Abstract: A security tag that is attached to an article in two stages. In a first stage, a first portion of an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, a second portion of the attachment clip is then permanently secured in a locking mechanism of a housing containing a security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF), benefit denial (e.g., ink-filled or dye-filled capsules) elements or any combination thereof. Because the security tag is not removed from the article at the point-of-sale, the security element is deactivatable. A preferred embodiment of the security tag uses all non-ferrous components including its locking mechanism.

Abstract: A multi-attach disposable security tag that is attached to an article in two stages. In a first stage, an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, the attachment clip is then permanently secured in a locking mechanism of a housing containing a deactivatable security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF) elements or any combination thereof. A preferred embodiment of the security tag uses all non-ferrous components including its locking mechanism.

Abstract: A multi-attach reusable security tag (MARST) that is attached to an article in two stages. In a first stage, an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, the attachment clip is then secured in a releasable locking mechanism of a housing containing a security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF) elements or any combination thereof. Alternatively, a fluke element can be used to secure the attachment clip to the releasable locking mechanism and wherein this fluke element permits the attachment clip to swivel outside of the housing.

Abstract: Security labels and tags including elements and methods of making them are disclosed. The elements are in the form of an oriented polymer layer, conductive traces clad to the polymer layer to form an open loop forming a window in the interior of the loop and an open support framework extending into the window to support the polymer layer in the window. In some embodiments the open support framework is in the form of parallel, interleaved linear extensions from the conductive traces which extend into the window. In other embodiments the open support framework is in a pattern of intersecting sections (e.g., a fishbone pattern) located in the window.

Abstract: A security hard tag, uses an attachment clip to couple to an article, such as but not limited to clothing, to be protected and which can only be released from the article by use of an authorized detacher that is inserted into the security hard tag. The attachment clip may include various types of locking mechanisms on its two ends, one end which is permanently secured within the security hard tag housing and the other end which is releasably secured within the housing. Before being releasably secured within the housing, the one end is inserted through or around a portion of an article, or through a security tag loop attached to the article, and then that end is locked into the housing. The detacher uses a cam, either located on the detacher itself or positioned within the security hard tag housing, to interact with the one end of the attachment clip to release the locked end.

Abstract: A resonant circuit for use with a radio-wave detection system for the prevention of shoplifting or the like, which is formed on a flexible substrate and has a coil and capacitor circuit whereby the capacitor has an indented area in the dielectric of the capacitor to promote disablement of the circuit when exposed to a strong electromagnetic field. Upon exposure to a strong electromagnetic field, an electrical short forms across the dielectric of capacitor in the indented area. Because the short is fragile and can be opened by flexure of the circuit, an island of reinforcing material is formed in the indented area, such that when the substrate is flexed, the indented area remains rigid to protect the short. The indented area can be further stress-relieved by introducing a gap in the conductors forming the capacitor plates.

Abstract: A multi-attach reusable security tag (MARST) that is attached to an article in two stages. In a first stage, an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, the attachment clip is then secured in a releasable locking mechanism of a housing containing a security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF) elements or any combination thereof. Alternatively, a fluke element can be used to secure the attachment clip to the releasable locking mechanism and wherein this fluke element permits the attachment clip to swivel outside of the housing.

Abstract: A multi-attach disposable security tag that is attached to an article in two stages. In a first stage, an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, the attachment clip is then permanently secured in a locking mechanism of a housing containing a deactivatable security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF) elements or any combination thereof. A preferred embodiment of the security tag uses all non-ferrous components including its locking mechanism.

Abstract: A security tag that can be attached to an item or items that provides a zero or low impact to the item or items such as elegant or soft goods. The security tag includes a security element that is enclosed within a pliable material that is coupled to the item or items it is protecting by either a lanyard or by passing a portion of the unfinished garment through aperture(s) in the pliable material. The lanyard can take on various compositions and can couple to the pliable material using different latching mechanisms. No puncturing, piercing or adhesive attachment to the elegant or soft goods occurs, thereby making a “zero or low impact” on the item while also making a pleasant presentation to customers when the item (or items) is displayed.

Abstract: Security labels and tags including elements and methods of making them are disclosed. The elements are in the form of an oriented polymer layer, conductive traces clad to the polymer layer to form an open loop forming a window in the interior of the loop and an open support framework extending into the window to support the polymer layer in the window. In some embodiments the open support framework is in the form of parallel, interleaved linear extensions from the conductive traces which extend into the window. In other embodiments the open support framework is in a pattern of intersecting sections (e.g., a fishbone pattern) located in the window.

Abstract: A security tag that is attached to an article in two stages. In a first stage, a first portion of an attachment clip is coupled to an article, such as but not limited to clothing, to be protected by a manufacturer or assembler. This attachment clip is durable to withstand harsh manufacturing environments. Once the article with the attachment clip is ready for presentation, for example, at a retail establishment, during a second stage, a second portion of the attachment clip is then permanently secured in a locking mechanism of a housing containing a security element therein. The security element may comprise EAS (including AM, RF, EM and microwave), RFID (including LF, HF and UHF), benefit denial (e.g., ink-filled or dye-filled capsules) elements or any combination thereof. Because the security tag is not removed from the article at the point-of-sale, the security element is deactivatable. A preferred embodiment of the security tag uses all non-ferrous components including its locking mechanism.

Abstract: A security hard tag, uses an attachment clip to couple to an article, such as but not limited to clothing, to be protected and which can only be released from the article by use of an authorized detacher that is inserted into the security hard tag. The attachment clip may include various types of locking mechanisms on its two ends, one end which is permanently secured within the security hard tag housing and the other end which is releasably secured within the housing. Before being releasably secured within the housing, the one end is inserted through or around a portion of an article, or through a security tag loop attached to the article, and then that end is locked into the housing. The detacher uses a cam, either located on the detacher itself or positioned within the security hard tag housing, to interact with the one end of the attachment clip to release the locked end.

