An Evaluation of Indoor Location Determination Technologies

Transcription

1 An Evaluation of Indoor Location Determination Technologies Kevin Curran, Eoghan Furey, Tom Lunney, Jose Santos, Derek Woods, Aiden Mc Caughey Intelligent Systems Research Centre Faculty of Computing and Engineering, University of Ulster, Northern Ireland, UK Abstract The development of Real Time Locating Systems (RTLS) has become an important add-on to many existing location aware systems. While GPS has solved most of the outdoor RTLS problems, it fails to repeat this success indoors. A number of technologies have been used to address the indoor tracking problem. The ability to accurately track the location of people indoors has many applications ranging from medical, military and logistical to entertainment. However, current systems cannot provide continuous real time tracking of a moving target or lose capability when coverage is poor. The deployment of a real time location determination system however is fraught with problems. To date there has been little research into comparing commercial systems on the market with regards to informing IT departments as to their performance in various aspects which are important to tracking devices and people in relatively confined areas. This paper attempts to provide such a useful comparison by providing a review of the practicalities of installing certain location sensing systems. We also comment on the accuracies achieved and problems encountered using the position-sensing systems. 1 Introduction Mobile devices are associated with network technologies that have the potential to provide user location and context cues to the services they offer. Location data alone has little value, but when it is used to expand the variety of mobile applications through timely, personalised content reactive to dynamic environments, it offers great return for very little additional bandwidth use. The ability to track and check the location of people or equipment in real time has a large number of application areas such as child safety, prisoner tracking and supply chain to name but a few (Krzysztof & Hjelm, 2006; Cooper et al., 2010). Over the past two decades a large number of commercial and research positioning systems have been developed (Hazas et al., 2004). Generally, these systems have the constraint of providing lower accuracy over a wide coverage area or providing high accuracy (<30 cm) in a small area. Accuracy systems often require extensive infrastructure, many sensors and time consuming calibration. AT&T Cambridge s Active Bats system (Addlesee et al., 2001) used ultrasonic badges and required one ultrasound receiver to be installed every square meter.

2 Radio Frequency Identification, is a technology used for the automatic identification and tracking of goods, animals and people. It requires each person or piece of equipment that is to be tracked to have a RFID tag attached and RFID tag readers to be installed in the mobile device. There are two types of RFID tags, active and passive. Active tags have a small power supply used to send out a signal that gives them a range of up to 100 meters while the passive tags have no power supply and are activated by a scanning signal which means they typically have a range of detection of less than a meter. A typical system consists of three parts a transponder, a reader, and a controlling application. Transponders hold data on the person or object they are attached to, usually containing a unique code used for identification, such as a serial number. When within an appropriate range of a reader, the transponders transmit this data to the reader using radio. The reader decodes this radio signal into digital information, which is then relayed to a computer application that makes use of it. RFID technology is extremely widespread, used in many different applications such as security systems, public transport payment systems, the tracking of commercial goods, and livestock identification. Wi-Fi location determination is a technology that has been developed in recent years to offer existing Wi- Fi enabled devices a positioning service. The technology uses modulated Wi-Fi transmission signals to detect the presence of a device: the system is able to triangulate the position of the device based on the signals received from the other Access Points (AP). One of the first examples of using Wi-Fi1 for location fixing was RADAR (Bahl & Padmanabhan, 2000; Krzysztof et al., 2006) developed at Microsoft. Microsoft also developed RightSPOT, which used a ranking system of available Frequency Modulation (FM) radio stations rather than their relative signal strengths to determine location. With eight radio stations they were able to get an accuracy rate of approximately eighty percent (Krumm et al., 2003). Indoor positioning is especially useful in large buildings like hospitals, university campuses and various business premises. Systems have been based on a range of 'signals of opportunity' such as ultrasound or Wi-Fi signals. These can be standalone signals that are not used for communication such as Ubisense which uses Ultra Wide Band (UWB) radio signals, or they can be based on existing communication signals like Ekahau which uses Wi-Fi signals (Steggles & Gschwind, 2005). An advantage of indoor positioning is that because of the short range of these technologies, power consumption is usually fairly low. Also, accuracy levels can be quite high, but this depends on the system used. On the downside, these systems cannot compete with GPS or Cellular positioning systems in terms of universal coverage and they often need to be calibrated, leading to larger roll-out costs in terms of time. This paper attempts to provide an overview of key features in a number of commercial indoor location tracking systems. The systems use a variety of underlying wireless standards such as RFID and WiFi. The paper provides an overview of the systems tested and also provides insights learned from installing them on a university campus with the intention of evaluating them against criteria such as ease of use and accuracy. 2 Indoor Positioning Systems The following sections give an overview of a number of currently used indoor positioning systems. The LA200 is a Wi-Fi network based system which uses the existing network hardware and devices already deployed. Trapeze claims that all the calibration can be done from a central point but this only gives RSS fingerprints at the access point locations. Like many commercial systems, much manual

