Abstract: A log-time stitching system provides for directly determining an accurate pixel exposure for each pixel in a recorded image. The present invention provides a digital processing system in which signals associated with a pixel are obtained at each of a plurality of different development times of the film being developed. A regression analysis that compares these different development times versus the natural log of time is made, to obtain a best fit line of this data, which line is then used to determine a “b” value. This “b” value or “fitting constant” corresponds to the intersection of the y-intercept and the best fit line. It has been discovered that this “b” value is substantially directly proportional to the log exposure of the pixel. Accordingly, this “b” value can be directly used to determine an appropriate exposure of the pixel.

Abstract: The present invention relates to material and waste transportation, in particular including an improved routine for delivery of newsprint and the removal of waste paper. There is described a material delivery and waste collection system for a premises. The system comprises (i) providing at least two, wheeled, enclosed elongate material-carrying containers each having a floor, walls, a roof and an access door at the rear of the container. The premises have a delivery bay for transfer of materials from the rear of a first container into the premises; and at least one waste collection bay. The waste collection bay includes a compactor unit having an input adapted to receive waste material and an output for expulsion of the waste material. Mutually cooperating connecting means are provided on the compactor units and on the rear of the second container; the connecting means providing a substantially rigid connection between the output of the compactor unit and the container.

Abstract: A method and system for electronic pasteurization using an electron beam is provided. The electronic pasteurization system (20) may comprise a module accelerator (22a), a module electron beam transport system (24a), and at least one treatment station (26). The module accelerator (22) produces a plurality of independent electron beams (28). The module electron beam transport system (24a) communicates the electron beams (28) to the treatment stations (26). A target (30) is irradiated with the electron beam (28) within the treatment station (26).

Abstract: Viable biological material is cryogenically preserved (cryopreservation) by preparing the material for freezing, immersing the material in a tank of cooling fluid, and circulating the cooling fluid past the material at a substantially constant predetermined velocity and temperature to freeze the material. A method according to the present invention freezes the biologic material quickly enough to avoid the formation of ice crystals within cell structures (vitrification). The temperature of the cooling fluid is preferably between −20° C. and −30° C., which is warm enough to minimize the formation of stress fractures in cell membranes due to thermal changes. Cells frozen using a method according to the present invention have been shown to have approximately an 80 percent survival rate, which is significantly higher than other cryopreservation methods.

Abstract: An armored spring-core superconducting cable (12) is provided. The armored spring-core superconducting cable (12) may include a spring-core (20), at least one superconducting strand (24) wound onto the spring-core (20), and an armored shell (22) that encases the superconducting strands (24). The spring-core (20) is generally a perforated tube that allows purge gases and cryogenic liquids to be circulated through the armored superconducting cable (12), as well as managing the internal stresses within the armored spring-core superconducting cable (12). The armored shell (22) manages the external stresses of the armored spring-core superconducting cable (12) to protect the fragile superconducting strands (24). The armored spring-core superconducting cable (12) may also include a conductive jacket (34) formed outwardly of the armored shell (22).

Abstract: Multiple widths of fluid may be extruded onto portions of material without requiring a complex reconfiguration of the system or replacing the extruding device. In at least one embodiment, various extrusion widths are provided by altering the angle at which materials are guided with respect to the extruding device along a lateral plane with the extruder. In one embodiment, the present invention provides for the manipulation of the position of the extruding device with respect to the material, or alternately, by manipulation of the position of the material with respect to the extruding device. Another embodiment provides a single extruder with multiple applicator heads of different sizes. An additional embodiment provides a single coater head with multiple applicator openings of different sizes. Yet another embodiment provides an extruding device capable of moving laterally over the material to achieve the proper angle of approach.

Abstract: The present invention provides a system for image-capturing devices, such as scanners, to accurately identify defects in objects. The objects can be the physical images to be captured or elements of the image-capturing devices such as the platen and mirrors. The image-capturing devices can then use this defect information to remove defects from captured images. The invention teaches an advantageous arrangement of illumination and sensor elements to record defect data at an angle roughly equal to the angle at which light is directed to an object, i.e. where the angle of reflection roughly equals the angle of incidence. Light reflected from surface defects has a wider diffusion and thus a lower amplitude than light reflected from the surface of the object itself. Accordingly, this characteristic can be utilized to identify defect information.

Abstract: One embodiment of a shielded cable assembly as disclosed herein includes a connector body including a wire attachment region. A contact member, including a wire attachment portion, is mounted on the connector body with the wire attachment portion positioned adjacent to the wire attachment region of the connector body. An insulating insert, including a wire-receiving region, is positioned adjacent to the connector body with at least a portion of the wire attachment region of the connector body extending into the wire-receiving region. A wire of a cable extends into the wire-receiving region of the insulating insert and is electrically connected to the wire attachment portion of the contact member. A shielding body, including an insert-receiving region, has at least a portion of the insulating insert positioned in the insert-receiving region. An insulating cover covers at least a portion of the shielding body.