Abstract: Semiconductor wafer devices are formed of a wafer or a portion of a wafer. The wafer or wafer portion includes a plurality of functional blocks, one of which comprises an energy source and another which takes some other form, such as digital logic, data storage, a communication module, a display, a display driver, or a sensor. A functional block may be formed as part of processing of the wafer or may comprise a post-processing element. The functional blocks combine to provide an operational system having a plurality of functions. The wafer may be formed of an amorphous material, allowing the device to have a three-dimensional, non-planar structure, such as a cuboidal or tubular structure. If the device comprises only a portion of a wafer, a plurality of devices may be formed from a single wafer, with each portion being removed from the remainder of the wafer to define a device.

Abstract: RFID tags are provided for incorporation into the packaging of a microwavable food item, with the RFID tag being configured to be safely microwaved. The RFID tag includes an antenna defining a gap and configured to operate at a first frequency. An RFID chip is electrically coupled to the antenna across the gap. A shielding structure is electrically coupled to the antenna across the gap and overlays the RFID chip. The shielding structure includes a shield conductor and a shield dielectric at least partially positioned between the shield conductor and the RFID chip. The shielding structure is configured to limit the voltage across the gap when the antenna is exposed to a second frequency that is greater than first frequency. In additional embodiments, RFID tags are provided for incorporation into the packaging of a microwavable food item, with the RFID tag being configured to be safely microwaved. The RFID tag includes an RFID chip and an antenna electrically coupled to the RFID chip.

Abstract: A temperature-sensing RFID device includes an RFID chip and an antenna electrically coupled thereto. The RFID chip includes a temperature sensor, while the antenna is adapted to receive energy from an RF field and produce a signal. A shielding structure and/or a thermally conductive or absorbent structure may be associated with the RFID chip. The shielding structure is oriented so as to be positioned between at least a portion of the RFID chip and an outside environment and configured to shield the temperature sensor from at least one environmental factor capable of affecting a temperature sensed by the temperature sensor of an article to which the RFID device is secured. The thermally conductive or absorbent structure is oriented so as to be positioned between at least a portion of the RFID chip and the article and configured to enhance thermal coupling between the temperature sensor and the article.

Abstract: A high-field emission tolerant RFID tag device that may be secured to a product to be cooked, heated, reheated and/or thawed in a heating apparatus such as, but not limited to, a microwave oven and that does not need to be removed from the product before initiating the heating process. The RFID device is microwave safe and does not damage the product or food item to which it is attached during the microwave process, and may contain data to control the microwave process. The microwave safe RFID tag comprises a split ring (or shield) conductor formed on one side of a substrate (or dielectric), a coil antenna conductor formed on an opposite side of the substrate, and a RFID chip. The split ring conductor capacitively couples to the coil antenna conductor via the dielectric and a gap in the split ring conductor prevents arcing.

Abstract: Systems and methods of using ultrasonic welding to form labels with RFID tags are disclosed. The methods can be useful for the production of a large volume of labels such as production with roll-to-roll processing. The labels can be useful for consumer products such as garments. The present invention discloses in one embodiment, a label having a first and second printed fabric label layer such that a radio frequency identification (RFID) inlay is disposed between the two printed fabric layers.

Abstract: Systems and methods are provided for assembling an RFID device mounted to a fabric substrate via a “flip chip” approach. The system includes a pin thermode with a tip configured to penetrate the fabric substrate. The pin thermode may include or omit a heating element, with the tip being variously configured. The tip may have a variable cross-sectional area or include a plurality of projections that separately penetrate the fabric substrate, for example. If the pin thermode includes a heating element, a body of the pin thermode may be formed of a low thermal conductivity material to allow the temperature of the tip to increase without increasing the temperature of the body to the same degree. The body may define a lumen, with the tip and/or body defining an aperture for flowing a liquid out of the pin thermode and into the region surrounding the pin thermode.

Abstract: RFID tags are provided for incorporation into the packaging of a microwavable food item, with the RFID tag being configured to be safely microwaved. The RFID tag includes a substrate having opposing first and second surfaces. An antenna is secured to the first surface, with the antenna defining a gap and being configured to operate at a first frequency. An RFID chip is electrically coupled to the antenna across the gap. A shielding structure is secured to the second surface of the substrate, with at least a portion of the shielding structure being in substantial alignment with the gap. The shielding structure is configured to limit the voltage across the gap when the antenna is exposed to a second frequency that is greater than first frequency. Also provided are methods for manufacturing RFID tags from a web in which conductive layers are secured to opposing surfaces of a substrate.

