A method and system for identification of an item is provided, wherein the system comprises includes a conveyor belt, a conveyor belt controller and a reader operable to receive at least one reading from at least one tag attached to the item and extract from the reading a measurement of the phase of the signal transmitted by the tag and received at at least one antenna of the reader, the antenna being adapted to be arranged at a read point along the conveyor belt, wherein the conveyor belt controller is configured to start the conveyor belt at a first time instant, after the item has been placed on the conveyor belt, and to stop the conveyor belt at a second time instant, when the item has passed the antenna of the reader.

A method and system for identification of an item is provided, wherein the system includes a conveyor belt, a positioning device and a reader operable to receive at least one reading at at least one first antenna from at least one tag attached to the item, the first antenna being adapted to be arranged at a read point along the conveyor belt, wherein the positioning device is configured to retrieve a first position of the item at a first time instant before the first antenna and a second position of the item at a second time instant after the first antenna, the first and second time instants defining a time window, wherein the reader is configured to extract from each reading retrieved by the first antenna a measurement (6) of the phase of the signal transmitted by the tag (5) and perform a data processing of the phase measurements whereby the identification of the item (2) is accomplished.

A cable antenna an end part of which is connected to an oscillator that supplies a high-frequency current is disclosed. The cable antenna includes: an inner conductor; an insulating layer covering the inner conductor; and an outer conductor covering the insulating layer, wherein only one exposed part is formed in a middle part of the cable antenna in a longitudinal direction, the exposed part formed by removing at least the outer conductor, a distance L between a tip end of the cable antenna and an end of the exposed part on a side closer to the tip end is an odd multiple of a quarter of a wavelength λ of the high-frequency current, the multiplier being three or greater, and a length G of the exposed part in the longitudinal direction satisfies the following formula (1):

$\lambda /20\le \text{G}\text{<}\lambda /4\mathrm{...}$

λ: wavelength (mm) of the high-frequency current.

Recommended installation position and posture of a stationary code reader can be proposed to a user to facilitate installation work of the code reader by the user. An installation support device for the stationary code reader acquires camera information including a camera parameter of the code reader, code information to be read, and environment information including a conveying speed of a line, determines required field of view and depth of the code reader required to read a code under an environment specified by the environment information, and determines an installation pattern which is recommended installation position and posture of the code reader that can satisfy the required field of view and depth based on the camera information and the code information.

Sortable tracking objects that can be associated with item containers and items for tracking and organization.

A wireless tag communication device for communicating with a wireless tag conveyed by a conveyance mechanism, includes radiation regions from which a radio wave is emitted. The radiation regions include a first region extending along a first direction crossing a conveyance direction of the tag and having a first length in the first direction, a second region extending along the first direction and having a second length in the first direction, a third region extending along the conveyance direction and having a third length in the conveyance direction, and a fourth region extending along the conveyance direction and having a fourth length in the conveyance direction. The device further includes a controller configured to cause at least one of the first, second, third and, fourth regions to emit a polarized wave towards the tag. Each of the first and second regions partially overlaps the third and fourth regions.

A system for reading RFID tags or labels on merchandise in a shopping cart or basket includes a chamber sized and configured to receive a shopping cart or basket. The chamber includes a portal sized and configured to accommodate a shopping cart or basket, along with an associated closure that is movable between open and closed conditions. At least one antenna coupled to an RFID reader is associated with an interior of the chamber and oriented to send signals to and receive signals from RFID tags or labels on merchandise in a shopping cart or basket within the chamber. The chamber and the closure are configured to prevent signals sent to and from RFID tags or labels on merchandise in a shopping cart or basket within the chamber from exiting the chamber. A transport mechanism may be provided to automatically move the shopping cart or basket through the chamber.

An apparatus for an efficient label application comprising a conveyor belt; a barcode reader that is disposed above a conveyor belt and attached to a first cross beam; a 3D profiler that is disposed above said conveyor belt and attached to a second cross beam, and records size, shape, and orientation of a shipping package; a first plexiglass shield that comprises a light curtain; wherein said first plexiglass shield and light curtain protect a robotic arm's operating space on one side of said conveyor belt; a second plexiglass shield that protects said robotic arm's foot; a printer that is disposed next to said robotic arm; two upward facing fans that are disposed between said printer and said robotic arm, and, together, create an air cushion; a third plexiglass shield that protects said robotic arm, air cushion, and printer on second side of said conveyor belt; said first plexiglass shield, third plexiglass shied, and said conveyor belt define and protect a critical zone of said robotic arm's operating space; a printer control panel that is mounted on said third plexiglass shield; an operator control panel that allows said apparatus to be started, stopped, and calibrated, and is mounted on said third plexiglass shield.

In some embodiments, apparatuses and methods are provided herein useful to track objects on a moving conveyor system. In some embodiments, an RFID based tracking system comprises a conveyor system to move and transport objects along a conveyance path, wherein each object includes a near field only RFID tag associated therewith and identifying the object. Each near field only RFID tag is not coupled to a far field antenna such that it is not readable in a far field of RFID communication and communicates only in a near field of RFID communication. An RFID tag reader is positioned to attempt to read the near field only RFID tag of each object. And a control circuit processes reads of the near field only RFID tags by the first RFID reader to determine an order of the objects being conveyed.

A method for bulk encoding of RFID tags. The method may include printing a plurality of unencoded RFID labels, coupling each of the plurality of unencoded RFID labels to each of a plurality of products, packaging like products from the plurality of products coupled with the unencoded RFID labels together in a container, scanning the container holding the products with an RFID antenna, and encoding each of the unencoded RFID labels coupled to each of the plurality of like products in a container simultaneously with identical information for each container.