Example implementations include a method, apparatus, and computer-readable medium for electronic article surveillance (EAS), comprising transmitting concurrently, an acousto-magnetic (AM) interrogation signal into an AM interrogation zone of an EAS system, and a radio frequency identification (RFID) interrogation signal into an RFID interrogation zone of the EAS system, the AM interrogation zone and the RFID interrogation zone overlapping to form a zone of interest. The implementations further include indicating, by the EAS system, a presence of a first tag of the EAS system in the zone of interest upon a concurrent detection of both an RFID response signal of the first tag in response to the RFID interrogation signal and an AM response signal of the first tag in response to the AM interrogation signal.

A product anti-theft method includes acquiring first image from a first photographic device, and obtaining item information of at least one first product and face feature information of a first user by recognizing the first image. The method further includes acquiring second image from a second photographic device, and obtaining item information of at least one second product and face feature information of a second user by recognizing the second image. When the face feature information of the second user is the same as the face feature information of the first user and searched item information is the same as the item information of the at least one second product, it is determined that a handover process is completed and an alarm device of the least one second product is deactivated.

Aspects of the present disclosure include methods, apparatus, and systems for deactivating an AM tag including receiving a deactivation signal via a first inductive coil, storing electrical charges generated from the deactivation signal in a capacitor, and discharging the electrical charges through a second inductive coil, wherein: a first bias strip in the demagnetized state and a second bias strip cause a resonator to vibrate at a first resonant frequency corresponding to an activated state of the AM tag, the discharging magnetizes the first bias strip from a demagnetized state to a magnetized state, and the first bias strip in the magnetized state and the second bias strip cause the resonator to vibrate at a second resonant frequency different than the first resonant frequency, wherein the resonator vibrating at the second resonant frequency corresponds to a deactivated state of the AM tag.

A magnetoelastic resonator device comprises a housing, at least one elliptically-shaped or substantially elliptically-shaped magnetoelastic element disposed within the housing, and at least one bias magnet disposed in the housing, wherein the at least one elliptically-shaped or substantially elliptically-shaped magnetoelastic element is configured to couple to an external magnetic field at a particular frequency and convert the magnetic energy into mechanical energy, in the form of oscillations.

The present invention describes a tag comprising a magnetic element in the form of a microwire of 80-250 microns with giant magnetoimpedance which, when joined to an object, allows for the wireless detection of same by modulating the reflectivity of the microwire. Detection is performed by using a system that emits an electromagnetic wave that has a frequency between 1 and 20 GHz and a low frequency magnetic field (0.01-50 Hz), and detects the modulation of the reflectivity of the microwire. Thus, objects at distances greater than 1 m can be detected.

This invention relates to a security tag for use in a retail environment. In particular this invention relates to a security tag including a flexible member or lanyard that can be formed into a loop to attach the security tag to an article. A security tag comprises a main body comprising a casing having opposite first and second end walls; an elongate flexible member for securing around an object, a first end of the flexible member being connected to the main body; a releasable locking mechanism in the main body, the locking mechanism configured to retain a second end of the flexible member within the casing such that a part of the flexible member external to the casing forms a loop, the locking mechanism being releasable by application of a magnetic force such that the second end of the flexible member can be withdrawn from the casing; and two electronic article surveillance (EAS) sensors housed within the casing, a first one of the sensors being proximate the first end wall of the casing and a second one of the sensors being proximate the second end wall of the casing.

A folded coil label and associated methods of making a folded coil label are provided. On example folded core label may include a core, a coil, and a capacitor. The coil may be wrapped around the core and connected to the capacitor to form a resonant circuit. The coil may be formed of angled traces wrapped around the core to form turns of the coil, and each angled trace may be electrically and physically connected in series to an adjacent angled trace to form a helical structure of the coil.

The system performs communication between two systems, a master system, that creates an alternating magnetic field by means of which it dialogues with one or more slave systems, which respond at frequencies other than those generated by the master by a non-linear magnetic core generating harmonics of higher order than those of the magnetic field created by the master. The generation of harmonics is controlled by the slave by a short-circuit coil which enables the data transmission from the slave to the master. The slave system can have its own power supply or it can be powered by the short-circuit coil. This allows microcontrollers in the slaves to be powered and give them intelligence and a large storage capacity, making them ideal for control security and monitoring processes. The excitation frequency can be varied because the functionality of the slaves does not depend on the frequency of the exciter field.

A recording medium is provided, such as paper, secured by magnetic microwires. The recording medium comprises: a pulp structure formed by pulp fibers, said pulp structure carrying microwires having a metal core of a predetermined material composition, and an insulating layer coating on said metal core; and at least one coating layer on at least one side of said pulp structure. The pulp structure is a single-layer structure with the microwires fully embedded in said single layer, the microwires having cross-sectional dimensions approximately equal to cross-sectional dimensions of the pulp fibers.

The system performs communication between two systems, a master system, that creates an alternating magnetic field by means of which it dialogues with one or more slave systems, which respond at frequencies other than those generated by the master by a non-linear magnetic core generating harmonics of higher order than those of the magnetic field created by the master. The generation of harmonics is controlled by the slave by a short-circuit coil which enables the data transmission from the slave to the master. The slave system can have its own power supply or it can be powered by the short-circuit coil. This allows microcontrollers in the slaves to be powered and give them intelligence and a large storage capacity, making them ideal for control security and monitoring processes. The excitation frequency can be varied because the functionality of the slaves does not depend on the frequency of the exciter field.