An electronic label apparatus comprises: an inductive communication unit which communicates wirelessly using inductive signals; a processor; memory including a computer program code; and a power source which supplies electric power to the inductive communication unit, the processor, and the memory for enabling their operation. The processor, the memory, the computer program code and the power source with the electric power cause the electronic label apparatus at least to: receive a plurality of inductive signals of known transmission powers from known locations; measure signal powers of the received inductive signals; and determine information about a location of the electronic label apparatus based on the measured signal powers, the known transmission signal powers and the known locations.

The present application relates to a data transmission method for a Bluetooth card reader and an electronic device. The method includes: a CCID driver determines communication rate information corresponding to the Bluetooth card reader based on type information corresponding to the Bluetooth card reader; the CCID driver determines specific communication rate information based on card information and the communication rate information; the CCID driver carries the specific communication rate information in a communication rate confirming request and forwards, via the Bluetooth service program, the communication rate confirming request to the Bluetooth card reader for verification, where the Bluetooth card reader is connected with the Bluetooth service program via Bluetooth; and the CCID driver instructs, based on a communication rate acknowledgement response returned by the Bluetooth card reader, the Bluetooth card reader to transmit, with the specific communication rate information confirmed through the communication rate acknowledgement response, data to be transmitted.

A method of associating data with a physical location comprises receiving, by at least two receiver antennae, a radiofrequency (RF) signal transmitted by a mobile device, the RF signal conveying data collected by the mobile device from an external source; calculating, for each of the at least two receiver antennae, a phase of the RF signal received by each receiver antennae; calculating, based on the calculated phases, a physical location from where the mobile device transmitted the RF signal; and associating the data conveyed by the RF signal and the external source from which the data were collected with the calculated physical location from where the mobile device transmitted the RF signal.

The invention relates to the field of logistics, and discloses a logistics apparatus and a method for identifying empty/full state of the logistics apparatus, which efficiently and accurately realizes automatic recognition of empty and full state. The invention includes: a base and side plates at four sides; a foldable mechanism being provided between the base and each side plate so that the side plates can be folded toward the base; and a short-range wireless transmitter module and a short-range wireless receiver module being respectively disposed on the base and at least one side plate; the short-range wireless transmitter module is configured to transmit a wireless signal indicating the identification of the logistics apparatus; and an arbiter, configured to determine whether the short-range wireless receiver module can currently receive the identifier transmitted by the short-range wireless transmitting module, and if yes, outputting an electrical signal indicating an empty state, otherwise, outputting an electrical signal indicating a full state.

A first reading can be determined of gaming chips in a gaming area using a first identification technology. The first reading can include a count of gaming chips. A second reading can be determined of gaming chips in a gaming area using a second identification technology. The second reading can include a count of gaming chips. A variance can be identified between the first reading and the second reading.

An agricultural data collection framework is provided in a system and method for tracking and managing livestock, and for analyzing animal conditions such as health, growth, nutrition, and behavior. The framework uses ultra-high frequency interrogation of RFID tags to collect individual animal data across multiple geographical locations, and incorporates artificial intelligence techniques to develop machine learning base models for statistical process controls around each animal for evaluating the animal condition. The framework provides a determination of normality at an individual animal basis or for a specific location, and generates alerts, predictions, and a targeted processing or application schedule for prioritizing and delivering resources when intervention is needed.

A wireless tag system includes: a tag signal antenna configured to receive a tag signal transmitted from a wireless transmission tag; and a communication area shaping antenna configured to transmit a reception area shaping signal for narrowing an area in which the tag signal antenna can communicate with the wireless transmission tag, wherein the tag signal antenna and the communication area shaping antenna are arranged for each prescribed product unit in a group of products that are arranged.

An apparatus for managing an inventory of goods stored in multiple bins on a shelving system includes an RFID antenna disposed on an upper shelf of the shelving system. The RFID antenna communicates with RFID tags disposed above the upper shelf RF shielding is disposed between the RFID antenna and lower shelves. An RFID tag is attached to a bin configured to contain the goods. The RFID tag is encoded with information identifying the goods stored in the bin. An RFID reader performs scans to detect RFID tags disposed above the upper shelf. An inventory computer generates a bin detection confirmation message based on the RFID tag being detected by the RFID reader at least a first number of times during a predetermined detection period. The inventory computer also generates a product reorder message based on the RFID tag being detected by the RFID reader at least a second number of times during the predetermined detection period, wherein the second number of times is greater than the first number of times. The product reorder message includes the information identifying the goods stored in the bin.

A numerical operation system for a plurality of individuals includes a contactless communication tag each included in a plurality of individuals, a reader allowed to read the contactless communication tag, and a control unit to which a result read by the reader is input, wherein the control unit is configured such as to acquire, from the result read by the reader, at least numerical values each corresponding to the plurality of individuals and operator symbols for operating the numerical values to calculate a total value based on the numerical values and the operator symbols.

The present application relates to a data transmission method for a Bluetooth card reader and an electronic device. The method includes: a CCID driver determines communication rate information corresponding to the Bluetooth card reader based on type information corresponding to the Bluetooth card reader; the CCID driver determines specific communication rate information based on card information and the communication rate information; the CCID driver carries the specific communication rate information in a communication rate confirming request and forwards, via the Bluetooth service program, the communication rate confirming request to the Bluetooth card reader for verification, where the Bluetooth card reader is connected with the Bluetooth service program via Bluetooth; and the CCID driver instructs, based on a communication rate acknowledgement response returned by the Bluetooth card reader, the Bluetooth card reader to transmit, with the specific communication rate information confirmed through the communication rate acknowledgement response, data to be transmitted.