3 tweaking is necessary to get satisfactory levels of accuracy. The underlying methods of positioning are also based on fingerprinting. The LA200 contains an API for further development. The LA200 has a granularity of five minutes without additional network load and then stores all this data for each device for a maximum of thirty days at a ten meter precision level so it can attempt to locate all devices to a room level. Ubisense 1 is a real time location system (RTLS) built on Ultra Wide Band (UWB) radio technology. The system is composed of UWB active tags (ubitags), sensors and a software platform. Active battery powered Ubisense tags enable positioning by transmitting UWB pulses. Sensors receive these pulses from the tags which must be positioned around the test area in a way that gives complete directional coverage of the test area. A software platform carries out the positioning calculations on the data received from the sensors. Each area to be tested must have its own network of sensors, i.e. each room. These areas can be integrated to give continuous positioning information even when the target moves from one area to another. This works in a similar manner to mobile phone cells transferring control from one to the next. Each sensor determines the Angle of Arrival (AoA) of the signal from the tag. If two or more sensors are connected in the test area it is possible to include Time Delay of Arrival (TDoA) along with AoA measurements. This gives a 3D location estimate with accuracy levels of 15 cm (Steggles & Gschwind, 2005). The tags can respond to an event in less than 100 ms and the battery life is claimed to last up to 5 years. The Ubisense system also contains a.net 2.0 API for custom application development. Ekahau's 2 Java based system contains of a number of main parts which include: (1) The Ekahau Positioning Engine (EPE), (2) the Ekahau Site Survey and (3) the Ekahau Client. The Client communicates with the mobile device s Wi-Fi chip and retrieves the RSSI information and passes this along to the EPE. The EPE is a positioning server that provides the location coordinates (x, y, and floor) of the mobile terminal or Wi-Fi tag. The Ekahau manager merges information from the EPE and the Client and also provides applications for site calibration (Ekahau Site Survey) and live tracking. A noteworthy element of the Ekahau systems is their proprietary Rails software which allows for tracking to be carried out in a way that replicates human movement and eliminates the jumping through walls effect. The Rails are added by an administrator to teach the solution where devices are able to travel. The software views the area where the rails are placed as a higher probability of true location. Ekahau can use a network, terminal or terminal assisted approach. It also comes with an Application Programming Interface (API) to enable custom applications to be developed. Trolley Scan s RFID-radar 3 system is an example of an indoor RFID based location determination system that has the accuracy capability of less than fifty centimetres in an area up to one hundred meters deep, however this depends on the tags used and may be as little as ten meters. The system can track up to fifty tags and locate their position within a few seconds. The system has three main components, the reader, the antenna array and the tags. The reader measures the distance of the signals from the tags, the antenna array for energising the tags and finally the tags themselves

