A tracking system uses a mobile reader or scanner that scans, for example through a barcode reader, a passive tag reader, a probe, input, camera, or an active RF tag communication reader, and records item (asset or inventory) data. After being recorded, this item data and other relevant data is sent by radio transmission to a receiver network in the tracking system. The receiver network has at least two receivers (or at least two receiver antennae). The scanner location data, calculated by comparing the signal information at each receiver antenna receiving the radio transmission, is then used to register and record the location data of the scanned item.

Disclosed are apparatuses and corresponding and associated methodologies for achieving current inventory data management in combination with an electronic access control system. An access control system provides access control data while the sealed enclosure incorporates an RFID reading system for determining the identity of respective tagged contents within the enclosure. Particularly in conjunction with the storage of controlled substances, such as some drugs utilized on an EMS vehicle, a form of RFID tag may be practiced which operationally is fully or partially destroyed or damaged, or otherwise impacted or affected so as to generate a changed ID, whenever the contained medicinal dosage is acquired for administration. By reading contents of the enclosure (narc box) prior to a work shift, and at the conclusion of the work shift, comprising tracking comparative methodology, usage of the tagged drugs may be tracked. By forming such reports throughout the course of a shift, as each point of consumption takes place, a complete record of custody of control may be maintained.

According to one embodiment, there is provided a printer including a print head, a platen roller, a sheet position sensor, an antenna, and a movable portion. The print head is configured to print on a strip-shaped sheet. The platen roller is configured to move the sheet pinched between the platen roller and the print head along a longitudinal direction of the sheet. The sheet position sensor is provided on a substrate disposed on an upstream side of the print head in a conveyance direction of the sheet, and is configured to detect a position of the sheet. The antenna is provided on the substrate and is configured to write information to a wireless tag provided on the sheet. The movable portion is configured to move the substrate along a width direction of the sheet.

A method for controlling an electronic shelf label includes identifying a user type; retrieving a task type matching the user type from at least one preset task type according to the user type, the user type including at least one of a gender or an age of the user; generating a task based on the retrieved task type; presenting the task; and transmitting the task to an electronic shelf label.

An inventory tracking system (10) for use in tracking articles (12) received in a cabinet (14) comprises at least one RFID read antenna assembly (100), an RFID tag interrogator (30), and an electrical connector arrangement (24). The cabinet comprises a receptacle (16), a holder (18) arranged in the receptacle and at least one metal substrate (20) received in the holder. The metal substrate is configured to receive at least one article carrying an RFID tag. The RFID read antenna assembly is mountable to the metal substrate, the antenna assembly comprising at least one antenna coil (102) and a high permeability layer (104). The RFID tag interrogator is configured to interrogate the RFID tag of the, or each, article received by the at least one metal substrate. The electrical connector arrangement has complementary components (26, 28) carried by the holder and the metal substrate for establishing, and breaking, an electrical connection between the interrogator and the at least read antenna assembly.

According to one embodiment, there is provided a printer including a print head, a platen roller, a sheet position sensor, an antenna, and a movable portion. The print head is configured to print on a strip-shaped sheet. The platen roller is configured to move the sheet pinched between the platen roller and the print head along a longitudinal direction of the sheet. The sheet position sensor is provided on a substrate disposed on an upstream side of the print head in a conveyance direction of the sheet, and is configured to detect a position of the sheet. The antenna is provided on the substrate and is configured to write information to a wireless tag provided on the sheet. The movable portion is configured to move the substrate along a width direction of the sheet.

According to one embodiment, there is provided a printer including a print head, a platen roller, a sheet position sensor, an antenna, and a movable portion. The print head is configured to print on a strip-shaped sheet. The platen roller is configured to move the sheet pinched between the platen roller and the print head along a longitudinal direction of the sheet. The sheet position sensor is provided on a substrate disposed on an upstream side of the print head in a conveyance direction of the sheet, and is configured to detect a position of the sheet. The antenna is provided on the substrate and is configured to write information to a wireless tag provided on the sheet. The movable portion is configured to move the substrate along a width direction of the sheet.

An electronic tag device includes: a processor, an OBD circuit and a radio frequency identification (RFID) tag chip; the processor is used to transmit an OBD data request command set to an OBD interface of a vehicle through the OBD circuit to thereby enable the vehicle to output OBD data in response to the OBD data request command set; and the processor is further configured to obtain target OBD data based on the OBD data obtained from the OBD interface of the vehicle through the OBD circuit and convert the target OBD data; and the RFID tag chip is configured to obtain and store the converted target OBD data from the processor to thereby allow a server to obtain the converted target OBD data from the RFID tag chip. The electronic tag device can be used in the variety of application scenes.

According to one embodiment of the present disclosure, an industrial facility is provided comprising a tag layout and at least one ingress/egress zone. The tag layout comprises at least one double row of tags. The ingress/egress zone is located outside of an area of the vehicle travel plane occupied by the aisle path and is bounded in its entirety by the double row of tags, by two or more double rows of tags, by a combination of one or more double rows of tags and one more selected facility boundaries, or by combinations thereof. The double row of tags is arranged in an n×m matrix that is configured for successive detection of the inner and outer rows of tags that is dependent on the point-of-origin of a sensor transit path across the double row of tags. Additional embodiments are disclosed and claimed.

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.