The present disclosure relates to methods and apparatus for accurately calculating time with a Miniature Atomic Clock along with other components that can receive process and communicate information to enable locating, identifying, and tracking physical Assets and data contained within the Assets. More specifically, the present disclosure presents a Global Resource Locating (GRL) device and service that may be adhered or inserted in the Asset, which may be built in or attached to a second Asset, wherein the device may comprise a receiver and a trilateration mechanism. In some aspects, the Asset may comprise a product, organism, produce, or component of a logistics based operational process and marketing based Asset movement and usage analysis.

Systems and methods for tracking a subject using radio-frequency identification (RFID). In an embodiment, an antenna array comprising a plurality of articulating brackets and a plurality of antennas is provided. Each of the articulating brackets is configured to move one of the plurality of antennas into a plurality of positions, and each of the antennas is configured to receive a RFID signal. In addition, a processor receives RFID data based on RFID signals received by the antennas of the antenna array, and determines a trajectory of a subject based on the RFID data. Based on the determined trajectory of the subject, the processor controls one or more of the articulating brackets to move one or more of the antennas into a position to track the subject.

A sports object comprises an electronic circuit having a power source and a transmitter and arranged to transmit a signal identifying the sports object. The sports object has an inner core encapsulating the electronic circuit. The inner core is configured such that the inner core and electronic circuit are balanced. There is at least one outer core layer encapsulating the inner core. The sports object is used in a system for providing sports game information. The system comprises the sports object and a portable computing device including a receiver responsive to the signal and a location means for determining the location of the computing device. The computing device records the signal received at two or more different locations and records the location of the computing device at each of the different locations to enable estimation of a location for the sports object identified by the received signal.

A system for providing destination guidance based on tracked real-time ambient health conditions includes one or more location tracking devices carried by one or more participants. The one or more location tracking devices track the locations of the one or more participants and providing the tracked locations to a central server when it is determined that the one or more participants are infected by a communicable ailment. The central server receives the provided tracked locations and transmits the tracked locations to a navigation guidance device carried by a user, without transmitting identifying details about the one or more participants. The navigation guidance device carried by the user provides guidance to the user on selecting a destination or route that avoids contact with or exposure to the plurality of participants.

An RF position tracking system for wirelessly tracking the three-dimensional position of a tracked object. The tracked object has at least one mobile antenna and at least one inertial sensor. The system uses a plurality of base antennas which communicate with the mobile antenna using radio signals. The tracked object also incorporates the inertial sensor to improve position stability by allowing the system to compare position data from radio signals to data provided by the inertial sensor.

A speed-based projection filtering method includes generating, based on a sequence of raw location points that indicate locations of a tracking tag attached to a tracked object, a sequence of averaged location points. Based on at least two most-recent averaged location points of the sequence, a latest speed and direction of the tracked object are determined. Based on the latest speed and direction, one or more projected location points are determined when the latest speed of the tracked object is greater than a high-speed threshold and raw location points are missing after the sequence of raw location points. The projected location points are then outputted.

A system is disclosed for providing a waste management app. The system may have a locating device disposed onboard a service vehicle and configured to generate a first signal indicative of a location of the service vehicle, an input device, and a controller. The controller may be configured to receive a route assignment including waste services to be performed by the service vehicle, and to track movement of the service vehicle during performance of the waste services based on the first signal. The controller may also be configured to provide a graphical user interface for display on the input device, listing the waste services from the route assignment to be performed by the service vehicle and showing a location of the service vehicle relative to at least one location at which the waste services are to be performed.

Provided are means for identifying stop periods of a device in a location. A method for identifying the stop periods may be performed by a mobile device and involve during a first step, determining a predicted position of the mobile device, according to a new filtered position obtained using a discrete-time Kalman Filter. The method may also involve during a second step, determining a normalized prediction error according to the difference between the new predicted position and the first position. If the normalized prediction error is smaller than a prediction error threshold, generating a stop message to indicate that the stop period is starting. The method may further involve during a third step, triggering an action on the mobile device, according to the stop message.

Methods, devices, and systems for tracking an asset are provided. In particular, a device is provided that includes an array of sensors and communications modules configured to detect tracking information, including environmental conditions and physical events, and report the tracking information along with a geographical location of the device to a control server across a wireless network. Upon receiving the tracking information, the control server interprets the information and generates tracking reports for the device configured to be displayed to a graphical user interface of a third-party communication device.

A receiver includes an RF module to receive and down convert multiple types of RF signals received from at least one antenna; a communication unit configured to communicate signals with at least one external device; and a processing unit communicatively coupling the radio frequency module with the communication unit. Processing unit receives operation mode selection. When first operation mode is selected, processing unit receives first input signal from antenna via RF module (the first input signal including ILS signal and/or VOR signal) and outputs first output signal based on first input signal to external device. When second operational mode is selected, processing unit receives second input signal from antenna via radio frequency unit (second input signal including AIS signal including data regarding a current location of remotely located transmitting device) and outputs second output signal based on second input signal to external device.