Abstract: An RFID reader apparatus designed to limit interference in a role of auditing individual RFID tagged or labeled items in areas of surrounding dense RIFD transponder populations. Such an RFID reader apparatus may include an RFID reader, a specialized antenna, and an enclosure, which may be constructed from ferrous material and which may be configured to hold the RFID reader and the specialized antenna in separate compartments. The enclosure may have one or more shelves, which may also be constructed from ferrous material. The RFID reader apparatus may also have a lid constructed from non-ferrous material. The RFID reader apparatus may be fitted to the bottom of an auditing workstation, for example with screws or other connectors, or may be placed within an auditing workstation specifically equipped to accommodate it.

Abstract: A labeling apparatus comprises a separation member configured to promote detachment of an adhesive label from liner web. Adhesive labels are fed to the separation member such that a surface of the facestock contacts the separation member. The separation member has a surface exhibiting a tack such that the tack force between the facestock and the separation member is greater than the release force between the release liner and the adhesive layer of the labels. The labels become associated with the separation member, and the label is applied to a surface of a substrate by contacting the exposed adhesive layer with a surface of a substrate, which causes the adhesive label to detach from the separation member.

Abstract: A method for recovering missed RFID tagged items in an RFID tunnel environment is disclosed. The method comprises using a dynamic RFID tunnel system comprised of a first RFID tunnel and a second RFID tunnel to inventory one or more containers of items having RFID tags. A first RFID read of the one or more containers is performed in the first RFID tunnel and compared to an expected containers' inventory stored in a database. If the comparison does not match, a second RFID read of the containers is performed in a second, subsequent RFID tunnel at a higher RFID read power and by moving the containers at a speed slower than a speed of movement of the containers into the first RFID tunnel. If a comparison of the second read to the expected containers' inventory still does not match, the containers may be recirculated through the tunnel system or may be diverted to an exceptions audit depending on how the system is configured.

Abstract: The present invention relates to heat transfers that include silicone based heat transfer inks and digitally printed toner images, particularly for use on fabrics, apparel items, garments and accessories. The present subject matter is especially suitable for use in heat-transferable labeling or creating embellishments on polyester fabrics and garments.

Abstract: A system and method is provided for delivering customized information related to a specific product of interest to consumer. In practice, the consumer uses a suitably enabled portable, mobile and/or wireless device (e.g., such as a mobile camera phone) to scan or otherwise read a marker associated with a product, retail item or other article of interest. From the marker, a unique ID is obtained (i.e., the marker ID). The marker ID is then used to cross-reference a URL or other like address in a database that relates marker IDs to corresponding URLs. The target URL is returned to the consumer's device and an http session is established with a content management server at the target URL. In one suitable embodiment, the content management server obtains a SKU and/or template web page ID that are associated with the marker ID in a database. Suitably, the SKU relates to the specific product with which the marker was associated.

Abstract: High density read chambers are provided for scanning and/or encoding a plurality of RFID tagged items. Such chambers may include an enclosure with an interior defined by upper and lower surfaces, with a sidewall extending therebetween. An access (such as a door) may be associated with at least one of the surfaces or the sidewall, with the access being at least partially opened to access the interior of the enclosure from an outside location. The chamber further includes an antenna positioned within the interior of the enclosure and an RFID reader associated with the antenna. The RFID reader receives signals from and/or transmits signals to the antenna, while the antenna emits a scanning or encoding signal within the interior of the enclosure, with at least a portion of at least one of the surfaces or the sidewall including a signal-reflective material facing the interior of the enclosure.

Abstract: A system for processing barcode information provided by the user, which may be used to print and encode RFID-enabled product labels. The system may include a bar code scanner or may include a manual bar code entry interface such as a keyboard and mouse, and may be configured to output a label corresponding to a barcode once the barcode has been scanned, optionally with user customization by an operator and optionally including variable data provided through a variable data module. This system may allow for the calculation of EPC values, the tracking of serial values used in the printing process, exporting of the printing history, and printing and encoding of tag.

Abstract: The present invention relates to a method of manufacturing a metal foil laminate which may be used for example to produce an antenna for a radio frequency (RFID) tag, electronic circuit, photovoltaic module or the like. A web of material is provided to at least one cutting station in which a first pattern is generated in the web of material. A further cutting may occur to create additional modifications in order to provide additional features for the intended end use of the product. The cutting may be performed by a laser either alone or in combinations with other cutting technologies.

Abstract: A combined EAS and RFID circuit includes an HF coil antenna, a UHF tuning loop, and an RFID chip coupled to a strap that includes a first coupling area and a second coupling area. The coil ends of the HF coil antenna are configured to capacitively and/or conductively couple to one or both of the first coupling area or second coupling area of the strap. The HF coil antenna can include a gap between turns for non-interfering placement of the UHF tuning loop. The EAS circuit can be deactivating upon application of a field at the resonant frequency of sufficient intensity to cause the breakdown voltage to be exceeded between a coil end and coupling area. The threshold breakdown voltage between a coil end and a coupling area can be reduced by laser ablation treatment of a conductive surface of one or both of the coil end or coupling area.