Abstract: A system for providing interoperability of electronic games independently-operable from one another includes a network entity and a client. The client can interact with the network entity to play a master electronic game using shared attributes otherwise configured for use in a subordinate electronic game, where the client can interpret the respective shared attributes for use during play of the master electronic game. During play of the master electronic game, the client can receive a selection of at least one subordinate game from within the master electronic game. In response, the client can initiate the selected subordinate game for play using shared attributes otherwise configured for use in the master electronic game and/or another subordinate electronic game. Similarly, the client can interpret the respective shared attributes for use during play of the selected subordinate game.

Abstract: The invention provides an apparatus and method for detecting flaws in an object. The method includes the step of heating a portion of a surface of an object wherein the surface is defined by a plurality of individual surface elements. The method also includes the step of recording a plurality of thermal images of the portion over time with a thermal imaging device. Each of the plurality of thermal images is defined by a plurality of pixels. Each of the plurality of pixels has an individual pixel address and corresponds to one of the plurality of individual surface elements. The method also includes the step of determining a pixel intensity for each of the plurality pixels in each of the plurality of thermal images. The method also includes the step of integrating the pixel intensity of each of the plurality of pixels having the same individual address from respective thermal images to establish elements within an array of integrated pixel intensity.

Abstract: The thickness of a workpart (10) is measured to a high degree of accuracy by passing a coherent light beam (20) through an aperture (16) in the workpart (10). The aperture (16?) can alternatively be created between an edge of the workpart (10) and an external reference plate (30). The light is diffracted on the far side of the workpart (10) and its diffraction pattern captured by a CCD camera (22). The captured image is analyzed by a computer (24) which compares the captured diffraction pattern to a stored referenced value to determine whether the thickness of the workpart (10) is within an acceptable range. The method is capable of returning measurements with micron or submicron resolution, and is a robust process readily adaptable to high volume production quality control applications.

Abstract: A system for providing interoperability of electronic games independently-operable from one another includes a network entity and a client. The client can interact with the network entity to play a master electronic game using shared attributes otherwise configured for use in a subordinate electronic game, where the client can interpret the respective shared attributes for use during play of the master electronic game. During play of the master electronic game, the client can receive a selection of at least one subordinate game from within the master electronic game. In response, the client can initiate the selected subordinate game for play using shared attributes otherwise configured for use in the master electronic game and/or another subordinate electronic game. Similarly, the client can interpret the respective shared attributes for use during play of the selected subordinate game.

Abstract: The invention provides an apparatus and method for detecting flaws in an object. The method includes the step of heating a portion of a surface of an object wherein the surface is defined by a plurality of individual surface elements. The method also includes the step of recording a plurality of thermal images of the portion over time with a thermal imaging device. Each of the plurality of thermal images is defined by a plurality of pixels. Each of the plurality of pixels has an individual pixel address and corresponds to one of the plurality of individual surface elements. The method also includes the step of determining a pixel intensity for each of the plurality pixels in each of the plurality of thermal images. The method also includes the step of integrating the pixel intensity of each of the plurality of pixels having the same individual address from respective thermal images to establish elements within an array of integrated pixel intensity.

Abstract: The thickness of a workpart (10) is measured to a high degree of accuracy by passing a coherent light beam (20) through an aperture (16) in the workpart (10). The aperture (16?) can alternatively be created between an edge of the workpart (10) and an external reference plate (30). The light is diffracted on the far side of the workpart (10) and its diffraction pattern captured by a CCD camera (22). The captured image is analyzed by a computer (24) which compares the captured diffraction pattern to a stored referenced value to determine whether the thickness of the workpart (10) is within an acceptable range. The method is capable of returning measurements with micron or submicron resolution, and is a robust process readily adaptable to high volume production quality control applications.