A method for glare reduction may be implemented by a graphical code reader. The graphical code reader includes an optic system, a plurality of light sources, and a control system. The control system is configured to determine that glare is present in an image captured by the optic system by identifying reflection from at least one of the plurality of light sources. The control system may take a corrective action to reduce the glare in subsequent images. The control system may be configured to take a first corrective action if a diffraction pattern is present at a periphery of the glare, and take a second corrective action if a diffraction pattern is not present at the periphery of the glare.

A sensor system for counting cards includes an optical sensor assembly configured to detect edges of cards in a card stack. The optical sensor assembly includes at least an optical sensor, and a light element coupled with the optical sensor. The light element is configured to reflect light from a card stack toward the optical sensor. A remote light element is spaced from the optical sensor assembly. The remote light element is configured to direct light toward the card stack.

An accuracy-enhanced scanner provides (in response to a first user input) illumination of potential scan targets and scans (in response to a second user input) a selected scan target. The user uses the illumination to aim the scanner at the selected scan target in between providing the first and the second user inputs. The scanner has switches to communicate the user inputs, to specify an operating mode for the scanner, and/or to communicate information codes to a computing device. The scanner has one or more scan engines (such as a barcode reader or an RFID tag reader), and optionally communicates wirelessly with the computing device. A scanning system including the scanner optionally provides feedback to the user based on feedback from a host processor. The scanner is any of a Multi-Mode Ring Scanner (MMRS), a cordless hand scanner, or a Personal Digital Assistant (PDA) with an add-on scanner.

A method for glare reduction may be implemented by a graphical code reader. The graphical code reader includes an optic system, a plurality of light sources, and a control system. The control system is configured to determine that glare is present in an image captured by the optic system by identifying reflection from at least one of the plurality of light sources. The control system may take a corrective action to reduce the glare in subsequent images. The control system may be configured to take a first corrective action if a diffraction pattern is present at a periphery of the glare, and take a second corrective action if a diffraction pattern is not present at the periphery of the glare.

A method and control system for optimizing active measurements are presented. In an embodiment, the method includes emitting at least one active signal in at least one direction; determining whether a return signal is detected for each of the at least one active signal; upon detecting at least one return signal for the at least one active signal: measuring a strength of each return signal; comparing the measured strength of each return signal to at least one optimal return signal strength; and determining, based on the comparison, an optimized configuration for active measurement emissions in one or more directions.

A code reader may include a housing configured to be wearable by a user, a scanning unit configured to scan machine-readable indicia of a target area, a user interface connected to the housing and configured to present identification data associated with the machine-readable indicia to the user, a power source disposed within the housing, a processing unit disposed within the housing, and a plurality of electrical conductors in electrical communication with the processing unit and the user interface. The processing unit may be configured to communicate a scan signal to the scanning unit to cause the scanning unit to scan the target area, receive response data from the scanning unit representative of the machine-readable indicia, generate the identification data in response to receiving the response data, and communicate the identification data to the user interface for display thereon. The electrical conductors may provide power and enable signals to be communicated.

In some embodiments, apparatuses and methods are provided herein useful for identifying an object using radiopaque ink. In some embodiments, a system for identifying an object comprises an object having an identifying marking formed of a radiopaque ink comprising a solvent and a plurality of nanoparticles having an average diameter from about 5 nm to about 300 nm suspended in the solvent, each nanoparticle comprising at least 50,000 atoms having an atomic number of 53 or greater. A control circuit causes a radiographic imaging device to irradiate the object, receives from the radiographic imaging device image data associated with the object, processes the image data to generate an x-ray image showing the identifying marking of the object, causes a display device to display the x-ray image showing the identifying marking of the object, and identifies the object based on the identifying marking of the object shown in the x-ray image.

Scanners, methods, and computer storage media having computer-executable instructions embodied thereon that process variable sized objects with high package pitch on a moving conveyor belt are provided. The scanners are laser scanners that include at least two laser diodes, sensors, and field programmable gate arrays processors. The at least two laser diodes have different focuses. Each diode generates a laser beam when excited by an activation signal and an appropriate modulation. The sensors within the laser scanner device measure light reflected from a target on the objects. The processors toggle activation among the at least two laser diodes based on measurements sensed from the light reflected from the target.

An information recording medium according to one embodiment includes a substrate, a first image, and a second image. The first image is provided on the substrate, emits light when irradiated with first excitation light having a first wavelength, and includes phase-modulated first information. The second image is provided on the substrate, emits light when irradiated with second excitation light having a second wavelength different from the first wavelength, and includes phase-modulated second information.

A portable scanner with improved user feedback provides scan data to a networked computing node via a wireless interface and the Internet. The portable scanner receives user feedback information from the networked computing node via the wireless interface and the Internet. The user feedback information indicates successful entry of the scan data into a database, or alternatively successful receipt of the scan data by the networked computing node. The portable scanner sets a scan status indicator to a final state in response to the user feedback information. Optionally, the database is a remote database that a local database is synchronized with, and/or the database is associated with the networked computing node. Optionally the portable scanner is wearable. Optionally the portable scanner is compatible with barcode and/or RFID technologies.