Abstract: An apparatus and method for inspecting a container having a base and a mouth, wherein light is directed through the container base into the container, and out of the container through the container mouth, using at least first and second light sources operatively disposed adjacent to each other beneath the container base and having differing operating characteristics. Light transmitted through the container mouth is sensed, and a composite image of the container mouth may be produced from two or more images of portions of the container mouth.

Abstract: A method of and apparatus for inspecting a container having a base and a mouth. Light is directed through the container base into the container, and out of the container through the container mouth, using at least one light source disposed beneath the container base. A plurality of images of the container mouth is obtained from the light transmitted through the container mouth. Minimum bore diameters of the container mouth are calculated from the plurality of images, and an overall lowest minimum bore diameter (OLMBD) of the minimum bore diameters is identified. A value other than the OLMBD is determined to be an effective minimum bore diameter of the container mouth.

Abstract: A method of and apparatus for inspecting a container having a base and a mouth. Light is directed through the container base into the container, and out of the container through the container mouth, using at least one light source disposed beneath the container base. A plurality of images of the container mouth is obtained from the light transmitted through the container mouth. Minimum bore diameters of the container mouth are calculated from the plurality of images, and an overall lowest minimum bore diameter (OLMBD) of the minimum bore diameters is identified. A value other than the OLMBD is determined to be an effective minimum bore diameter of the container mouth.

Abstract: An apparatus and method for inspecting a container having a base and a mouth, wherein light is directed through the container base into the container, and out of the container through the container mouth, using at least first and second light sources operatively disposed adjacent to each other beneath the container base and having differing operating characteristics. Light transmitted through the container mouth is sensed, and a composite image of the container mouth may be produced from two or more images of portions of the container mouth.

Abstract: A glassware inspection apparatus that includes an electronic control system and method for optimum control of indexing and inspecting glass containers. The control system generally includes a driver circuit for each servo motor of the apparatus, an electronic control unit, and an operator interface. Information about the apparatus and the particular containers being inspected is entered into the control system through the operator interface. The electronic control unit executes a recursive algorithm that utilizes the inputted information, as well as predetermined constraints of the apparatus, to develop an optimum motion profile for each servo motor. The optimum motion profiles provide the overall apparatus with coordinated control and increased container throughput speed, while efficiently distributing cycle time and thermal energy between the various servo motors.

Abstract: An apparatus for inspecting articles of glassware at a plurality of angularly spaced inspection stations includes a conveyor that moves articles of glassware to and from inspection stations, a drive roller that rotates articles of glassware at at least one inspection station, and an inspection device spaced from an inspection station and adapted to inspect an article of glassware as it is moved by the conveyor and caused to pass by the inspection device.

Abstract: An exemplary operation for maintaining an imaging device includes obtaining an identification of the imaging device connected to a kiosk, testing the imaging device at the kiosk with at least one test that is selected for the imaging device based on the identification, and transmitting information about the imaging device from the kiosk to at least one remote server.

Abstract: A color management module which accepts input color image data and transforms the input color image data into output color image data based on information contained in at least one color profile, wherein the color management module includes an interface to an externally provided, pluggable gamut mapping module which is accessed by the color management module to map the input color image data from an input color gamut into an output color gamut.

Abstract: An application programming interface (API) that provides a common interface between an application program and plural different types of color measuring devices each having at least one color measuring sensor. The API includes plural functions for operating any of the plural different types of color measuring devices. In order to complete an operation performed by at least one of the plural functions, the function that performs the operation must be called a number of times which is different for at least two different types of color measuring devices. For a particular color measuring device, the API provides the application program with flow control data of the number of times that the function must be called. This flow control data preferably can be provided by the function, in the form of a call-again value or as a numerical value, or by a separate function in the API such as a get-device-capabilities function.

Abstract: Imaging device analysis systems and imaging device analysis methods are described. According to one embodiment, an imaging device analysis system includes a light source configured to output light for use in analyzing at least one imaging component of an imaging device, wherein the imaging device is configured to generate images responsive to received light, and processing circuitry coupled with the light source and configured to control the light source to optically communicate the light to the imaging device, wherein the processing circuitry is further configured to access image data generated by the imaging device responsive to the reception, by the imaging device, of the light from the light source and to process the image data to analyze an operational status of the at least one imaging component.

Abstract: In a method for fabricating a nanowire thermoelectric device, a first electrode pattern is formed on a substrate, wherein the first electrode pattern includes bottom electrodes and a first set of connections which connects the bottom electrodes to form first and second groups of electrically connected bottom electrodes. P-type nanowires and n-type nanowires are selectively formed on the substrate by selectively activating either the first group of electrically connected bottom electrodes and the second group. The p-type and n-type nanowires are then connected by top electrodes. A first set of holes in the substrate is formed to remove the first set of connections. A second set of holes to allow for electrical access to the bottom electrodes, and a second set of connections are formed, so as to result in an array of thermocouples connected to each other in parallel banks of series-connected thermocouples.

Abstract: The present invention concerns a method for fabricating a nanowire thermoelectric device comprising the step of providing a substrate upon which to form nanowires. The substrate comprises substrate electrodes passing from a top exposed surface of the substrate to a bottom exposed surface of the substrate. Another step involves forming a first electrode pattern, which forms first and second electrically connected groups of substrate electrodes, on the bottom surface of the substrate. A p-type nanowire is then formed on the substrate by activating the first group of substrate electrodes during p-type material deposition. Similarly, a n-type nanowire is formed by activating the second group of substrate electrodes during n-type material deposition. And top electrodes are formed to connect the p-type and the n-type nanowires and a second electrode pattern is formed on the bottom side of the substrate to replace the first electrode pattern to form a thermocouple.

Abstract: To generate a color palette having m colors (such as 28=256 colors) from a color image described in a color space, pixel image data corresponding to the color image is first obtained. A frequency of occurrence for each color in the pixel image data is then determined. Each color in the pixel image data is assigned to one of a predetermined number of cells into which the color space has been partitioned, the predetermined number being not greater than m. The most commonly occurring color is selected in each cell in which a color exists, so as to obtain n palette colors. A vote value is calculated for each unselected color, the vote value being based at least in part on the frequency of occurrence of the color in the pixel image and a weighting factor based on a rank of the color in its corresponding cell, the unselected colors being the colors not selected in the first selecting step. Thereafter, m-n colors are selected as the unselected colors with the highest vote values.

Abstract: Apparatus for inspecting the bottom of a container that includes a light sensor positioned to view the container bottom through the open container mouth, a light source positioned externally of the container on the opposite side of the container bottom, and electronics for detecting commercial variations in the container bottom as a function of light energy incident on the sensor. The light source, as viewed by the sensor through the container bottom, is characterized by being elongated radially of the container bottom and narrow transversely of the container bottom. In this way, any variations in the container bottom that refract the line of sight of the sensor in the radial direction, such as mold code rings and baffle scars, are essentially transparent as viewed by the sensor.