The disclosed embodiments provide a method for tamper-evident shipment or storage of goods. An Electrical Shield pattern is embedded in or printed on a substrate with other electrical, optical, and electronic components, communication components, semiconductors, which are attached or printed on a substrate to form a shipment bag used as a shipping container. The shield pattern can be made variable between different bags by using algorithms entered into a printer control system. The shipment bag with its components can then be assigned a unique signature which differentiates each bag. Application of encryption methods serves to guarantee the shipped goods are authentic and that were not tampered with during shipment. Digital signal processing is used to generate pedigree information, which may include items such as shipping location, serial numbers, sensor information, and lot numbers for the goods. The information related to the history of tampering attempts and other sensor status can be placed in encrypted form in an RFID tags or control or monitoring electronics which can be read by a mobile phone application or sent to a remote cloud-based server.

A system for detecting tampering in a product having a tamper-detector seal, including a secure element configured to store a digital signature and a data associated with the digital signature, transmit the digital signature and the data associated with the digital signature in response to a request, detect tampering of the tamper-detector seal, and modify the data associated with the digital signature if tampering is detected. The system further includes a seal validation device configured to receive a public key associated with the product, request the digital signature and the data associated with the digital signature from the secure element, and validate the digital signature utilizing the data associated with the digital signature and the public key associated with the product.

The present invention concerns a secure sealing device 101 comprising at least a closure element 102 with an electrically conductive path 120, and a locking body 103 comprising an electric circuit with a data carrier and a radiofrequency transceiver with a predetermined working wavelength. Said locking body 103 is configured be locked to at least one free end 102a of said closure element 102 to attach the locking body 103 to an object to be sealed. The electrically conductive path 120 of the closure element 102 has a length which is substantially equal to X or ½.sup.X times half said predetermined working wavelength of the radiofrequency transceiver, thus enhancing the range of the radiofrequency transceiver by inductive coupling.

A label including an RFID tag according to one embodiment of the present invention is configured to be selectively attached and detached in such a manner that one region of the label is attached and fastened onto a product box in a strong adhesive manner and a label region including an RFID tag is attached onto the product box in a weak adhesive manner, and thus a user is enabled to check information that is described on one region of the product box and is covered with the RFID tag. In this case, when the amount of information to be described on the product box is excessively large and thus all the information cannot be described, a space for the description of information can be enlarged by describing the remaining information in one region of the first base film of the label.

The present invention relates to a baggage tag (1) to be fastened to a luggage, such that the luggage can be tracked and traced via the baggage tag. The baggage tag comprising a face material (5) with a first side (6) and a second side (7). A liner (8) with a first side (9) and a second side (10), wherein the first side is siliconized and facing against the second side (7) of the face material (5); and a pressure sensitive adhesive layer (11), which is arranged between the second side of the face material and the first side of the liner. The baggage tag further comprising an RFID tag which tag comprises an RFID antenna (3) and an IC (4) attached onto the antenna such that the antenna and the IC form the RFID tag and wherein the RFID antenna is formed directly onto the second side of the liner.

A method for manufacturing a carrier tape housing a plurality of electronic components with seal materials includes forming housing holes in tape-shaped main body with first and second principal surfaces along a longitudinal direction of the tape-shaped main body, the housing holes penetrating from the first principal surface to the second principal surface, affixing an adhesive layer of a tape-shaped seal material to the second principal surface of the tape-shaped main body to cover the housing holes, forming cuts in the tape-shaped seal material to separate portions defining and functioning as the seal materials including portions at least partially overlapping with the respective housing holes in a planar view from the other portions, and providing chip-shaped electronic component into each of the housing holes of the tape-shaped main body and fixing the electronic component to the adhesive layer of the seal material exposed in each of the housing holes.

A fastener with a head element that is coupled to a strip element is disclosed. The strip element is configured to fasten to the head element via an attachment structure of the head element. An identification device is molded into the fastener. The identification device has an identifier integrated circuit (IC) within an IC package and an antenna, having a portion internal to the IC package and a portion extending out of the IC package, coupled to the identifier IC.

A packaging system or tag is provided for at least one article or item, which employs a multilayer laminate structure that includes an encapsulated transformative material that is disposed between first and second conductive layers. The transformative material is configured to undergo a state change (for example, by a chemical reaction or physical change) that changes impedance between the first and second conductive layers in response to an intrusion or perforation through at least part of the multilayer laminate structure. Furthermore, one of the first and second conductive layers can be configured (for example, by printing or etching) to provide an RF antenna and a first electrode of the at least one integrated galvanic cell. The other of the first and second conductive layers can provide a second electrode of the at least one integrated galvanic cell. The at least one integrated galvanic cell is further provided by encapsulated electrolyte material and ion bridge disposed between the first and second conductive layers. At least one NFC/RFID integrated circuit is mechanically secured to the multilayer laminate structure (for example, in space between the first and second conductive layers) and electrically coupled to the coil antenna, the at least one galvanic cell, and other parts of the first and second conductive layers of the multilayer laminate structure. The galvanic cell can also be made to have long shelf life.

A labeling set for marking a pharmaceutical vessel including a body having a peripheral surface and a removable closure includes: a three-dimensional molded attachment, a label for sticking on the outer vessel circumference to be marked, and an RFID transponder for electronic identification of the vessel and/or contents. The attachment is mountable and/or positionable on the vessel in a predefined relative position and has a circumferential wall with an outer circumferential surface which is intended as an additional labelable and/or electronically identifiable outer wall and/or outer surface and whose radius, outer circumference and/or wall course is selected in accordance with the radius, outer circumference and/or wall course of the vessel circumferential surface. The label and/or the RFID transponder sticks over and/or covers both a circumferential surface, formed in accordance with the vessel body outer circumference, and the attachment circumferential surface at least in regions and/or to secure the vessel attachment to the vessel.

The present disclosure relates to the field of security systems and discloses a tamper detection device. The device (100) comprises at least one transducer (106,110), a power supply unit (114), a logical gate (112), a processing unit (104), and, a tamper tag 102). The transducer (106,110) generates a trigger signal upon detection of a tamper event. The logical gate (112) is operable in an open state or a closed state. The processing unit (104) generates a tamper detection signal for changing the state of the logical gate (112) upon receiving the trigger signal or upon detecting loss of power supply from the power supply unit (114). The change in state of logical gate (112) causes a tamper flag value stored in the tamper tag (102) to change, thereby indicating a tampered status to a reader scanning the tamper tag (102). The device (100) detects a tamper event even if the device (100) is not damaged/broken during tampering.