4 3 Evaluation of Location Determination Systems RSSI is the most crucial parameter in the localization of WLAN devices. One of the most important factors in the measurement of RSSI is the power attenuation due to distance; however absorption gradient also affects the RSSI measurement. Sudden changes in signal absorption, due to walls for example, introduce discontinuities into the dependence between RSSI and distance that is normally considered a smooth function (Nafarieh & How, 2008). In addition to walls, the presence of humans, the direction of the antenna, and the types of WLAN cards have an effect on the absorption of the RF signal energy. Throughout our study, we attempted to recreate environments as close to the real world conditions as possible. The RSSI values can be reported by the device driver as a non-dimensional number or percentage and sometimes is converted to dbm through some nonlinear mapping process (Bardwell, 2005). Since the RSSI measurements are dependent on different laptop / antenna positioning (e.g., height of the mobile card), antenna orientations were controlled. The average of all data in all directions was used to create the vector for the particular measurement point. We found that the antenna orientation could cause a variation in RSS level of up to 10 dbm. This effect cannot be ignored when considering the impact different orientations have on RSSI measurements reliability and eventually on the localization accuracy documented here (Li et al., 2005), relating to: (1) Trapeze Networks LA-200 (2) Ubisense Precise RTLS (3) Ekahau RTLS and (4) Trolley Scan RFID-radar. 3.1 Trapeze Networks LA-200 The Trapeze LA200 is a location appliance from Newbury Networks. Physically it is a rack server and was slotted into the central IT services server room. The LA200 can sense any wifi device in the environment and these devices do not need to be associated with an access point. This allows a device with a weak signal which otherwise would not be allowed to connect to be tracked. It also allows devices to connect which do not need to be running client software. However the LA200 is also compatible with any compatible active tags from Newbury Networks, Pango, AeroScout or Ekahau. Figure 1: LA200 Locales visible in Dashboard application

5 Once setup was complete, the fingerprinting began. This involved the uploading of maps for each floor to be mapped. Locales are defined so as to define regions for clarity (see Figure 1). For instance, a corridor may be irregularly shaped but the locale allows this type of region to be defined such as for instance second floor hallway. Fingerprinting was done holding a Newbury tag whilst selecting current locations on the map and defining locales. Graphical bars in the dashboard application show the strength levels of the signal for each locale. Figure 2: Device view Devices can be tracked and viewed using the dashboard application. For instance, Figure 2 shows a laptop associated with an access point and located in an academic office. Views may be created which allow searching for particular devices, groups of devices, devices in particular locales and more. Historical movement of devices can also be viewed and downloaded. The LA200 can also be queried through its API. Applications can be built on top and Trapeze supply a new application called Active Asset (See Figure 3) which allows the system to immediately respond with the location of a device on the map. Figure 3: Active asset showing all devices on MS first floor

6 Figure 4: Asset Tag History from Active Asset Application The active asset software also allows the querying of history from any device that has been tracked. Figure 4 shows the locations which a tag with mac address 00:18:8E:20:1A:85 has visited. It shows the start time and end time and duration in that locale. 3.2 Ubisense The Ubisense RTLS solution utilizes battery-operated radio tags and a cellular locating system to detect the presence and location of the tags. The locating system is usually deployed as a matrix of sensors that are installed at a spacing of anywhere from 50 to 1000 feet depending on the site layout. These sensors determine the locations of the radio tags. Ubisense consists of Tags - designed to be mounted on assets or to be worn by a person; Location Engine software to install and tune a Ubisense sensor network and track tags in real time, through a series of configuration wizards and the Location Platform software which provides persistent storage and distribution of real-time location events for multiple clients in conjunction with real-time monitoring and notification of user-specified spatial interactions between objects. The Ubisense Series 7000 sensor is a precision measuring instrument containing an array of antennas and ultra-wideband (UWB) radio receivers. The sensors calculate the location of the tags based on reception of the detected UWB signals transmitted from Ubitags. Each sensor independently determines both the azimuth and elevation Angle of Arrival (AOA) of the UWB signal, providing a bearing to each tag. The Time Difference of Arrival (TDOA) information is determined between pairs of sensors connected with a timing cable. Sensors are administered remotely using standard Ethernet protocols for their communication and configuration. They work in standard wired and wireless environments, using networking infrastructures, such as access points, Ethernet switches and CAT5 structured network cabling for communication between sensors and servers. The tests were carried out in the same room used for the RFID-radar tests along with the same calibrated locations shown in Figure 5. Each of the four sensors were mounted high in the corners of the Lab and pointed towards the floor in the middle of the room. Each sensor network cable was connected to an 8 port Ethernet switch. The sensor in the top-left of the map (near location (0,5)) was chosen as Master and

