A storage system may comprise a common characteristic label comprising a first scannable code correlated to a first catalogue information and at least one origin or destination label having a second scannable code correlated to a second catalogue information. The storage system may comprise a smart device having a processor, a memory, and a transceiver, and may receive an input from a camera. The smart device may receive scans of the first scannable code and of the second scannable code, and receive the first catalogue information and the second catalogue information, respectively. The processor may associate the second catalogue information with the first catalogue information. The processor may access origin or destination data associated with the first catalogue information and/or second catalogue information. The smart device may receive images of stored items. The memory may store images and the processor may associate the images with the first catalogue information.

A reduced size optical code identifier includes a transparent body having a flat bottom surface with a rounded or domed top surface that meets the bottom surface around the perimeter of the bottom surface. An optical code is provided in the body adjacent the bottom surface and is visible through the top surface. The top surface is configured to reduce reflection to facilitate optical recognition and decoding of the optical code. The body has a maximum length or diameter of about twelve millimeters or less. The identifier can be placed on an object or structure and then used to associate information with the optical code of the identifier so that the information can be retrieved using a computing device that can optically recognize the code and communicate with a remote server.

Systems and methods of monitoring progress of delivery of a patient-specific medication are disclosed. A patient/medication identification (ID) device is provided on a package containing the medication, the patient/medication ID device comprising medication/patient information indicative of the medication and the patient. At least one location ID device is provided at a location, the at least one location ID device comprising a unique location ID associated with the location. The medication/patient information and the patient/medication ID are read. Delivery progress information indicative of a last-known read location where at least one of the medication/patient ID information and the unique location identifier was read is generated. The delivery progress information is stored in a database. The delivery progress information is accessed from the database in response to the request. A delivery status of the medication is indicated to the user.

Methods and systems include using three-dimensional imaging apparatuses to capture three-dimensional images and analyze resulting three-dimensional image data to enhance captured two-dimensional images for scanning related processes such as object identification, symbology detection, object recognition model training, and identifying improper scan attempts or other actions performed by an operator. Imaging systems such as bi-optic readers, handheld scanners, and machine vision systems are described using three-dimensional imaging apparatuses and described capturing three-dimensional images and using with captured two-dimensional images.

A method and apparatus to control optical communication between proximal devices, providing autonomous data transfer sessions that include optically-represented datagram (e.g., QR Code™) presentations, is disclosed. Optical control signals sent between a viewing device and a presenting device enable control of the presenting device without physical contact during initiation, performance, and termination of the transfer session. Advancement between datagrams is provided by control signals indicated by changes in relative orientation, changes in relative position, and gestural relative motion between the proximal devices.

A bioptic scanner optical arrangement with a single sensor split four ways is disclosed herein. An example bioptic scanner optical arrangement includes a housing, an imaging assembly having a primary FOV, a decode module, a generally horizontal window supported by the housing, a generally upright window supported by the housing, and a mirror arrangement positioned within the interior region. The mirror arrangement is configured to divide the primary FOV into a plurality of subfields, to redirect at least one of the plurality of subfields through the generally horizontal window, and to redirect at least another two of the plurality of subfields through the generally upright window. The bioptic barcode reader has no other imaging assembly communicatively coupled to the decode module and used to process images for decoding indicia.

A system includes a processing apparatus and a management server. The processing apparatus includes a first transmission unit configured to transmit information about a state of a consumable item for consumption by the processing apparatus. The management server includes a first generation unit configured to generate a first screen for purchasing the consumable item based on the information transmitted from the processing apparatus about the state of the consumable item, a second transmission unit configured to transmit a request for purchasing the consumable item based on a user instruction designated on the first screen displayed on the processing apparatus, and a second generation unit configured to generate a second screen containing a payment code based on information about the payment code acquired based on the request for purchasing.

A ground marker for use in identifying a location associated with a mission performed by an aerial vehicle includes a visible surface with aspects that are positioned at different vertical heights or elevations. The vertical variation in the aspects of the visible surface enhances a level of visibility of the ground marker within images captured by cameras provided aboard the aerial vehicle, resulting in more accurate estimations of ranges to such markers (e.g., altitudes) determined from such images. The visible surface includes one-dimensional or two-dimensional bar codes, alphanumeric characters and symbols thereon and is provided on or within rigid or flexible frames that are adapted to be placed on ground surfaces at the location associated with the mission.

A nonwoven is provided having a pattern displaying at least two groups of areas having different optical properties distinguishable to reading and decoding equipment. The pattern may be arise from differences in the microstructure of the web. The nonwoven material may have an embossed pattern having a basic, static component and a dynamic component which varies within a given length of the nonwoven web. Further, a method is provided for obtaining information from a nonwoven web, comprising observing the web surface using an optical reading device, collecting data based on differences in optical properties in the web surface, storing in a digital memory a pattern based on the collected data and comparing the stored pattern to a collection of previously stored patterns.

This disclosure describes techniques for receiving information that is wirelessly transmitted to a mobile computing system by wireless devices that are proximal to a route being travelled by the mobile computing system, and presenting at least a portion of the received information through a display of the mobile computing system. The information can be displayed according to a computing experience that is determined for a user of the mobile computing system (e.g., user-selected, inferred based on a stored schedule of the user, and so forth). Different sets of location-based information can be transmitted to the mobile computing system from different wireless devices that the mobile computing system comes into proximity with while traveling along a route. In some instances, the information can be locally stored on the wireless device(s) to reduce latency.