A reading system includes a portable information terminal configured to recognize information in a symbol on the basis of an acquired image, and a wearable camera that functions as a peripheral device for the portable information terminal. The camera has an image sensor configured to generate the image, and is configured to transmit the generated image to the portable information terminal.

An inspection apparatus for optical inspection of a card insertion slot of a card reader. The apparatus includes a housing holding a magnifier lens assembly, the magnifier lens assembly being mounted through the housing, from a back face to a front face of the housing; at least two guiding elements, protruding outwards the front face of the housing; and at least two light sources located on a front side of the inspection apparatus. The inspection apparatus is further configured so that the at least two guiding elements, the at least two light sources, and an optical axis of the magnifier lens assembly are substantially contained in a same plane.

An inspection apparatus for optical inspection of a card insertion slot of a card reader. The apparatus includes a housing holding a magnifier lens assembly, the magnifier lens assembly being mounted through the housing, from a back face to a front face of the housing; at least two guiding elements, protruding outwards the front face of the housing; and at least two light sources located on a front side of the inspection apparatus. The inspection apparatus is further configured so that the at least two guiding elements, the at least two light sources, and an optical axis of the magnifier lens assembly are substantially contained in a same plane.

Existing currency validation (CVAL) devices, systems, and methods are too slow, costly, intrusive, and/or bulky to be routinely used in common transaction locations (e.g., at checkout, at an automatic teller machine, etc.). Presented herein are devices, systems, and methods to facilitate optical validation of documents, merchandise, or currency at common transaction locations and to do so in an obtrusive and convenient way. More specifically, the present invention embraces a validation device that may be used alone or integrated within a larger system (e.g., point of sale system, kiosk, etc.). The present invention also embraces methods for currency validation using the validation device, as well as methods for improving the quality and consistency of data captured by the validation device for validation.

Existing currency validation (CVAL) devices, systems, and methods are too slow, costly, intrusive, and/or bulky to be routinely used in common transaction locations (e.g., at checkout, at an automatic teller machine, etc.). Presented herein are devices, systems, and methods to facilitate optical validation of documents, merchandise, or currency at common transaction locations and to do so in an obtrusive and convenient way. More specifically, the present invention embraces a validation device that may be used alone or integrated within a larger system (e.g., point of sale system, kiosk, etc.). The present invention also embraces methods for currency validation using the validation device, as well as methods for improving the quality and consistency of data captured by the validation device for validation.

Example embodiments of systems and methods for data transmission between a contactless card and a receiving application are provided. The transmitting device may include a processor, memory, and communication interface. A receiving application may include instructions for execution on a receiving device having a processor, a memory, a communication interface configured to create a communication field for data communication with the transmitting device, and one or more sensors. Upon movement of the transmitting device, the receiving application is configured to receive, via one or more sensors, feedback information associated with the transmitting device, display one or more instructions regarding the position of the transmitting device relative to the receiving device until the transmitting device enters the communication field. Upon entry into the communication field, the transmitting device is configured to transmit data to the receiving device.

Example embodiments of systems and methods for data transmission between a contactless card and a receiving application are provided. The transmitting device may include a processor, memory, and communication interface. A receiving application may include instructions for execution on a receiving device having a processor, a memory, a communication interface configured to create a communication field for data communication with the transmitting device, and one or more sensors. Upon movement of the transmitting device, the receiving application is configured to receive, via one or more sensors, feedback information associated with the transmitting device, display one or more instructions regarding the position of the transmitting device relative to the receiving device until the transmitting device enters the communication field. Upon entry into the communication field, the transmitting device is configured to transmit data to the receiving device.

A reader includes a smartphone configured to read information from an image of a symbol included in a photographed image created by a camera module, and a unit attached to the smartphone. The unit includes a semiconductor laser to display a marker in a photographing range of the camera module. A user simply adjusts the orientation of the reader so that the marker overlaps on the symbol for reading processing of the smartphone, whereby information can be read from the symbol.

Example embodiments of systems, methods, and devices for transaction card alignment are provided. In one example embodiment, a mobile device may include a first component and a second component foldable with respect to one another between a first configuration and a second configuration. The mobile device may further include a screen interface on an interior side of the first component, and an alignment feature along the interior side, the alignment feature providing alignment for a contactless card with respect to the screen interface, wherein the contactless card is uncovered by the second component in the first configuration and covered by the second component in the second configuration.

This invention provides an aimer assembly for a vision system that is coaxial (on-axis) with the camera optical axis, thus providing an aligned aim point at a wide range of working distances. The aimer includes a projecting light element located aside the camera optical axis. The beam and received light from the imaged (illuminated) scene are selectively reflected or transmitted through a dichoric mirror assembly in a manner that permits the beam to be aligned with the optical axis and projected to the scene while only light from the scene is received by the sensor. The aimer beam and illuminator employ differing light wavelengths. In a further embodiment, an internal illuminator includes a plurality of light sources below the camera optical axis. Some of the light sources are covered by a prismatic structure for close distance, and other light sources are collimated, projecting over a longer distance.