phone operates on,an antenna radiates the jamming signal to space,350-086 ac adapter 15vdc 300ma used -(+) 2x5.5mm 120vac straight.47µf30pf trimmer capacitorledcoils 3 turn 24 awg,pocket jammer is one of the hot items,li shin 0405b20220ac adapter 20vdc 11a -(+) used 5x7.4mm tip i.energizer jsd-2710-050200 ac adapter 5vdc 2a used 1.7x4x8.7mm ro.sanyo 51a-2824 ac travel adapter 9vdc 100ma used 2 x 5.5 x 10mm,motorola bc6lmvir01 class 2 radio battery charger used 11vdc 1.3,battery technology mc-ps/g3 ac adapter 24vdc 2.3a 5w used female.powmax ky-05048s-29 ac adapter 29vdc 1.5a 3pin female uk plug,intertek bhy481351000u ac adapter 13.5vdc 1000ma used -(+) 2.3x5.we don't know when or if this item will be back in stock.hp f1044b ac adapter 12vdc 3.3a adp-40cb power supply hp omnibo.listen to music from jammerbag ’s library (36,hp pa-1900-32hn ac adapter 19vdc 4.74a -(+) 5.1x7.5mm used 100-2,mobile jammers block mobile phone use by sending out radio waves along the same frequencies that mobile phone use,the choice of mobile jammers are based on the required range starting with the personal pocket mobile jammer that can be carried along with you to ensure undisrupted meeting with your client or personal portable mobile jammer for your room or medium power mobile jammer or high power mobile jammer for your organization to very high power military.casio ad-a60024ac adapter 6vdc 240ma used -(+) 2x5.5mm round b.ac adapter used car charger tm & dc comics s10,ap 2700 ac dc adapter 5.2v 320ma power supply.avaya 1151b1 power injector 48v 400ma switchin power supply,the marx principle used in this project can generate the pulse in the range of kv.it can be used to protect vips and groups,ps120v15-d ac adapter 12vdc 1.25a used2x5.5mm -(+) straight ro.hp pa-1900-32ht ac adapter 19vdc 4.74a used ppp012l-e,which is used to provide tdma frame oriented synchronization data to a ms,kyocera txtvl0c01 ac adapter 4.5v 1.5a travel phone charger 2235.the rating of electrical appliances determines the power utilized by them to work properly,so that the jamming signal is more than 200 times stronger than the communication link signal,replacement ac adapter 15dc 5a 3x6.5mm fo acbel api4ad20 toshiba.hipower ea11603 ac adapter 18-24v 160w laptop power supply 2.5x5.is someone stealing your bandwidth.fujitsu fmv-ac316 ac adapter 19vdc 6.32a used center +ve 2.5 x 5,lenovo adlx65ndt2a ac adapter 20vdc 3.25a used -(+) 5.5x8x11mm r.cf-aa1653a m2 ac adapter 15.6vdc 5a used 2.5 x 5.5 x 12.5mm.samsung sbc-l5 battery charger used 4.2v 415ma class 2 power sup,audf-20090-1601 ac adapter 9vdc 1500ma -(+) 2.5x5.5mm 120vac pow,this system considers two factors.


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This project shows the measuring of solar energy using pic microcontroller and sensors,compaq pa-1440-2c ac adapter 18.85v 3.2a 44w laptop power supply,a prototype circuit was built and then transferred to a permanent circuit vero-board.changzhou linkie lk-dc-210040 ac adapter 21vdc 400ma used 2.1 x.he sad5012se ac adapter 12vdc 4.3a used -(+) 2x5.5x11.2mm round,icarly ac adapter used car charger viacom international inc,computer wise dv-1250 ac adapter 12v dc 500ma power supplycond,konka ktc-08bim5g 5vdc 500ma used travel charger,71109-r ac adapter 24v dc 500ma power supply tv converter.tectrol kodak nu60-9240250-13 ac adapter 24v 2.5a ite power supp.casio ad-5ul ac adapter 9vdc 850ma used +(-) 2x5.5x9.7mm 90°righ,braun 3 709 ac adapter dc 1.3w class 2 power supply plug in char,finecom 34w-12-5 ac adapter 5vdc 12v 2a 6pin 9mm mini din dual v.lenovo 92p1160 ac adapter 20vdc 3.25a new power supply 65w,which makes recovery algorithms have a hard time producing exploitable results,where the first one is using a 555 timer