Abstract: A food blotting composite includes an absorbent layer and a non-absorbent layer, the absorbent layer in one embodiment having an oleophilic surface and the non-absorbent layer having an oleophobic surface. The absorbent layer is physiologically safe for food contact applications, such as removing oil and grease from pizza and other cooked foods. A pizza box assembly and a blotting method also involve the pizza-blotting composite. In one embodiment the composite is positioned beneath the pizza with the absorbent layer facing upwardly to contact the underside of the pizza in use.

Abstract: A pizza-blotting composite includes an absorbent layer and a non-absorbent layer, the absorbent layer having an oleophilic surface and the non-absorbent layer having an oleophobic surface. The absorbent layer is low-linting and physiologically safe for food contact applications, such as removing oil from pizza. The absorbent layer and the non-absorbent layer are joined to form a composite, which is dimensioned to cover a substantial portion of a pizza's surface. A pizza box assembly is also provided with the pizza-blotting composite, in which the non-absorbent layer of the composite is secured to the interior of the top of the pizza box.

Abstract: A method and system for transportation using a magnetic bearing structure is disclosed. In one aspect, there is an apparatus for carrying a load along a magnetizable structure. In one embodiment, the apparatus comprises a third structure spaced apart vertically from the magnetizable structure and configured to generate magnetic flux and repel from the magnetizable structure. In one embodiment, the apparatus comprises at least one coil positioned at at least one end portion proximal to the magnetizable structure. In one embodiment, the apparatus comprises at least one flux guide comprising a magnetizable material and configured to concentrate magnetic flux. A first portion of the flux guide is thinner than a second portion of the flux guide that is positioned closer to the magnetizable structure than the first portion of the flux guide.

Abstract: A mechanism for manipulation of a substrate over a substantially planar region has at least three, and up to six, degrees of freedom (DOF). The mechanism may be manufactured in various configurations, including triangular, and may use inherent symmetry to reduce the number of distinct components that must be manufactured. The mechanism may use parallelism to reduce the moving mass and thereby achieve higher levels of performance using less expensive motors while dissipating less power.

Abstract: A method is presented for converting the sine/cosine signals from an optical encoder into a high-resolution position signal for use by a position control system while eliminating common noise and error sources. The improved noise performance resulting from the alias-free demodulation of encoder signals improves precision and reduces power consumption in precision motion control applications. The adaptive compensation of harmonic distortion eliminates errors related to offset, gain and quadrature of the encoder channels. The interpolator is able to process encoder signals at extremely high resolution without the speed limitation of prior art encoder interpolators.

Abstract: A mechanism for manipulation of a substrate over a substantially planar region has at least three, and up to six, degrees of freedom (DOF). The mechanism may be manufactured in various configurations, including triangular, and may use inherent symmetry to reduce the number of distinct components that must be manufactured. The mechanism may use parallelism to reduce the moving mass and thereby achieve higher levels of performance using less expensive motors while dissipating less power.

Abstract: A reflective metrological scale has a scale pattern of elongated side-by-side marks surrounded by reflective surface areas of a substrate, which may be a nickel-based metal alloy such as Invar® or Inconel® and may be a thin and elongated flexible tape. Each mark has a furrowed cross section and may have a depth in the range of 0.5 to 2 microns. The central region of each mark may be rippled or ridged and may be darkened to provide an enhanced optical reflection ratio with respect to surrounding reflective surface areas. A manufacturing method includes the repeated steps of (1) creating a scale mark by irradiating a surface of the substrate at a mark location with a series of overlapped pulses from a laser, each pulse having an energy density of less than about 1 joule per cm2, and (2) changing the relative position of the laser and the substrate by a displacement amount defining a next mark location on the substrate at which a next mark of the scale is to be created.

Abstract: A high-speed method and system for precisely positioning a waist of a material-processing laser beam to dynamically compensate for local variations in height of microstructures located on a plurality of objects spaced apart within a laser-processing site are provided. In the preferred embodiment, the microstructures are a plurality of conductive lines formed on a plurality of memory dice of a semiconductor wafer. The system includes a focusing lens subsystem for focusing a laser beam along an optical axis substantially orthogonal to a plane, an x-y stage for moving the wafer in the plane, and a first air bearing sled for moving the focusing lens subsystem along the optical axis.

Abstract: A high-speed method and system for precisely positioning a waist of a material-processing laser beam to dynamically compensate for local variations in height of microstructures located on a plurality of objects spaced apart within a laser-processing site are provided. In the preferred embodiment, the microstructures are a plurality of conductive lines formed on a plurality of memory dice of a semiconductor wafer. The system includes a focusing lens subsystem for focusing a laser beam along an optical axis substantially orthogonal to a plane, an x-y stage for moving the wafer in the plane, and a first air bearing sled for moving the focusing lens subsystem along the optical axis.

Abstract: A method and apparatus for examining internal components of a sealed container is disclosed. In one embodiment, the method includes the steps of attaching an acoustic sensor to an outer surface of the sealed container and moving the sealed container about at least one axis of the sealed container. An audio signal is received from the acoustic sensor, where the audio signal is generated by a component within the sealed container that is put into motion as a result of the step of moving the sealed container about the at least one axis. The audio signal is analyzed to determine the frequency of the signal. In an embodiment for an apparatus of the present invention, an acoustic sensor is attached to the sealed container. An amplifier is coupled to the acoustic sensor and receives an audio signal from the acoustic sensor. The audio signal is generated by a component within the sealed container that is put into motion as a result of movement of the sealed container.