![]() In order to re-enter configurable mode for a RadBeacon Tag, remove the front cover and press the configuration push button switch near the coin cell battery. In order to re-enter configurable mode for a RadBeacon USB, remove and restore power to the device. ![]() The Lock feature is a security precaution to limit the possibility of third party manipulation of your beacons once they have been installed and configured. Submit a valid PIN to prevent connections from remote Bluetooth 4.0 devices to the beacon configuration service. Press the Action Menu button and select Lock. Submit a valid PIN to reset the settings for your beacon to factory defaults. Reset the device to the original factory settings. ![]() Press the Action Menu button and select Reset. Submit a new and existing PIN to update the PIN for your beacon. Press the Action Menu button and select Update PIN. Validate the accuracy of your beacon settings by quickly verifying the ranging behavior of your device in proximity to your configured beacon. Press the Action Menu button and select Range. ![]() Update the measured power value with the results of your calibration activity and update your settings. Press the Action Menu button and select Calibrate.Ĭalibrate the measured power value of the beacon settings to ensure optimal proximity events and ranging. Submit a valid PIN to update the settings for this beacon. (If the RadBeacon is not configurable, then an "unable to connect" message will be displayed after approximately 15 seconds.) The settings displayed include: If the RadBeacon is configurable, its detailed settings will be displayed. Each beacon discovered is displayed with the following summary details Scan for nearby configurable RadBeacons by pressing the SCAN button. Once discovered, if the beacon is configurable, you can display each beacon's operating settings and make modifications to those settings. With the RadBeacon app you can scan for nearby Radius Networks beacons. The RadBeacon app from Radius Networks requires an Android device running Android 4.3 or higher and equipped with Bluetooth 4.0 capabilities. We performed extensive experiments and our results show that the proposed beacon based micro-location system can be used to locate a user in an indoor environment with an error as low as 0.27 meters.The RadBeacon™ app is the configuration utility for RadBeacon proximity beacons from Radius Networks that support Apple's iBeacon™ proximity services and the AltBeacon proximity services for Android devices. We propose to leverage a control theoretic approach, namely particle filtering, in order to increase the tracking accuracy in an indoor environment. In this work, we propose to use the cutting edge and commercially available Apple’s iBeacon protocol and iBeacon BLE sensors for micro-location. At the same time, each vendor would install different technologies. Although several technologies have been used for tracking purposes, the accuracy has always been a serious issue. This is a requirement of many IoT user-centric applications for indoor environments. Tracking a user with high accuracy is known as Micro-Location. Due to the lower energy consumption and higher throughput, BLE could therefore be an integral pillar of an Internet of Things (IoT) Location Based Service (LBS). The advent of Bluetooth Low Energy (BLE) enabled Beacons is poised to revolutionize the indoor contextual aware services to the users. We also discuss remaining challenges to accurate indoor localization. Rather than comparing the technologies or techniques, we compare the localization systems and summarize their working principle. In contrast with the existing surveys, we also evaluate different systems from the perspective of energy efficiency, availability, cost, reception range, latency, scalability and tracking accuracy. We highlight the strengths of the existing systems proposed in the literature. The paper primarily discusses localization and positioning of human users and their devices. In this paper, we aim to provide a detailed survey of different indoor localization techniques such as Angle of Arrival (AoA), Time of Flight (ToF), Return Time of Flight (RTOF), Received Signal Strength (RSS) based on technologies such as WiFi, Radio Frequency Identification Device (RFID), Ultra Wideband (UWB), Bluetooth and systems that have been proposed in the literature. However, there is a lack of an up-to-date survey paper that incorporates some of the recently proposed accurate and reliable localization systems. Different techniques, wireless technologies and mechanisms have been proposed in the literature to provide indoor localization services in order to improve the services provided to the users. Indoor localization has recently witnessed an increase in interest, due to the potential wide range of services it can provide by leveraging Internet of Things (IoT), and ubiquitous connectivity.
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