7 we connected a timing cable (unshielded CAT5 Ethernet straight-through cable) from each slave to a timing socket on the back of the Master case. Ubisense recommend that the timing cables be shielded and rated as CAT5e or better and that preferably be factory made. Figure 5: Room MG281where locations for experiments are spotted in red A coordination system must be defined. We choose the origin (0,0,0) near the column in the centre of the room with a right-handed co-ordinate system. Calibration was done with a slim-tag in five uniformly distributed points in the room. It is important to avoid those points that were not in LoS with the four sensors and in each location we waited 10s before moving to the next one. In the actual testing, the tag was left for 30s at each location before we read the measurement. The slim tag was also placed one meter above the floor. Overall the error distance for static tags was on average 0.89 meters. Location Tag ID Ubisense Real Range accuracy(m) location(m) location(m) (1,0) ,25 from B -0,62 from A -2,60 from B -0,10 from A -0,65 from B -0,52 from A (1,1) ,25 from B -2,17 from A -2,60 from B -2,00 from A -0,65 from B -0,17 from A (1,2) ,89 from A -3,69 from B -4,30 from A -2,60 from B -0,44 from A -1,09 from B (0,0) ,30 from B -0,56 from A -0,10 from B -0,10 from A -1,20 from B -0,46 from A Table 1: Results of experiments with low range accuracy due to the presence of obstacles Table 1 reports the results for those locations where the range accuracy was low due to the presence of obstacles in the path. For instance, Figure 6 shows the Ubisense Location Engine results for position (1,0) where location reported is not accurate.

8 Figure 6: Poor results obtained by Ubisense Location Engine for position (1.0) Table 2 illustrates some locations where the system reported good accuracy. Figure 7 shows the actual Ubisense Location Engine results for position (2,0) where location reported is accurate. Location Tag ID Ubisense location(m) Real location(m) Range accuracy(m) (0,4) ,66 from B -4,02 from C -0,10 from B -2,60 from C -0,56 from B -1,42 from C (1,3) ,63 from B -3,69 from C -2,60 from B -4,30 from C -1,03 from B -0,61 from C (2,0) ,18 from D 0,66 from A -4,30 from D -0,10 from A -0,88 from D -0,76 from A (2,1) ,68 from D -2,57 from A -4,30 from D -2,00 from A -0,38 from D -0,57 from A (2,2) ,30 from D -4,30 from A -4,55 from A -3,63 from B -0,25 from A -0,97 from B (2,4) ,68 from D -2,31 from C -4,30 from D -2,60 from C -0,38 from D 0,31 from C Table 2: Some selected locations with good accuracy measurements Figure 7: A good result obtained by Ubisense Location Engine for position (2,0)

