Systems (100) and methods (600, 1800) for making a marker. The methods comprise: obtaining a resonator material which has been annealed under a tensile force selected to provide a maximum resonant amplitude at a bias field; providing by a bias material of the marker an operating bias field with a value less than a value of the bias field; forming a first housing portion from a flexible material so as to have a planar shape; and forming a second housing portion from the flexible material so as to comprise a cavity in which the resonator and bias materials can be housed when the second housing portion is coupled to the first housing portion. The cavity is defined by two opposing short sidewalls, two opposing elongate sidewalls (OESW) and a bottom sidewall. Each of OESW is stiffened by forming a plurality of first stiffener edge features along an exterior surface thereof.

A smart tag comprises a processor, a non-volatile memory, at least one of an internal power source and an external power source, and a transceiver configured for two-way communication with a reader external to the smart tag. The smart tag is formed as an integrated circuit chip less than 10 cubic millimeters in size to less than 0.000125 cubic millimeters in size. An apparatus comprising the smart tag may further include an antenna connect to the smart tag.

A system, method, and device for improving the functioning of security tags for use with merchandise are provided. A security tag device, to be used in conjunction with a tag monitoring device, may be provided with a product. The product may be conductive or may have metallic packaging. The security tag may include a planar dielectric substrate having a first side and an opposing side. An electronic article surveillance (EAS) circuit may be placed on the first side of the planar dielectric substrate. A ferrite sheet having a first side and an opposing side may be coupled to the opposing side of the planar dielectric substrate. A metal backing sheet may be coupled to the opposing side of the ferrite sheet. The planar dielectric substrate may be centered or offset on the ferrite sheet and the ferrite sheet may be centered or offset on the metal backing sheet.

A smart tag comprises a processor, a non-volatile memory, at least one of an internal power source and an external power source, and a transceiver configured for two-way communication with a reader external to the smart tag. The smart tag is formed as an integrated circuit chip less than 10 cubic millimeters in size to less than 0.000125 cubic millimeters in size. An apparatus comprising the smart tag may further include an antenna connect to the smart tag.

A marking label includes an RFID transponder with an RFID chip and an antenna structure which are coupled to one another by signal technology, and a sealing layer which covers the RFID transponder. The sealing layer is bonded to a substrate by welding so that the RFID chip and/or the antenna structure is surrounded by a weld seam and enclosed between the sealing layer and the substrate.

A smart tag comprises a processor, a non-volatile memory, at least one of an internal power source and an external power source, and a transceiver configured for two-way communication with a reader external to the smart tag. The smart tag is formed as an integrated circuit chip less than 10 cubic millimeters in size to less than 0.000125 cubic millimeters in size. An apparatus comprising the smart tag may further include an antenna connect to the smart tag.

Systems (100) and methods (1800) for making a marker housing. The methods comprise: forming a first housing portion from a flexible material so as to have a planar shape; and forming a second housing portion (700, 1200, 1500) from the flexible material so as to comprise a cavity (702, 1202) in which resonator and bias elements (104, 110) of the marker can be housed when the second housing portion is coupled to the first housing portion. The cavity is defined by two opposing short sidewalls (708, 712), two opposing elongate sidewalls (706, 710) and a bottom sidewall (704). The two opposing elongate sidewalls are stiffened such that crushing and bending thereof is made difficult. The stiffening is achieved by forming a plurality of first stiffener edge features (714) along an exterior surface of each of the two opposing elongate sidewalls which partially define the cavity of the second housing portion.

An anti-theft AM label is formed with a housing that includes concave and/or convex patterns and wordings on the upper surface thereof. The concave and/or convex patterns and wordings provide a different appearance for anti-theft AM labels that can deter shoplifters from finding and removing the labels from the goods the labels are protecting. The concave and/or convex patterns can be the logo of the store in which the labels are used. The upper surface of the housing can be formed with a cold forming process or a hot forming process. The shape of the housing can be varied between square, rectangular, circular, sector and oval configurations, as desired by the customer. The depth of the patterns and words relative to a flat portion of the upper surface of the housing is in the range of 0.05-1.0 mm or, more preferably, in the range of 0.2-1.0 mm.

Disclosed are combination radio frequency identification (RFID) and electronic article surveillance (EAS) tags and methods of producing such tags. The claimed method is characterized by feeding a first plurality of first type inlays and a second plurality of second type inlays into a laminating machine, wherein each of the first and second type inlays are formed on first and second substrates, respectively; laminating the first type inlays to the second type inlays, thereby forming a plurality of pairs of the first and second type inlays, each of the pairs comprising an RFID inlay and an EAS inlay, wherein the RFID inlay and the EAS inlay of each pair are functionally independent.

A dual security tag including an RFID component and an electronic article surveillance (EAS) component, respectively disposed on opposite sides of a PET carrier substrate, is provided. The RFID component may include one or more ultra-high frequency antennae, such as a near field loop antenna and a far field dipole antenna, and an integrated circuit (IC) chip. The EAS component may be provided as an RF device, an acoustic-magnetic (AM) device, a low power Bluetooth (BLE) device, or other suitable device. The security tag may also include a facesheet affixed to the RFID component, a release liner layer affixed to the EAS device, and one or more intermediary films or protective layers. A method for manufacturing a dual security tag is also described.