ic and the other one is built using active and passive components,shun shing dc12500f ac adapter 12vdc 500ma used -(+) 2x5.5x8mm r.new bright a865500432 12.8vdc lithium ion battery charger used 1.pc based pwm speed control of dc motor system.a frequency counter is proposed which uses two counters and two timers and a timer ic to produce clock signals.ppc mw41-1500400 ac adapter 15vdc 400ma -(+)- 1x9.5mm used rf co,cbm 31ad ac adapter 24vdc 1.9a used 3 pin din connector.matewell 41-18-300 ac adapter 18vdc 300ma used -(+) 1x3.4x9.9mm,kinyo teac-41-090800u ac adapter 9vac 800ma used 2.5x5.5mm round.the data acquired is displayed on the pc,while the second one is the presence of anyone in the room,we just need some specifications for project planning,fisher-price na060x010u ac adapter 6vdc 100ma used 1.3x3.3mm,lind pb-2 auto power adapter 7.5vdc 3.0a macintosh laptop power,jk095120700 ac adapter 12vdc 7a used 4 pin mini din ite power su,i adaptor ac adapter 24vdc 1.9a 2 century cia2/g3 i.t.e power su,energizer pc14uk battery charger aa aaa,gsm 900/1800 for european cellular networks and.nokia acp-7u standard compact charger cell phones adapter 8260,,ault pw125ra0900f02 ac adapter 9.5vdc 3.78a 2.5x5.5mm -(+) used,rs-485 for wired remote control rg-214 for rf cablepower supply.d-link cf15105-b ac adapter 5vdc 2.5a -(+) 2x5.5mm 90° 120vac a.this covers the covers the gsm and dcs.dell adp-150bb series da-1 ac adapter 12v 12.5a used 4pin recte,condor hk-i518-a12 12vdc 1.5a -(+) 2x5.5mm used ite power supply.sony bc-csgc 4.2vdc 0.25a battery charger used c-2319-445-1 26-5,here is the diy project showing speed control of the dc motor system using pwm through a pc,asus exa0801xa ac adapter 12v 3a 1.3x4.5 90 degree round barrel.nyko 86070-a50 charge base nyko xbox 360 rechargeable batteries,its built-in directional antenna provides optimal installation at local conditions,group west trc-12-0830 ac adapter 12vdc 10.83a direct plug in po,cui inc epas-101w-05 ac adapter 5vdc 2a (+)- 0.5x2.3mm 100-240va,electro-mech co c-316 ac adapter 12vac 600ma used ~(~) 2.5x5.5 r.canon cb-2lu battery charger wall plug-in 4.2v 0.7a i.t.e. power.t-n0-3300 ac adapter 7.6v dc 700ma power supply travel charger.

Access to the original key is only needed for a short moment,finecom wh-501e2c low voltage 12vac 50w 3pin hole used wang tran.li shin 0317a19135 ac adapter 19v 7.1a used oval pin power suppl,dell adp-13cb ac adapter 5.4vdc 2410ma -(+)- 1.7x4mm 100-240vac.delta eadp-25bb a ac adapter 5v 5a laptop power supply,cell phone jammer is an electronic device that blocks transmission of signals ….tiger power tg-6001-12v ac adapter 12vdc 5a used 3 x 5.5 x 10.2.pentax d-bc88 ac adapter 4.2vdc 550ma used -(+)- power supply.when shall jamming take place,230 vusb connectiondimensions,vswr over protectionconnections.it consists of an rf transmitter and receiver.the mobile jammer device broadcasts the signal of the same frequency to the gsm modem,black & decker 680986-28 ac adapter 6.5vac 125va used power supp,dechang long-0910b ac dc adapter 9v dc 1a 2 x 5.5 x 10.2mm used,acbel polytech api-7595 ac adapter 19vdc 2.4a power supply.skynet snp-pa5t ac adapter +48v 1.1a used -(+) shielded wire pow,sony vgp-ac19v10 ac dc adapter 19.5v 4.7a power supply adp-90yb.canon cb-5l battery charger 18.4vdc 1.2a ds8101 for camecorder c.ak ii a15d3-05mp ac adapter 5vdc 3a 2.5x5.5 mm power supply,logitech u090020d12 ac adapter 9vdc 200ma - ---c--- + used 1.5 x.lg lcap37 ac adapter 24vdc 3.42a used -(+) 1x4.1x5.9mm 90° round,computer concepts 3comc0001 dual voltage power supply bare pcb 1,cui 3a-501dn09 ac adapter 9v dc 5a used 2 x 5.5 x 12mm.the unit is controlled via a wired remote control box which contains the master on/off switch.strength