9 3.3 Ekahau The Ekahau Real Time Location System is a software suite that uses an existing WLAN network without the need for additional special network hardware to determine the location of a Wi-Fi equipped device. The suite has three main components namely the Ekahau Site Survey (ESS), the Ekahau Positioning Engine (EPE) and the Ekahau API that utilises the EPE system to create custom applications. The EPE uses software-based algorithms to calculate the position of a tag. However before the EPE can determine the location work it needs the site survey calibration information from the ESS. The ESS collects the information on the coverage and RSSI of each AP in the network across the area to be covered. The ESS gathers the calibration information by a person carrying the system and walking around the area to be covered. The Ekahau Positioning Engine allows the pinpointing of items such as Wi-Fi laptops, PDAs, tablet PCs, barcode scanners, hospital telemetry devices, wireless VOIP phones or people wearing tags or carrying these devices. The Ekahau client runs on a client device such as a PC laptop or PDA. The Ekahau Positioning Engine service runs on a desktop PC or (PC/Unix) server and calculates the client device x,y co-ordinates and area name. The Ekahau Manager is an application for recording the field data for a positioning model (Ekahau Site Calibration), tracking client devices on a map, and analyzing the positioning accuracy. Finally, the Ekahau Application Framework and SDK is a set of helpful tools and easy programming interface for authorized applications to quickly utilize EPE location information. EPE supports both a zone based tracking, to report the device location by zone name, and also a continuous real-time positioning of precise (x, y, floor) location coordinates. The Ekahau client is fully IEEE a/b/g compliant and runs in the background while still leveraging the Wi-Fi data and voice capabilities for other applications. Figure 8: Calibration Quality (Red = Low quality, Green = High quality) Ekahau Site survey records RSSI data of the test area with all observable aspects of the WLAN being considered. RF characteristics e.g. multipath and reflection are recorded and do not harm location accuracy or signal measurement. This survey data then facilitates building tracking models. The observed client data is recorded and each recorded location is assigned a probability based on this data. Figure 8 illustrates the calibration quality for one floor. Red indicates locales of poor fingerprinting quality whilst areas of green indicate high quality calibration information. Ekahau Site Survey (ESS) is their software tool for Wi-Fi network planning and administration. ESS gives a ground-level view of coverage and

10 performance for creating, improving and troubleshooting Wi-Fi networks. ESS can provide tools for network deployment and troubleshooting that are not provided by the centrally managed Wi-FI systems. Network issues that are invisible to the wireless management systems may indeed by more easily identified and resolved with ESS. Figure 9: Rails and free space Before you can calibrate an area, you have to draw "rails" in the Ekahau Manager program. Rails are walking paths where it is assumed people will walk (see Figure 9). Figure 10: Signal Strength Ekahau uses its own probabilistic location detection algorithms giving 1-3 metres accuracy in ~ 5 seconds. A process of normalization is applied which allows for the use of hardware from different vendors. Figure 9 illustrates how each dot represents a fingerprint. RSSI fingerprinting facilitates creating radio maps and pin-pointing device locations (see Figure 10). All tags in the systems may be monitored at all times and detailed information is given on each one through the Vision application. Various rules may be set up and applied to control the movement of tags and devices for instance rules can be setup to trigger alarms when tags enter certain zones (e.g. Lab B, outer perimeter) and this information may also be output in report form. 3.4 RFID

11 RFID has seen widespread use across many different applications. The vast majority of these applications, however only use the data contained in tags within the reader s zone, rather than the location of the tag at any given time. Radio Frequency Identification tags can be easily added into most everyday objects. Trolley Scan s RFID-radar (rfid-radar.com, 2007) is an example of an indoor RFID based location determination system that has the accuracy capability of less than fifty centimetres in an area up to one hundred meters deep, however this depends on the tags used and may be as little as ten meters. The system can track up to fifty tags and locate their location within a few seconds. The system has three main components, the reader, the antenna array and the tags. The reader measures the distance of the signals from the tags, the antenna array for energising the tags and finally the tags themselves. The RFID-radar reader measures the distance of signals travelling from transponders and provides an energy field to power them. The processing module can report the identity, position in 2D or 3D space, and movement at one-second intervals of any tags in the reader zone. Its location accuracy is within 50 centimetres and its pointing accuracy is to within one degree. The antenna array contains one transmit antenna for energising the passive transponders and one antenna for each receiver, giving a total of three antennas in the array. By comparing the ranges on both receivers, the angle of arrival can be calculated, allowing the system to show the range and direction of a tag at the time of reading. By measuring the range many times per seconds, the system can plot the path of moving transponders. An example stream, showing data for multiple tags, is shown in Figure :45:08 BCBBB :45:08 BCBBB :45:08 BCBBB :45:09 BCBBB :45:09 BCBBB :45:09 BBBBB :45:09 BCBBB :45:09 BCBBB :45:09 BCBBB :45:09 BCBBB :45:09 BCBBB :45:09 BCBBB Figure 11: RFID Radar Screen Output: the columns, from left to right indicate the time of the tag report, the tag ID, the range of tag in meters and angle of the tag from the reader s centre-line We evaluated the base performance of the RFID-radar by comparing the estimated location with the true location of tags in an indoor scenario. Tags with two orthogonal or nearly-orthogonal antennas, often known as dual-dipole tags, are much less dependent on orientation and polarization of the reader antenna, but are larger and more expensive than single-dipole tags. We tested just single-dipole tags, so the measurements were strictly dependent on their polarization. The antenna was horizontal to the ground and also the tags had to be horizontal to the ground. To minimise multipath problems an appropriate indoor test scenario was chosen to test the systems accuracy and we also verified the performance of the system through the following characteristics. With regards to the location estimates, we looked for sufficient precision so that the reported position should be within the range accuracy stated by the maker and systems operation should not interfere with other systems nor crash in active environments. With regard to tracking performance the tracking system

