A system including a multi-dimensional scanner includes a body including a chassis extending from the body, a connector assembly coupled to the chassis, and a plurality of interchangeable attachments. Each of the plurality of interchangeable attachments is securable to the body via the connector assembly and each of the plurality of interchangeable attachments is associated with a type of operation of the system.

A non-contact charging cart station includes a housing and a plurality of non-contact charging devices. The housing has a cart placement region on which stackable carts or the like can be inserted along a cart placement direction. The plurality of non-contact charging devices are in the housing and aligned in the cart placement region along the cart placement direction.

A method for manually reading a code marked on an article having a first main face on a first side and a second main face, opposite the first main face, on a second side, wherein, with the article being fixed, a portable device equipped with an optical imaging system including at least one optical sensor is positioned on the first side of the article so as to place the optical sensor facing the code in a reading direction corresponding to the observation direction of the imaging system, and wherein, with the code being illuminated by a light source located on the second side of the article, at least one image of the code is acquired by the optical imaging system.

Systems and methods for improving the efficiency of order fulfillment are disclosed. When fulfilling an order in which substitutions are required, due to unavailability of particular products, the process of contacting the customer and receiving a selection from the customer can be separated from the picking process. The picker can continue to fulfill the order, while an automated system offers alternatives and receives selections from the customer. If appropriate, the substitution can be appended to the picker's list. If the picker has completed the remainder of the order, on the other hand, a new order with the substitution can be created, which can later be aggregated with the original order. A variety of methods can be used to efficiently present substitutions to the customer and receive choices from the customer, including use of imagery of substitute items.

A barcode scanner assembly for capturing at least one object appearing in a field of view (FOV) is provided that includes a base defining a curved base surface and a scanner enclosure being mechanically coupled to the base. The scanner enclosure includes a top portion and a bottom portion opposite the top portion. The bottom portion of the scanner enclosure is positioned proximate to the base. The bottom portion of the scanner enclosure includes a curved scanner enclosure surface. The curved base surface and the curved scanner enclosure surface are nested such that a clearance of less than approximately 5 mm is formed between the curved base surface and the curved scanner enclosure surface.

An interrogation device and/or system includes a body and an antenna, the body has an aperture or elongated receiver with an opening and an internal perimeter or inner wall sized and/or shaped to receive a portion of a container therein, either with or without a cap of the container. The container may, for example, be used to store biological specimens a cryogenic temperatures. One or more alignment features of the body align wireless transponders (e.g., RFID transponders) of tagged specimen containers and/or carriers with the antenna to enhance interrogation. Alignment may be along a longitudinal or Z-axis, and/or alignment in an XY plane, perpendicular to the Z-axis. Shielding may reduce or even eliminate cross-talk with neighboring wireless tagged specimen containers and/or carriers.

A multifunctional handheld scanner includes a scanner main body (100) and a volume measuring module (200). The scanner main body (100) has a work surface (101) and a barcode capturing unit (102) exposed on the work surface (102). The volume measuring module (200) is disposed on the work surface (101) and has: photographic lenses (201a, 201b), an optical distance measuring unit (300) and an optical projection unit (400). The photographic lenses (201a, 201b) define a measuring zone (204). The optical distance measuring unit (300) is disposed corresponding to the measuring zone (204). The optical projection unit (400) projects an aiming indication cursor (410) toward a projection zone (401), wherein the projection zone (401) is located within the measuring zone (204).

A non-contact charging cart station includes a housing and a plurality of non-contact charging devices. The housing has a cart placement region on which stackable carts or the like can be inserted along a cart placement direction. The plurality of non-contact charging devices are in the housing and aligned in the cart placement region along the cart placement direction.

A handheld barcode reader includes a reader enclosure constructed from a dielectric material and a screen engaging member operatively coupled with the reader enclosure. The reader enclosure includes a nose portion and a handle portion coupled with the nose portion and is adapted to accommodate a user's hand. The screen engaging member is constructed from a conductive material and includes an extension member coupled with the nose portion of the reader enclosure and at least one arm member extending from the nose portion of the reader enclosure to the handle portion of the reader enclosure.

A data capture device includes a housing supporting a window at a scan opening, a data capture module with a scanner field of view directed through the scan window, a heater controllable to heat the window, a non-contact temperature sensor with a sensor field of view directed at the scan window, an auxiliary temperature sensor, a humidity sensor, and a controller. The controller is configured to receive (i) a window temperature from the non-contact temperature sensor, (ii) an external ambient temperature from the auxiliary temperature sensor, and (iii) an external ambient humidity from the humidity sensor. The controller then determines a dew point according to the ambient temperature and the ambient humidity, and selects a power level for the heater based on a comparison of the window temperature and the dew point.