Label constructions comprise a first section and a second section that are laminate constructions of a card stock top surface that may include printed indicia, an adhesive layer disposed underneath the card stock, and a removable liner adhered to the adhesive layer and common to the first and second sections. The first section includes an RFID device. The first section may be configured once removed from the liner to fold on itself to form an RFID tag, or to form an RFID adhesive label. The second section once separately removed from the liner forms an adhesive label. The construction first and second sections are positioned adjacent one another and are formed during the same manufacturing process for purposes of manufacturing efficiency. The first and second sections may be treated to facilitate separate removal from the liner to provide labeling flexibility.

The invention relates to a method for making a textile part (A; A1, A2), comprising a step of forming a stitched seam (c1, c2, c3; C). The stitched seam step also aims to secure an electronic tag (1) to the textile part (A; A1, A2). The electronic tag (1) is formed from a strip comprising a wired electronic device comprising a chip (3a) associated with at least one antenna wire (3b), the chip (3a) and the antenna wire (3b) being arranged inside the stitched seam (c1, c2, c3; C). The invention also relates to the textile part provided with the tag.

A wireless tag processing device includes a wireless tag reader-writer and a processor configured to acquire first and second sets of parameter values, control the reader-writer to transmit a radio wave using each parameter value of the first set and acquire a first intensity of a response wave from a wireless tag, when a highest first intensity satisfies a first condition, determine a parameter value of the first set corresponding to the highest intensity as a parameter value to be used by the reader-writer, and when the highest intensity does not satisfy the condition, control the reader-writer to transmit a radio wave using each parameter value of the second set and acquire a second intensity, and when a highest second intensity satisfies a second condition, determine a parameter value of the second set corresponding to the highest second intensity as the parameter value to be used by the reader-writer.

A wireless communication device manufacturing system is provided that includes a conveyor that conveys an antenna base material in a manner passing through a mounting position, a mounter that mounts an RFIC module on the antenna base material with an insulating adhesive layer interposed therebetween, a roller pair that nips the antenna base material having the RFIC module mounted thereon in a thickness direction of the antenna base material and presses the RFIC module against the adhesive layer, a first dancer roller freely movably placed on the antenna base material on an upstream side of the mounter, and a second dancer roller freely movably placed on the antenna base material on a downstream side of the roller pair. Moreover, each of the first and second dancer rollers includes a cylindrical portion placed on the antenna base material and locking portions provided at respective ends of the cylindrical portion.

The method for producing a strip of material with an integrated electronic component comprises the following steps according to the present invention: feeding a material web, cutting a first piece of material from the material web, lifting the first piece of material, applying an electronic component to the material web, once again feeding the material web with the electronic component located on it, cutting a piece of material from the material web to obtain a second piece of material on which the electronic component is located, and applying the first piece of material to the second piece of material so that the electronic component is accommodated between the first piece of material and the second piece of material.

Improved RFID devices and manufacturing methods that utilize more efficient RFID designs, result in less manufacturing material waste and increased recycling opportunities, all without sacrificing RFID device performance, are disclosed herein. Some exemplary embodiments of the improved RFID device may make use of a thinner foil, a hollowed-out foil, a “no-strip” design, or a tessellated design that may reduce material usage. Other exemplary embodiments may use a lower-impact and/or biodegradable adhesive so as to improve aluminum recycling and lessen risks to the environment.

Disclosed are combination radio frequency identification (RFID) and electronic article surveillance (EAS) tags and methods of producing such tags using a converting machine. The method is characterized by feeding a first roll carrying first type inlays and a second roll carrying second type inlays into a converting machine; and, transferring, using the converting machine, the first type inlays to a surface of the second type inlays, thereby forming a two-layer tape carrying pairs of first and second type inlays, each of the pairs comprising an RFID inlay and an EAS inlay, wherein there is no overlap of an RFID antenna element of each RFID inlay and an EAS antenna element of a paired EAS inlay, and wherein the RFID inlay and the EAS inlay of each pair are functionally independent.

Apparatus and methods disclosed herein provide technical solution for on-demand manufacturing of a payment instrument that includes an integrated circuit chip. Apparatus and methods provide technical solutions for securely validating and activating the manufactured payment instrument. The customer may submit a request to manufacture a payment instrument through an automated teller machine (“ATM”), online banking channel or mobile banking channel. Apparatus and methods allow a customer to manufacture a payment instrument at home using a 3D printer or use a 3D printer installed at an ATM. Using a secure validation methods, the newly manufactured payment instrument may be activated at an ATM.

Apparatus and methods disclosed herein provide technical solution for on-demand manufacturing of a payment instrument that includes an integrated circuit chip. Apparatus and methods provide technical solutions for securely validating and activating the manufactured payment instrument. The customer may submit a request to manufacture a payment instrument through an automated teller machine (“ATM”), online banking channel or mobile banking channel. Apparatus and methods allow a customer to manufacture a payment instrument at home using a 3D printer or use a 3D printer installed at an ATM. Using a secure validation methods, the newly manufactured payment instrument may be activated at an ATM.

In some implementations, a wireless sensing system may receive sensor data associated with an asset. The sensor data may be associated with a tampering event and the tampering event may include an action performed on the asset. The wireless sensing system may further determine whether the tampering event is performed by an authorized user of the wireless sensing system. The wireless sensing system may further determine whether the tampering event is performed within an authorized location of the wireless sensing system. The wireless sensing system may transmit a notification to a user of the wireless sensing system. The notification may alert the user of the wireless sensing system that the tampering event has occurred.