12 should not make jumps that the tracked object would never perform and the trace of the target on screen (or in database) should resemble the actual motion of the target. To respect all these constraints, the experiments were carried out in the first floor of MG building in the Magee Campus of the University of Ulster, in a room without people but containing office furniture (desks, chairs, bookcases and similar). All experiments for the RFID radar were carried out in the same lab as the system could not penetrate walls. Dots on the map in Figure 12 are the calibrated locations. (0,0) (0,1) (0,2) Obstacle4 (0,3) (0,4) (0,5) Obstacle3 (1,0) (1,1) (1,2) (1,3) (1,4) (1,5) (2,0) (2,1) Obstacle5 (2,2) (2,3) (2,4) (2,5) Obstacle2 RADAR ANTENNA (3,0) (3,1) (3,2) (3,3) (3,4) (3,5) Obstacle1 READER (4,0) (4,1) (4,2) (4,3) (4,4) (4,5) Figure 12: Room MG281 with all calibrated locations One design consideration for the evaluation was how the system would translate positional data from the RFID-Radar system to a graphical representation shown on our prototype map. The system was calibrated for the area to be monitored by placing a transponder at the far edge of the area and storing its range information. This total range, shown in Figure 13 was then used in calculations to depict the relative position of transponders to the equipment on the on-screen map. Figure 13 shows the layout of a simple room to be monitored using the RFID-Radar system. Monitored Area Original Transponder position for calibration Real-World Total Range / Centre Line Range Reading Angle RFID Radar Antenna Transponder On-Screen Map John Smith Tracker

13 Figure 13: Tracking a Transponder after Calibration Figure 14 shows how we translated location data from a transponder onto the map in the GUI. It can be seen that a transponder s range and angle reading, together with the centre line, defines a right-angled triangle. With trigonometric calculations, and the known total range, the triangle could be scaled down so that the icon depicting the tag will appear on the map in the location corresponding to the real tag s location. Centre-Line 15 Person with Tag 6m (Range of Tag) Tag Tracked On Screen Radar System Antenna On-Screen Map. Figure 14: Overview of System Each object (person) to be tracked in the tests was assigned an RFID tag containing a unique ID. The reader in the RFID-Radar system retrieves this ID and calculates the location of the tag. After an unstable setup phase the tag s range reports settled on a value near 4m. Once the tag was moved, the RANGE command had to be submitted to the equipment to recalculate the new range, which took an average of 30 seconds. Sometimes the newly-calculated range was inaccurate, e.g. increasing from 4m to 9m when moving the tag closer to the antenna. The main problem unearthed was that the reader was not able to report a correct range or a Tag ID for those locations that were not in line of sight (LoS) with the antennas. LoS is a restrictive requirement since in a typical indoor environment there are lots of obstacles between the tags and the Antennas. In the room there are some metal obstacles drawn in grey in Figure 12. For static measurements (i.e. objects were not moving), the average error distance of RFID-radar was found to be 4.19m. ( 0,0 ) ( 0,1 ) ( 0,2 ) ( 0,3 ) ( 0,4 ) ( 0,5 ) O b s t a cl e4 O b s t a cl e3 (1,0 ) ( 1,1 ) ( 1,2 ) ( 1,3 ) ( 1,4 ) ( 1,5 ) O b s t a cl e5 O b s t a cl e 2 ( 2,0 ) ( 2,1 ) ( 2,2 ) ( 2,3 ) ( 2,4 ) ( 2,5 ) A N T E N N A ( 3,0 ) ( 3,1 ) ( 3,2 ) ( 3,3 ) ( 3,4 ) ( 3,5 ) O b s t a cl e1 R E A D E R ( 4,0 ) ( 4,1 ) ( 4,2 ) ( 4,3 ) ( 4,4 ) ( 4,5 ) Figure 15: Locations where RFID-radar failed to locate tags in red (Good spots are in bold green)

