A card exhibiting multiple linear arrays of sensors are provided to detect a presence and movement of an external object (e.g., a read-head of a magnetic stripe reader). Each sensor of each array of sensors may be independently connected to a dual port of a processor so that the processor may determine a direction in which the card is swiped through a magnetic stripe reader. A portion of sensors of each array of sensors may be shared by a portion of inputs and/or outputs of a single port of a processor. Sensors may be cross-coupled to a single processor port so that forward and reverse directions of a card swipe may nevertheless be detected by a single-port processor of a card.

Various electronic credentials comprising signal activation are disclosed. An electronic credential core comprises a controller configured to maintain an off-state until activated by a received signal during a personalization process. The electronic credential core further comprises an antenna configured to receive a first signal. The energy in the first signal is harvested by a signal interface. The signal interface generates a second signal using the harvested energy of the first signal. The second signal is provided to the controller. The controller transitions to an active state and continuously performs one or more functions until an onboard battery is depleted. By maintaining an off-state until personalization, the electronic credential can be stored without draining power from the battery, extending the shelf life of the electronic credential.

Magnetic stripe cards including a skimmer detection mechanism detect unauthorized access to data and information stored on a magnetic strip of a magnetic stripe card by illicit card skimming devices. In one embodiment, a method of detecting an unauthorized scan of confidential data encoded on a magnetic strip portion of a magnetic stripe card having a skimmer detection mechanism includes detecting a scan of the magnetic strip portion, measuring a parameter associated with the scan of the magnetic strip portion by the skimmer detection mechanism, and comparing the measured parameter to a baseline value associated with the parameter. Upon determining that the parameter exceeds the baseline value, an unauthorized scan of confidential data encoded on the magnetic strip portion of the magnetic stripe card is detected.

A card, such as a payment card, or other device may include an electronics package. The electronics package may include an RFID antenna. The RFID may not be utilized to access data on the card, or other device, until the appropriate manual input is received into the card or other device. Such manual input may take the form of a manual press of a physical button or the manual activation of a virtual button on a touch-screen device (e.g., a touch-screen mobile phone or card).

A transaction card includes at least one metal layer having one or more apertures therein. A light guide is disposed beneath the metal layer. The light guide has a light output and a light input. The light output is positioned to transmit light through at least the one or more apertures of the metal layer. At least one LED is positioned to transmit light into the light input of the light guide.

Provided herein are systems and methods comprising two or more localization agents that are linked together by a linker. For example, provided herein are systems and methods for the placement of two or more linked localization devices within biological systems and the detection of such localization devices for targeted surgeries or other medical procedures. For example, provided herein are systems comprising one or more miniature detectable devices that are linked together, that are placed into a target location and activated by remote introduction of a magnetic field.

A flexible card may include a dynamic magnetic stripe communications device having multiple layers, such as an electromagnetic generator, a magnet, and a shield. A shield may form a non-flexible layer within the stack and may bend, but the shield may not be able to stretch or compress. Flexible layers may surround and adhere to the shield such that when the card is flexed, the flexible layers may stretch and compress with the movement of the shield. The dynamic magnetic stripe communications device may include one or more coils. Each coil may contain a stepped material, such that a length of a lower layer of the stepped material is longer than a length of a middle layer of the stepped material which is longer than a length of a top layer of the stepped material.

A piece of jewellery, wherein the jewellery comprises at least one tag or chip programmed with at least a unique identification code, and a tag reader is configured to read the tag or chip when the tag reader and the piece of jewellery touch, or come into close contact and, display a message or content associated with the unique identification code.

A fluid treatment cartridge includes a housing having a fluid inlet and a fluid outlet with a treatment media contained within the housing. The fluid treatment cartridge includes a detection member comprising at least one closed electrically conductive loop having at least two spatially separate sections. Each of the sections generates a magnetic response when at least one section is electromagnetically excited. The magnetic response of each section is predetermined by the physical shape of the section and comprises at least one of a predetermined magnetic phase response and a predetermined magnetic amplitude response. The predetermined magnetic response of at least one other section of the closed electrically conductive loop corresponds to at least a one digit code.

The present invention provides integrated circuit chips having chip identification aspects. The chips include magnetic tunnel junction (MTJ) structures, and more specifically, include permanent bit strings used for chip identification and/or authentication. Systems and processes for chip identification are also disclosed herein. The MTJ element structures provided herein can have a defined resistance profile such that the intrinsic variability of the MTJ element structure is used to encode and generate a bit string that becomes a fingerprint for the chip. In some embodiments, an oxygen treatment covering all or a selected portion of an array of MTJ elements can be used to create a mask or secret key that can be used and implemented to enhance chip identification.