A UID is utilized as a scale and determine basic intake information for shipping a package in order for an individual to use their UID as a intake information determining device in sending packages. Such a device is intended to be used with unmanned kiosks where the intake information would be transmitted to the shipper and the package deposited for pickup and shipping. Unmanned kiosks of this nature would provide for reduced cost and ease of drop off of packages.

Embodiments of a system and method for automating shipping for a physical object can include an object dimensions measurer (ODM) operable to collect and wirelessly transmit a dimensions dataset for the physical object, an object weight measurer (OWM) operable to collect and wirelessly transmit a weight dataset for the physical object, and a shipping automation system operable to receive datasets from the ODM and the OWM, implement a compatibility rule facilitating standardization of requirements for service levels provided by shipping carriers, determine object characteristics for the physical object, determine object characteristic specifications required by the service levels, and determine a service level for the physical object based on the object characteristics and the object characteristic specifications.

A weighing and labeling system has a scale, label printer, and at least one controller. The controller stores information about incoming food packages and drives the printer to produce labels based on the stored information and the weight of the food packages. The labels are transferred to the food packages.

Weighing system (FIG. 3, FIG. 6) to weigh items, parcels and the like, while they are moving, for example, on a conveyor. A servo amplifier (14) and servo controller (20) are arranged to drive a servo motor in a feedback (15) configuration, and acquire torque sensing signals (17) responsive to commanded acceleration of the conveyor while the item(s) are on board. Preferably, constant acceleration of the item(s) is realized during one or more measurement intervals, and mass is derived by a processor (30) based on the measurement data (FIG. 5). Other embodiments are described for weighing granular and slurry materials (FIG. 7) and for weighing multiple, potentially overlapping parcels in motion (FIG. 8).

A package dimensioning device is provided. The device may comprise a frame, a weight sensor, contactless sensors, a control unit, and a communication unit. The frame may be configured to receive a package thereon. The weight sensor may be configured to output a weight data signal that may be related to a weight of the package. The contactless sensors may comprise a plurality of contactless sensors. The plurality of contactless sensors may be configured to output a dimensional data signal that may be related to at least one of a height, length and width of the package. The control unit may be communicatively coupled to the weight sensors and the plurality of contactless sensors. The communication unit may be coupled to the control unit. The communication unit may be configured to output measurements of the package to a computer network resource.

A method and apparatus for dimensioning and, optionally, weighing an object. A platform with a surface is used for supporting an object. A user selects between two different dimensioning devices of the apparatus. The first device employs three distance sensors to determine a distance between each of the distance sensors and a side of an object. The second device includes a movable gate that is passed over and about an object or objects on the platform. Sensor arrays, such as paired, aligned light emitter and receiver arrays, are used in combination with a plurality of sensed gate positions to determine the dimensions of the objects(s) as the gate passes around the object(s) based on whether or not light from an emitter on one side of the gate reaches a light receiver on another, opposing side of the gate.

This disclosure pertains to weighing a physical item while it is moving in a servo-driven conveyor system for e-commerce, logistics, manufacturing and other applications. The introduction of an unknown mass to an electro-mechanical feedback or filter network controlling a conveyance system will modify the steady state behavior of that system in such a way that measuring the phase or frequency shift of an input signal or oscillation will enable us to infer the magnitude of that mass.

Weighing system (FIG. 3, FIG. 6) to weigh items, parcels and the like while they are moving, for example, on a conveyor. A servo amplifier (14) and servo controller (20) are arranged to drive a servo motor in a feedback (15) configuration, and acquire torque sensing signals (17) responsive to commanded acceleration of the conveyor while the item(s) are on board. Preferably, constant acceleration of the item(s) is realized during one or more measurement intervals, and mass is derived by a processor (30) based on the measurement data (FIG. 5). Other embodiments are described for weighing granular and slurry materials (FIG. 7) and for weighing multiple, potentially overlapping, parcels in motion (FIG. 8).

Methods and systems for tracking an object comprise a horizontal surface upon which objects are to be placed, a weight sensor disposed on one side of the horizontal surface, and a processor in communication with the weight sensor. The processor is adapted to detect a change in weight measured by the weight sensor, to associate the detected weight change with an identified object and with a location on the horizontal surface, and to confirm whether a cause of the weight change at the location on the horizontal surface corresponds to a proper handling of the identified object.

Methods and systems for tracking an object comprise a horizontal surface upon which objects are to be placed, a weight sensor disposed on one side of the horizontal surface, and a processor in communication with the weight sensor. The processor is adapted to detect a change in weight measured by the weight sensor, to associate the detected weight change with an identified object and with a location on the horizontal surface, and to confirm whether a cause of the weight change at the location on the horizontal surface corresponds to a proper handling of the identified object.