Disclosed embodiments may include a device that may receive data corresponding to transaction card(s) associated with a user. The device may receive first photograph(s) of the user, the first photograph(s) associated with first respective date(s) and first respective time(s). The device may dynamically display a first most recent photograph. The device may receive a request from the user to complete a transaction, the request comprising a selection to utilize first data of the data corresponding to at least one transaction card of the transaction card(s). The device may retrieve the first data to enable the user to complete the transaction. The device may also receive a second photograph associated with a second date and a second time. The device may update the dynamic display with a second most recent photograph by comparing the first respective date(s) and first respective time(s) to the second date and second time.

When forming smartcards or pre-forms thereof additional functionality may be implemented by, for instance, incorporating components, such as a display device, and the like, by preparing pre-packages separately from the rest of the pre-forms and subsequently inserting the pre-packages into the pre-forms, thereby achieving superior process robustness and production yield.

Systems, methods, and processor-readable storage media for remote controlling of electronic shelf labels. An example method includes receiving, at a computing device, store layout data of a retail store and product data. The product data identifies at least one product and a price of the product. The method causes an optical emitter to emit an optical signal to at least one electronic shelf label based at least in part on the store layout data, the product data, and a predetermined rule. The optical signal bears the product data and is configured to cause the electronic shelf label to change displayable information to reflect new product data. The electronic shelf label can also send feedback to the optical emitter to inform that the optical signal was successfully received.

An integrated circuit, a wireless communication card and a wiring structure of an identification mark are provided. The integrated circuit includes a power supply wiring, a ground wiring and at least one identification mark pattern. Each identification mark pattern has a first conductive wiring and a second conductive wiring that overlap each other, wherein the first conductive wiring is electrically connected to the power wiring, and the second conductive wiring is electrically connected to the ground wiring.

Exemplary embodiments relate to updatable displays for transaction cards, such as credit cards or event passes. The displays may be, for instance, an electrophoretic or memory liquid crystal diode display. The transaction card may include a contact pad capable of engaging in wireless communication. Information may be exchanged between the transaction card and a mobile device or terminal, where a processor on the mobile device processes the received information to generate displayable information. The processor updates the display with the displayable information. The contact pad may be electrically connected to the display, and the display may derive electrical power to perform the updating from the wireless communication. For example, where the wireless communication is a near field communication (NFC), a radio frequency field may be generated that supplies enough power to run the processor and at least partially update the display.

A computerized transaction card is provided and includes a plastic form factor resembling a credit card, the form factor including all or a combination of a magnetic stripe, a euro-pay master card and visa (EMV) chip, and or a near field communication (NFC) chip, a micro-controller powered by a rechargeable battery, at least one wireless chip set for sending and receiving data over a local wireless network; and, an interactive display screen for displaying information to a card operator.

Monitoring and authorizing collection of printed media. A print task is received. A unique electromagnetic (EM) signature is generated for the received print task. Files for the print task are printed including the EM signature. Communication information is received including information exchanged between a radio frequency identification (RFID) badge associated with a user requesting access to a common printing area and a RFID reader associated with the common printing area, and information by an electromagnetic detector of a computer from the EM signature. Based on the first and second set of received communication information, an attempted collection of the printed media by the print task owner is determined. If the attempted collection is not made by the print task owner, a notification is transmitted to a computer associated with the print task owner indicating an unauthorized attempted collection of the printed media.

An electronic module for a chip includes a first dielectric substrate provided on one of the faces thereof with a first microelectronic chip whose input/output terminals are connected to first connection pins which are arranged around the first microelectronic chip, and a second dielectric substrate which is placed directly opposite the first substrate and which is provided on one of the faces thereof with a second microelectronic chip whose input/output terminals are connected to second connection pins which are arranged around the second microelectronic chip. The first and second microelectronic chips are arranged on the faces of the substrates directed towards the interior of the electronic module. A dielectric shim has a calibrated thickness and separates the first and second dielectric substrates. The shim has through-holes or vacancies accommodating electrically conductive materials connecting some of the first connection pins to some of the second connection pins.

Systems and methods are disclosed for using a color changing surface to display a status of a storage device. In certain embodiments, a storage includes a display-less enclosure, non-volatile memory, memory configured to store firmware, and control circuitry. The control circuitry can be configured to determine an available space in the non-volatile memory, determine a first color corresponding to the available space based on a mapping of ranges of available space to corresponding colors, apply a voltage to the electrochromic material to change the color changing surface to the first color, and cease application of the voltage to the electrochromic material, wherein the color changing surface retains the first color after cessation of the voltage.

An electronic device including an electronic assembly and an enclosure. The electronics assembly including a host interface and a direct user input interface. The direct user input interface remains exposed when the device is connected to a host via the host interface. The enclosure, substantially in the form factor of a microSD device, forms the outer boundary of the electronic device, overmolded on the electronics assembly.