A system for determining the location of a wireless device is described, the system includes a map, a fixed beacon, a fixed sensor and a server component. The server component receives a beacon identifier and a beacon signal strength from a wireless device. A sensor is located on the map. The fixed sensor receives the beacon identifier and the sensor captures a measured sensor beacon signal strength. The sensor is communicatively coupled to the server component. The server component receives the beacon identifier and the measured sensor beacon signal strength from the fixed sensor. The server component uses the beacon identifier and the beacon signal strength communicated by the wireless device and the sensor beacon signal strength and the beacon identifier received by the sensor to determine the location of the wireless device.

A system for determining the location of a wireless device is described, the system includes a map, a fixed beacon, a fixed sensor and a server component. The server component receives a beacon identifier and a beacon signal strength from a wireless device. A sensor is located on the map. The fixed sensor receives the beacon identifier and the sensor captures a measured sensor beacon signal strength. The sensor is communicatively coupled to the server component. The server component receives the beacon identifier and the measured sensor beacon signal strength from the fixed sensor. The server component uses the beacon identifier and the beacon signal strength communicated by the wireless device and the sensor beacon signal strength and the beacon identifier received by the sensor to determine the location of the wireless device.

Methods and systems disclosed herein utilize location signals received from beacons and other indoor positioning systems along with an application program on customer devices for better management of customer traffic in physical queues and virtual queues, specifically in environments such as airports, food courts, shopping malls, and amusement parks. These methods and systems also provide a customer with a token for his place in the queue on his mobile device, so he is free to continue with his activities until it is time for him to acquire a product or a service.

Systems and methods for automatically locating web-based social network members are provided. According to one embodiment, contact content including an associated GPS identifier and status for web-based social network members located at or near the same location automatically appears on a GPS-enabled device. A further exemplary system includes a GPS-enabled device configured to receive a GPS identifier and a status representing a location and a current state for a web-based social network member, a processing module that associates the received GPS-identifier and the received status, and a communications module that sends the associated GPS-identifier and status to a server comprising a web-based social network database. Contact content in a web-based social network database record in the web-based social network database is updated to include the associated GPS identifier and status for the web-based social network member.

A system and method is provided for using information broadcast by devices and resources in the immediate vicinity of a mobile device, or by sensors located within the mobile device itself, to ascertain and make a determination of the immediate environment and state of the mobile device. The sensor data is then used to identify situational profiles to target and determine the relevance of apps, advertisements, content, and recommendations.

Systems and methods for passive dynamic geofencing on a mobile device are discussed. For example, a method for passive dynamic geofencing can include operations such as monitoring a first parent geofence and a first plurality of child geofences; detecting crossing a boundary of the first parent geofence into a second parent geofence; loading the second parent geofence and a second plurality of child geofences encompassed by the second parent geofence; and monitoring the second parent geofence and the second plurality of child geofences.

A transportable container is enabled with radio frequency identification (“RFID”) technologies to maintain automated inventory levels of those items that are inside the container. The inventory data is communicated via wireless methods, such as cellular or Wi-Fi, to a remote device such as enterprise resource planning (“ERP”) system. The ERP system may use the inventory data received from the remote device to automatically update appropriately and generate appropriate records (e.g., container inventory, restocking, invoicing, etc.). In some embodiments, automated RFID scans are triggered when the container is opened and subsequently closed. The container may include RF containment/screening to prevent inadvertent scanning of RFID tags outside of the container. The container may also include a location device to allow the location of the container to be readily determined.

A mobile device may receive updates, support and other data from a current data center agent platform. When the mobile device travels to another location the nearest data center agent may be different from the previous agent. A changeover determination must be performed prior to determining whether the new agent should be assigned to the mobile device. One example method of operation may include receiving current location information of the mobile device and identifying a present location of the mobile device and a current service center assigned to the mobile device. The method may also provide determining whether a new service center location at a remote location from the current service center location should be assigned to the mobile device based on predefined assignment criteria.

A wireless device is enabled to provide offers. The wireless device receives card data for a financial account card and stores the card data in a memory associated with the wireless device. Responsive to using the card data in a transaction at a first merchant location, the wireless device receives transaction line-item data from a computing system associated with the first merchant location. The wireless device determines merchant information for a second merchant location and determines an offer associated with the second merchant location based on the line-item data and the merchant information for the second merchant. The wireless device presents the offer when the wireless device is near the second merchant location.

Techniques for wireless component monitoring are described herein. The techniques may include entering a low power mode to associate a radio frequency identification (RFID) component with a patient monitoring device within a first range. The techniques also include entering a high power mode wherein the patient monitoring device is to detect the RFID component within a second range of the patient monitoring device, wherein the second range is larger than the first range.