A system, method, and computer program product for implementing electronically generated promotion deployment is provided. The method includes receiving electronic data comprising shipment identification for a shipment of an item from a shipping client to a recipient. Specialized programmable software code is generated and a resulting profile is generated for the recipient. A visible promotional structure associated with a package comprising the shipment is generated and presented during delivery of the package. Generating the visible promotional structure may include generating a physical structure or a digital structure.

A server, method, and computer program product for implementing electronically generated promotion deployment is provided. Package shipments being shipped from a client to at least one recipient recipient are detected. A promotional placement request associated with promotions with respect to attributes of the at least one recipient is received within a data structure. Promotional attributes from the client with the at least one recipient are cross referenced with respect to the received promotional placement request. At least one visible promotional structure associated with the promotional attributes is electronically generated. The at least one visible promotional structure is deployed during a real time delivery process of at least one package to the at least one recipient.

An object of the present invention is to provide a thin volume hologram sheet to be embedded sufficiently resistant to a mechanical stress such as a stress including a tensile stress, a shear stress and a compression stress at the time of processing even under a heating condition, a forgery prevention paper and a card using the same. The object is achieved by providing a volume hologram sheet to be embedded comprising a volume hologram layer, and a substrate disposed only on one side surface of the volume hologram layer using an adhesion means, wherein a peeling strength of the volume hologram layer and the substrate is 25 gf/25 mm or more.

Aspects of the disclosure provide for automatically generating labels for sensor data. For instance, first sensor data for a vehicle may be identified. This first sensor data may have been captured by a first sensor of the vehicle at a first location during a first point in time and may be associated with a first label for an object. Second sensor data for the vehicle may be identified. The second sensor data may have been captured by a second sensor of the vehicle at a second location at a second point in time outside of the first point in time. The second location is different from the first location. A determination may be made as to whether the object is a static object. Based on the determination that the object is a static object, the first label may be used to automatically generate a second label for the second sensor data.

A contactless communication medium according to an embodiment of the present technology includes an IC module, a first member, a second member, and a print layer. The IC module is capable of performing a contactless communication. The first member is made of a first transparent resin material, the first member including a first surface and a second surface, the first surface being a surface in which a concave portion that accommodates therein the IC module is formed, the second surface being situated opposite to the first surface. The second member is made of a second transparent resin material, the second member being connected to the first surface or the second surface. The print layer is arranged between the first member and the second member.

A physical card (in some cases without any on-board source of power or computing capabilities) is configured to maintain access information for digital bearer assets. A unique identifier visible on the card may be transmitted to a server-system to utilize functionalities corresponding to the card (e.g., based on information associated with the unique identifier) on a decentralized computing platform, like a blockchain-based decentralized computing platform. Private access information, like a secret, private key that corresponds to a public key (e.g., a public-private key-pair) or a representation of the private key (like a ciphertext thereof) and corresponding encryption key, may be physically concealed with tamper-evident components such that a user can readily determine whether the private access information was divulged. In some examples, a user is required to activate one or more tamper-evident features, thereby altering a visible state of the card, to utilize functionalities corresponding to the card.

Systems and methods include tamper-evident indicators applied to a band comprising a strap that forms a closed loop. Tamper-evident sections of the indicators provide increased security against accidental and intentional removal of the indicators. Indicators are provided with adhesives and bare areas devoid of adhesive allowing easy and secure application of indicators to bands while they are being worn and with greater ease. Indicators can be further provided with liners protecting the adhesives allowing the indicators to be easily applied by gloved hands, reducing contamination risks. Contamination and wear risks can be further reduced by supplying indicators with antimicrobial surfaces and overprint varnishing.

An identification bracelet includes a wristband securable to a wearer. The wristband includes a plurality of openings for receiving a locking rivet and one or more openings for receiving one or more color-coded pins, a housing attached to the wristband, the housing having a pair of lugs with a slit, each lug extending from each side of the housing and adapted to receive the corresponding ends of the wristband inserted into the corresponding slits. The housing comprises a snap-on cover with at least a portion of the cover being transparent, a base, and a waterproof gasket insertable into the base. The snap-on cover is configured to be snapped on the base thereby creating a hermetically sealed waterproof structure. The housing also includes an information tag insertable into the housing and visible through the transparent portion of the housing.

A label includes a recycled sloop type radio frequency identification (RFID) tag from a previously used label. The RFID tag is removed from the previous label by cutting the RFID tag from the previous label using a laser, die, or cutting wheel. The conductor antenna of the RFID tag can be cut to remove damaged portions or change operation of the RFID tag. A slot in the conductor antenna can be resized to tune the RFID tag to allow the RFID tag to be used for the same application use or a different application use. The label can include indicia such as machine readable indicia and human readable indicia. The extracted RFID tag can include portions of the previous label, which can be free of indicia.

Self-laminating label assemblies, self-laminating labels and methods for laminating label facestocks are described herein. The self-laminating label assemblies may include a label support liner and one or more self-laminating label(s) releasably affixed to the label support liner. Each self-laminating label may include a label facestock releasably affixed to the label support liner and a laminating facestock for at least partially laminating the label facestock. The laminating facestock may be releasably affixable to the label support liner, directly or indirectly, and may be provided between a non-laminating configuration in which at least part of the aminating facestock is releasably affixed to the label support liner for holding the laminating facestock thereon or thereabout, and a aminating configuration in which the laminating facestock is at least partially affixed to, and laminates, the label facestock.