14 Figure 15 shows the locations in red where the radar failed to log the tag. The bold lines in green highlight locations (2,0), (2,1), (2,2), (2,4) and (2,5) where the Radar had good measurements from the tags. Finally, we tested the ability to track relatively fast moving objects. When the distance of the Tags to the antenna is small, the accuracy should be high, however when the read range starts increasing, then uncertainty is introduced into the system. Here we used the single speed Claymore tag. Figure 16: Room MG281 with the test navigation path The path navigated for tests shown in Figure 16 was traversed at a very slow walking pace. The average length of each walk was 2 minutes and the sampling rate was 30s. Obstacles caused the reader to lose the tag thus the accuracy of measurements was poor. We found the radar to require~10-20s to determine the exact position of tags. We found this seriously limiting and would only recommend for static situations where transponders are relatively stationary. However, in reality devices to be tracked are not fixed to a location 21. Here we found the average error distance for slowly moving devices was 10m. 4 Findings To assess the applicability of the positioning systems evaluated here, a number of metrics were applied including accuracy and precision, yield and consistency, latency and roll out and operating costs. Accuracy is concerned with the closeness of position fix to the true position. Precision deals with the closeness of position fixes to their mean value. Yield is the ability to get position fixes in all environments and consistency is the stability of the accuracy in different environments. Latency is the time delay between each position fix and Time To First Fix (TTFF) depends on the type of System used. Indeed, a high TTFF is often a factor in the popularity of positioning systems with everyday users. Roll out and operating costs are the costs involved with setting up the infrastructure whilst operating costs depend on the complexity of the infrastructure (Stantchev et al., 2008).

