Devices, systems, and methods for removing a security tag from an article are disclosed herein. A device for removing a security tag includes a housing including an opening positioned to receive the tag and at least a portion of the article. A magnet is supported adjacent the opening to retain a tag body and to release a retainer pin therefrom when the tag is inserted into the opening. A pin retractor is positioned in the housing opposite the magnet to capture the retainer pin and retract it from the tag body. The pin retractor is retracted into a collar to strip the pin from the pin retractor. A release frame is positioned proximate the magnet and movable between a first position wherein the magnet retains the tag body, and a second position wherein the tag body is moved away from the magnet, thereby releasing the tag body from the magnet.

Systems and methods for providing a tag. The tag comprising a flexible elongate structure comprising a cord or a cable; an electronic thread device integrated into the cord or cable that is operative to wirelessly communicate with external devices for inventory management or security purposes; and/or an Electronic Article Surveillance (“EAS”) component integrated into the cord or cable.

Systems and methods for operating a Unified Security Device (“USD”). The methods comprise: receiving an Electronic Article Surveillance (“EAS”) interrogation signal with an antenna of the USD; processing the EAS interrogation signal using a processor unit of the USD; using the processor unit to generate an EAS response signal that emulates a response signal produced by an Acousto-Magnetic (AM) type of EAS security tag, in response to the EAS interrogation signal; and communicating the EAS response signal from the USD.

A security tag including: a housing and circuitry which detects a locked state, the circuitry configured to execute a signal transfer function responsive to interchanging a pin and a lanyard in the circuitry, and/or the housing including a replaceable battery compartment locked by inserting either the pin or the lanyard into a lock mechanism which differently secures the pin and the lanyard; and an alarm, in communication with the circuitry, triggered by an undisarmed breach of the locked state.

Systems and methods for operating a marker. The method comprising: receiving, by a Radio Frequency Identification (“RFID”) element of the marker, an RFID deactivation signal transmitted from an external device; and responsive to the RFID deactivation signal, supplying power from the RFID element to a detuner element so that the detuner element switches from a first state to a second state. The marker's resonant frequency is changed to a first value that falls outside of an Electronic Article Surveillance (“EAS”) systems operating frequency range when the detuner element switches from the first state to the second state.

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.

Aspects of the present disclosure provide techniques to deactivate security tags associated with purchased products via a mobile application by using the Near Field Communications (NFC) protocol or other near field wireless capabilities of the mobile device to communicate with a stand-alone deactivator. In some instances, the mobile device may be configured to deactivate either single tag (“single deactivation”) or a plurality of tags (“bulk deactivation”) using an authorization code. Features of the present disclosure provide advantages over conventional systems in terms of convenience for the customer and lower hardware requirements. Specifically, unlike current systems, the stand-alone deactivator of the present disclosure does not need to be part of or connected to the POS network to enable or inhibit the deactivation of security tags. The information needed to enable deactivation may be transferred to the deactivator using the NFC or other near field wireless capabilities of a mobile device.

Systems and methods for operating a marker. The methods comprise: storing energy collected by an energy harvesting element of the marker; using the stored energy to enable operations of the marker's communications element; receiving, by the marker's communications element, a marker deactivation signal transmitted from an external device; and causing either a resonator to be prevented from receiving transmit bursts emitted from an EAS system, a bias element's magnetic field to be normalized, or a resonator to be physically prevented from vibrating, in response to the marker deactivation signal's reception.

Aspects of the present disclosure include methods, systems, and non-transitory computer readable media for receiving a confirmation signal to unlock the security tag being detachably locked to a merchandise, wherein the confirmation signal includes a RFID device identifier associated with a RFID device of the security tag, and the RFID device is associated with a wireless device of the security tag, identifying the wireless device associated with the RFID device based on the RFID device identifier, transmitting a wireless signal to the wireless device to enable a controller to receive a release signal used to unlock the security tag from the merchandise, and transmitting the release signal to the controller to unlock the security tag from the merchandise.

Systems and methods for operating a marker. The method comprising: receiving, by a Radio Frequency Identification (“RFID”) element of the marker, an RFID deactivation signal transmitted from an external device; and responsive to the RFID deactivation signal, supplying power from the RFID element to a detuner element so that the detuner element switches from a first state to a second state. The marker's resonant frequency is changed to a first value that falls outside of an Electronic Article Surveillance (“EAS”) systems operating frequency range when the detuner element switches from the first state to the second state.