Abstract: A resonant circuit for use with a radio-wave detection system for the prevention of shoplifting or the like, which is formed on a flexible substrate and has a coil and capacitor circuit whereby the capacitor has an indented area in the dielectric of the capacitor to promote disablement of the circuit when exposed to a strong electromagnetic field. Upon exposure to a strong electromagnetic field, an electrical short forms across the dielectric of capacitor in the indented area. Because the short is fragile and can be opened by flexure of the circuit, an island of reinforcing material is formed in the indented area, such that when the substrate is flexed, the indented area remains rigid to protect the short. The indented area can be further stress-relieved by introducing a gap in the conductors forming the capacitor plates.

Abstract: A security tag that can be attached to an item or items that provides a zero or low impact to the item or items such as elegant or soft goods. The security tag includes a security element that is enclosed within a pliable material that is coupled to the item or items it is protecting by either a lanyard or by passing a portion of the unfinished garment through aperture(s) in the pliable material. The lanyard can take on various compositions and can couple to the pliable material using different latching mechanisms. No puncturing, piercing or adhesive attachment to the elegant or soft goods occurs, thereby making a “zero or low impact” on the item while also making a pleasant presentation to customers when the item (or items) is displayed.

Abstract: A method of making a resonant frequency tag which resonates at a predetermined frequency. The method involves providing a first conductive pattern having an inductive element and a first land and a second conductive pattern having a second land and a third land which are joined together by a link. The second conductive pattern is overlaid the first conductive pattern such that the second land is positioned over the first land. The third land is in electrical communication with the inductive element of the first conductive pattern. The formed resonant frequency tag is energized to determine if the tag resonates at the predetermined frequency. If the tag resonates properly, the third land is electrically coupled to the inductive element. If it does not, the second conductive pattern is adjusted so that overlapping portions of the first and second lands are changed, altering the capacitance to adjust the resonant tag frequency.

Abstract: A method of making a resonant frequency tag having a predetermined frequency comprises forming a first conductive pattern comprising an inductive element and a first land having a first end connected to an inductive element end, and a second end spaced a predetermined distance from the first end; separately forming a second conductive pattern comprising a second land having a predetermined width and a link element; placing the second conductive pattern proximate the first conductive pattern at a first location wherein the second land overlies a portion of the first land with a dielectric therebetween establishing capacitive element plates having a first capacitance along with the inductive element forming a resonant circuit; measuring the resonant circuit frequency and comparing the measured and predetermined frequencies moving the second land along of the first land length to match the resonant frequency; and securing the second conductive pattern to the first conductive pattern.

Abstract: A tag and method of making it. The tag includes a first adhesive layer provided in a first predetermined pattern between a surface of a first substrate and a first conductive foil. The first pattern corresponds to a pattern for a first conductive trace, e.g., a portion of a resonant circuit. The first conductive foil is laminated, e.g., adhesively secured, to the surface of the first substrate to form a first conductive layer. A first portion of that layer is shaped, e.g., die-cut, to generally correspond to the first pattern. A second portion of the first conductive layer not corresponding to the first portion is removed, to establish the first conductive trace, with the adhesive layer confined within the boundaries of the first conductive trace. Another conductive trace is secured to the first conductive trace, with a dielectric therebetween, to form a resonant circuit.

Abstract: A method of making a resonant frequency tag which resonates at a predetermined frequency. The method involves providing a first conductive pattern having an inductive element and a first land and a second conductive pattern having a second land and a third land which are joined together by a link. The second conductive pattern is overlaid the first conductive pattern such that the second land is positioned over the first land. The third land is in electrical communication with the inductive element of the first conductive pattern. The formed resonant frequency tag is energized to determine if the tag resonates at the predetermined frequency. If the tag resonates properly, the third land is electrically coupled to the inductive element. If it does not, the second conductive pattern is adjusted so that overlapping portions of the first and second lands are changed, altering the capacitance to adjust the resonant tag frequency.

Abstract: A method of making a resonant frequency tag which resonates at a predetermined frequency comprises the steps of forming a first conductive pattern comprising an inductive element and a first land, the first land having a first end connected to one end of the inductive element, and a second end spaced a predetermined distance from the first end; separately forming a second conductive pattern comprising a second land and a link element, the second land having a predetermined width; placing the second conductive pattern proximate to the first conductive pattern at a first predetermined location so that the second land overlies at least a portion of the first land with a dielectric therebetween to establish the plates of a capacitive element with a first predetermined capacitance which with the inductive element forms a resonant circuit; measuring the resonant frequency of the resonant circuit and comparing the measured frequency with the predetermined frequency; if the resonant frequency does not match the prede

Abstract: A method of making a resonant frequency tag which resonates at a predetermined frequency comprises the steps of forming a first conductive pattern comprising an inductive element and a first land, the first land having a first end connected to one end of the inductive element, and a second end spaced a predetermined distance from the first end; separately forming a second conductive pattern comprising a second land and a link element, the second land having a predetermined width; placing the second conductive pattern proximate to the first conductive pattern at a first predetermined location so that the second land overlies at least a portion of the first land with a dielectric therebetween to establish the plates of a capacitive element with a first predetermined capacitance which with the inductive element forms a resonant circuit; measuring the resonant frequency of the resonant circuit and comparing the measured frequency with the predetermined frequency; if the resonant frequency does not match the prede