15 We found that the LA200 system easily allowed logging of time associated with individuals in various locales over a period. The LA200 also integrated with a smartpass system from Trapeze that allowed location to be used to control network access. The system was tested in two buildings over a 9 month period. Straightforward can you see me now trail runs were conducted and on average the system could detect devices to room level 70% of the time. The accuracy was measured at approximately 25 meters. Overall, the system produced accurate traces provided the initial fingerprints were good. There are a number of limitations including cost and specialist knowledge needed to integrate the LA200 into existing enterprise systems, and the system needed rebooting on average every eight weeks. The ultra wideband based Ubisense system was non-trivial to install. Cables circulated the lab in most directions along the exterior walls and simply were messy and almost a hazard. Of course, if a building can be developed from the ground up then cables can be hidden but there are many scenarios which seek a location sensing system (e.g. museum, library) where cables have simply got to run along the wall. We also found that the Ubisense sensors needed to be adjusted using a spirit level to have no roll as sensors with non-zero roll will exhibit poor performance tracking those tags that are near the edge of their visible field. We had to recalibrate a number of times as readings were ad hoc on occasions. The associated software installation was a little more complex than similar systems tested. Obstacles in the room were also found to interfere with the readings. Latency was low while roll out costs were high. It was found that the RFID Radar system, even with accurate tag location data, had a delay of nearly a minute when calculating the location of a new tag that has entered the radar s field of view, and a similar delay when updating tag data when the tag had moved. These delays would mean that RFID-Radar would be impractical for applications that require accurate real-time locations of moving objects or people over large areas. The RFID-Radar equipment would function best in a large, open environment, with few obstacles and no interference from other RF devices. Suitable applications may include locating stock in an open-plan warehouse, or the location of a parked car in a car park. Delays in updating tag positions would not be critical in these situations, as the tags would most likely be stationary when using the system. Ekahau provided the good results for position-sensing using standard WLAN technology. The Ekahau system was easy to set up and required little work in the fingerprinting phase. It also mapped quite accurately throughout. The RFID Radar prevailed in some scenarios in which a tag was moving fast but with good line of sight. The strength of the LA200 lay in the fact that it did not need software on the clients and it did not require devices to associate with each access point. Only the appearance of a device in range of an AP was sufficient for detection. Ubisense whilst accurate when in a good line of sight is cumbersome with the mandatory cabling between sensors and the switch/hub. The installation of a DHCP server and software was also non-trivial at one particular location. Ubisense we feel is more tailored towards large open spaces where line of sight is guaranteed and fine-grained location determination is a necessity. One example would be a factory line. The RFID Radar had a limited range and here again it would be more suitable to open spaces or niche markets such as tracking items that pass through an archway. Finally, it is worth noting that to successfully deploy a positioning systems based on WLAN, some aspects must be considered and planned carefully (Zhou, 2004) such as the number of access points. At least 3 access points are needed but 5 to 6 access points would be ideal. It is important to note that more access points do not enhance coverage. In relation to this, the locations of access points should be strategic. The distance between two adjacent calibrated locations should not be too large ~ 1-2 meters is

16 fine and each location should have enough calibration samples (e.g. 200 to 300 samples). It can be important to give denser calibration locations to the areas which may be confused with other areas and finally to ensure that during the calibration/fingerprinting process that one walks slowly, stopping regularly for up to 30 seconds for increased accuracy (Zhou, 2005). 5 Conclusion Every location determination technology has its advantages and disadvantages in a number of areas namely; if they are designed to operate inside or outside, how they determine their position internally or via a network connection, their cost, their susceptibility to interference and their location determination accuracy. There is much potential for applying position-sensing technology, for example to enhance security such as perhaps enforcing limited access areas by alerting security when an unauthorized person enters a restricted area. It can also monitor and protect objects that should not move without proper authorization, such as expensive spectrum analyzers or laptops. In our evaluation, we considered technologies already in use to track PDAs and mobile computers that are also compatible with the existing standard WLAN infrastructure. We recorded the various stages of a case study that investigated the use of location determination applications. It presented a comprehensive investigation into the various RFID, Ultra wideband and Wi-Fi location determination methods and technologies and their uses and seeks to provide a review of available position- sensing technologies. It could also be stated that the non location tracking systems include ones such as ultra-wideband, active RFID, ultrasound and other RF-based systems for the most part require installation of proprietary and single-purpose antennas, and dedicated staff to deploy, manage and maintain. Some of these technologies such as active RFID, are problematic in certain scenarios because they can introduce possible interference with Wi-Fi networks and critical patient care equipment. 125 khz chokepoints have been banned by many hospitals around the world because they can interfere with clinical equipment in hospitals and ZigBee can adversely impact a customer s existing Wi-Fi network that is used for primary voice and data communications. These aspects are not to be underestimated and may indeed strengthen the hand of the location tracking systems in the future. Acknowledgements This research was supported by funding from JA.NET UK. We would like to acknowledge the following individuals who also performed experiments on the various location tracking systems providing useful data. These individuals are Annie Cadau, Carmelo Giuffri, Stephen Norrby, Jude McGlinchey, Colm McMenamin, William McDevitt, James Knox and Robert Woolmore. References

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