| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 356627000 | Volume | 6 |
| 20140002828 | VOLUME DIMENSIONING SYSTEM AND METHOD EMPLOYING TIME-OF-FLIGHT CAMERA | 01-02-2014 |
| 20140355008 | Spray Droplet Sizer - A spray sizer is provided that can measure the average droplet size in a spray. The spray sizer first separates a section of the spray for measurement. This section of the spray is passed through an optical droplet counter and the number of the droplets is measured while the droplets are collected after counting. The volume of the collected droplets is determined and it is divided by the total number of the droplets. This provides and average droplet diameter for the spray. | 12-04-2014 |
| 20150049347 | VOLUME DIMENSIONING SYSTEM AND METHOD EMPLOYING TIME-OF-FLIGHT CAMERA - Volume dimensioning employs techniques to reduce multipath reflection or return of illumination, and hence distortion. Volume dimensioning for any given target object includes a sequence of one or more illuminations and respective detections of returned illumination. A sequence typically includes illumination with at least one initial spatial illumination pattern and with one or more refined spatial illumination patterns. Refined spatial illumination patterns are generated based on previous illumination in order to reduce distortion. The number of refined spatial illumination patterns in a sequence may be fixed, or may vary based on results of prior illumination(s) in the sequence. Refined spatial illumination patterns may avoid illuminating background areas that contribute to distortion. Sometimes, illumination with the initial spatial illumination pattern may produce sufficiently acceptable results, and refined spatial illumination patterns in the sequence omitted. | 02-19-2015 |
| 20150092200 | Measuring Volume and Constituents of Cells - A method for determining a mean cell volume for a blood sample includes: illuminating the sample with incident light at a plurality of illumination wavelengths and obtaining a two-dimensional image of the sample at each of the plurality of illumination wavelengths; identifying a plurality of cells that appear in each of the images; for each one of the plurality of cells, determining an integrated optical density corresponding to each of the plurality of illumination wavelengths; for each one of the plurality of cells, determining a cell volume based on the integrated optical densities corresponding to each of the plurality of illumination wavelengths; and determining the mean cell volume for the blood sample from the cell volumes for each one of the plurality of cells. | 04-02-2015 |
| 20160187120 | 3D LASER MEASURING SCANNING APPARATUS - The invention discloses a 3D laser measuring scanning apparatus. The apparatus comprises: a measurement scanning body; an -axial laser beam outlet and an X-axial reception lens arranged on a side wall of the measurement scanning body, and a Y-axial laser beam outlet and a Y-axial reception lens arranged on another side wall; a Z-axial laser beam outlet and a Z-axial reception lens arranged on the bottom of the measurement scanning body, wherein a groove being open at the side wall with the X-axial laser beam outlet and at the side wall with the Y-axial laser beam outlet is formed in the bottom; a control device placed inside the measurement scanning body and for controlling the emitting of the laser beams from the laser beam outlets when receiving a measurement instruction through a measurement button on the measurement scanning body. A bar code and 2-dimensional bar code scanning laser head, a laser reception lens and a camera are also placed at the bottom of the measurement scanning body. By using this utility model, the three dimensions of a transport box can be easily measured. | 06-30-2016 |
| 20160375194 | OPTICAL IMAGING SYSTEM WITH MULTIPLE IMAGING CHANNEL OPTICAL SENSING - A method of calculating a volume of a drop pendant using a microprocessor. Included in the method are generating a gravity vector based on a direction of gravity with respect to the drop pendant; establishing a reference frame of the drop pendant for an image processing based on a reference point of the drop pendant and the gravity vector; generating a first reference line associated with the reference frame for representing an actual orientation of the drop pendant; generating a second reference line associated with the reference frame for representing a longitudinal axis of a chamber in which the drop pendant is located; comparing the first and second reference lines with respect to the gravity vector; and calculating the volume of the drop pendant based on the comparison of the first and second reference lines and the gravity vector. | 12-29-2016 |