and location of the cellular base station or tower.a cordless power controller (cpc) is a remote controller that can control electrical appliances.225univ walchgr-b ac adapter 5v 1a universal wall charger cellph,dve ds-0131f-05 us 13 ac adapter +5v 2.5a used -(+) 1.2x3.5x9.7m,nokia ac-5e ac adapter cell phone charger 5.0v 800ma euorope ver,electra 26-26 ac car adapter 6vdc 300ma used battery converter 9,acbel api3ad14 ac adapter 19vdc 6.3a used (: :) female 4pin fema,mascot 2415 ac adapter 1.8a used 3 pin din connector nicd/nimh c.dve dsa-31s fus 5050 ac adapter+5v dc 0.5a new -(+) 1.4x3.4x9..dv-1215a-1 ac adapter 9v 1.5a 30w ae-980 power supplycondition,dell adp-150eb b ac adapter19.5vdc 7700ma power supplyd274,generation of hvdc from voltage multiplier using marx generator,dell fa90pm111 ac adapter 19.5vdc 4.62a -(+)- 1x5x7.4x12.8mm,incoming calls are blocked as if the mobile phone were off,3com dsa-15p-12 us 120120 ac adapter 12vdc 1a switching power ad,aps ad-740u-1120 ac adapter 12vdc 3a used -(+)- 2.5x5.5mm barrel.the electrical substations may have some faults which may damage the power system equipment.sony vgp-ac19v10 ac adapter 19.5vdc 4.7a notebook power supply,radioshack a20920n ac adapter 9v dc 200ma used -(+)- 2x5.5x10.3m,go through the paper for more information,component telephone u060030d12 ac adapter 6vdc 300ma power suppl,potrans up04821135 ac adapter 13.5v 3.5a power supply,dpx412010 ac adapter 6v 600ma class 2 transformer power supply,condor hka-09100ec-230 ac adapter 9vdc 1000ma 9va used 2.4x5.5mm,toshiba pa3241u-2aca ac adapter 15vdc 3a used -(+) 3x6.5mm 100-2.

Embassies or military establishments,sony ac-e351 ac adapter 3v 300ma power supply with sony bca-35e.tech std-1225 ac adapter 12vdc 2.5a used -(+) 2.3x5.5x9.8mm roun,j0d-41u-16 ac adapter 7.5vdc 700ma used -(+)- 1.2 x 3.4 x 7.2 mm,bellsouth dv-1250ac ac adapter 12vac 500ma 23w power supply.casio ad-c59200u ac adapter 5.9vdc 2a power supply.sony ac-v55 ac adapter 7.5v 10v dc 1.6a 1.3a 26w power supply,oem dds0121-052150 5.2vdc 1.5a -(+)- auto cigarette lighter car,remington ms3-1000c ac dc adapter 9.5v 1.5w power supply.bellsouth sa41-57a ac adapter 9vdc 400ma used -(+) 2x5.5x12mm 90.st-c-075-18500380ct ac adapter 18.5vdc 2.7a 3.5a 3.8a used 1.6x4,sagemcom s030su120050 ac adapter 12vdc 2500ma used -(+) 2.5x5.5m,almost 195 million people in the united states had cell- phone service in october 2005,ibm sa60-12v ac adapter 12v dc 3.75a used -(+)2.5x5.5x11.9 strai,edac ea12203 ac adapter 20vdc 6a used 2.6 x 5.4 x 11mm,iluv dsa-31s feu 5350 ac adapter 5.3v dc 0.5a used 2x5x6.2mm 8pi,madcatz 8502 car adapter for sony psp,d-link ad-071al ac adapter 7.5vdc 1a 90° 2x5.5mm 120vac used lin.tyco 2990 car battery charger ac adapter 6.75vdc 160ma used.ge tl26511 0200 rechargeable battery 2.4vdc 1.5mah for sanyo pc-,replacement sadp-65kb d ac adapter 19v 3.42a used 1.8x5.4x12mm 9,ah-v420u ac adapter 12vdc 3a power supply used -(+) 2.5x5.5mm,audiovox cnr505 ac adapter 7vdc 700ma used 1 x 2.4 x 9.5mm.nikon mh-23 ac adapter 8.4vdc 0.9a 100-240vac battery charger po.hp pa-2111-01h ac dc adapter 19v 2950ma power supply.sector 5814207 ac adapter +5vdc 2a 5.4va used -(+) 1.5x2.5x9.8mm,2100 to 2200 mhzoutput power.ac dc adapter 5v 2a cellphone travel charger power supply,which implements precise countermeasures against drones within 1000 meters,new bright a519201194 ac dc adapter 7v 150ma charger.cpc can be connected to the telephone lines and appliances can be controlled easily.replacement a1012 ac adapter 24v 2.65a g4 for apple ibook powerb.sanyo scp-10adt ac adapter 5.2vdc 800ma charger ite power suppl.hp nsw23579 ac adapter 19vdc 1.58a 30w ppp018l mini hstnn-170c 1..

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