A method for measuring an object and a smart device are provided. The method includes: detecting by a smart device a track of a target object moving along the object to be measured; calculating a parameter of the track by the smart device according to the track; and acquiring a parameter of the object to be measured by the smart device according to the parameter of the track.

A system and method for identifying available cargo space and allocating that available cargo space while in transit includes a plurality of sensors for measuring space from reference surface of a cargo container to pallets in the cargo container. Such distances are aggregated to identify unused space in real time. The unused space is used by a freight management system to identify cargo along the same route that can use the unused space.

A system and a method are disclosed including a dual laser measurement device (DLMD) coupled with a mobile computing device to measure dimensions of a building or other structure, calculate other quantities based on the measured dimensions, select building construction or finishing material, order the material, and save the list of the measured dimensions and ordered materials in a data storage device. All steps of this process from measurement to ordering material may be performed using a DLMD app running on the mobile computing device.

An inkjet printing system with a droplet measurement apparatus is described herein. The droplet measurement apparatus has a light source with a collimating optical system, an imaging device disposed along an optical path of the collimating optical system, and a droplet illumination zone in the optical path of the collimating optical system, the droplet illumination zone having a varying droplet illumination location, wherein the light source, the imaging device, or both are adjustable to place a focal plane of the imaging device at the droplet illumination location. The droplet measurement apparatus is structured to accommodate at least a portion of a dispenser of the printing system within the droplet illumination zone.

A method includes monitoring a submerged arc welding (SAW) operation in real-time; determining, based on the monitoring and in real-time, a discrepancy between a desired weld parameter and an actual weld parameter of a weld resulting from the SAW operation; and in response to determining the discrepancy, controlling a power supply, which provides power for the SAW operation, to modify at least one of balance or offset of an alternating current (AC) welding power signal supplied for the SAW operation to compensate for the discrepancy.

A road surface area detection device, which is capable of accurately determining a road surface shape, includes: a data accumulator accumulating a ranging point sequence measured in a circumferential direction for each depression angle by a sensor; an adjacent point specifying processing circuitry extracting an attention point in one of the ranging point sequences, and adjacent points located on a large depression angle side and a small depression angle side with respect to the depression angle for the one ranging point sequence; an angle calculator calculating an angle formed by the adjacent points with respect to the attention point, as a difference angle; and a shape calculator classifying the attention point based on a shape determination result using the attention point and the adjacent points, and calculates a road surface shape based on the classification.

A system and a method are disclosed including a dual laser measurement device (DLMD) coupled with a mobile computing device to measure dimensions of a building or other structure, calculate other quantities based on the measured dimensions, select building construction or finishing material, order the material, and save the list of the measured dimensions and ordered materials in a data storage device. All steps of this process from measurement to ordering material may be performed using a DLMD app running on the mobile computing device.

Disclosed herein are an apparatus and method for measuring a volume of an object. The object volume measuring apparatus includes an area measuring unit that includes a detection sensor, which is arranged at predetermined spacing in a single row along lengthwise edges and widthwise edges of a plate respectively, where an object is placed, measures a length and a width according to the numbers of detection sensors lengthwise and widthwise respectively in which the edges are detected, and calculates an area of the object according to the measured length and width, a height measuring unit that is located above the plate and comprises a distance measuring sensor for measuring a height of the object when the object is placed, and an object calculation unit for calculating a volume of the object based on the area and the height.

Tissue sample cassettes for receiving tissue samples include an upper tray including compartments separated by dividers, a lower tray coupled to the upper tray and having a central recess, and an absorbent material located in the recess of the lower tray. Related systems and methods for automated gross processing of tissue samples are also disclosed.

A load scanning apparatus for taking physical measurements from a load. The load scanning apparatus has a scanning robot including a plurality of sensors arranged in an array spanning substantially across at least one load dimension in a first direction. The array of sensors moves together in a second direction, in a scanning plane. The plurality of sensors are configured to take images of the load from the scanning plane, and are configured to capture distance information about the distance of said load from the scanning plane.