A method for manufacturing a filter medium includes providing a computer-readable three-dimensional model of the filter medium including a plurality of segments, each segment of the three-dimensional model being configured to be converted into a plurality of slices that each define a cross-sectional layer of the filter medium, each segment including an undulating layer extending along a predetermined direction that is different than the predetermined direction of the undulating layer of the other segment; and successively forming each layer of the filter medium by additive manufacturing.

A system includes a plurality of tooth models each including computer code controlling its movement. The system also includes a tooth movement control system (TMCS) with a processor executing a dental manager module and with memory scoring a different tooth movement plan for each of the tooth models. In practice, the tooth movement plans are stored in the memory of each of the tooth models (e.g., a different tooth movement plan for each tooth model). Then, during tooth movement operation, each of the local control modules independently controls the tooth model to execute the tooth movement plan stored in the memory of the tooth model.

A system includes a plurality of tooth models each including computer code controlling its movement. The system also includes a tooth movement control system (TMCS) with a processor executing a dental manager module and with memory scoring a different tooth movement plan for each of the tooth models. In practice, the tooth movement plans are stored in the memory of each of the tooth models (e.g., a different tooth movement plan for each tooth model). Then, during tooth movement operation, each of the local control modules independently controls the tooth model to execute the tooth movement plan stored in the memory of the tooth model.

A system and method are disclosed for interactive product assortment planning and visualization by receiving product attribute values for items of a product assortment is disclosed. Embodiments include displaying icons on an interactive visualization, connecting the icons with transferable demand links, identifying items to be removed from a product assortment, and transporting items among one or more supply chain entities.

A system and method are disclosed for interactive product assortment planning and visualization by receiving product attribute values for items of a product assortment is disclosed. Embodiments include displaying icons on an interactive visualization, connecting the icons with transferable demand links, identifying items to be removed from a product assortment, and transporting items among one or more supply chain entities.

An inspection system for in situ evaluation of an additive manufacturing (AM) build part is provided. The inspection system comprises a build plane induction coil sensor configured and positionable so that during construction of the build part, the sensor's magnetization and sensor coils surround at least the last-produced layer of the AM build part in the build plane. The inspection system further comprises an energization circuit and a central processing system. The central processing system comprises a communication processor configured for sending command signals to the energization circuit and receiving impedance data from the build plane induction coil sensor, and energization controller configured for determining energization commands for transmission to the energization circuit, and an induction data analyzer configured for processing build part impedance data using complex impedance plane analysis and for identifying anomalies in the AM build part.

An inspection system for in situ evaluation of an additive manufacturing (AM) build part is provided. The inspection system comprises a build plane induction coil sensor configured and positionable so that during construction of the build part, the sensor's magnetization and sensor coils surround at least the last-produced layer of the AM build part in the build plane. The inspection system further comprises an energization circuit and a central processing system. The central processing system comprises a communication processor configured for sending command signals to the energization circuit and receiving impedance data from the build plane induction coil sensor, and energization controller configured for determining energization commands for transmission to the energization circuit, and an induction data analyzer configured for processing build part impedance data using complex impedance plane analysis and for identifying anomalies in the AM build part.

A system design support apparatus generates new user data on the basis of derived user data including: base user data reference information that is information specifying user data to be referred to; and information on an item changed from the user data specified by the base user data reference information and on changed contents. A system design support method includes a step of selecting user data to be used, a step of generating derived user data including: base user data reference information for specifying the selected user data to be used; and information on an item changed from the user data specified by the base user data reference information and on changed contents, and a step of generating new user data on the basis of the derived user data.

A system design support apparatus generates new user data on the basis of derived user data including: base user data reference information that is information specifying user data to be referred to; and information on an item changed from the user data specified by the base user data reference information and on changed contents. A system design support method includes a step of selecting user data to be used, a step of generating derived user data including: base user data reference information for specifying the selected user data to be used; and information on an item changed from the user data specified by the base user data reference information and on changed contents, and a step of generating new user data on the basis of the derived user data.

The device, system and process of the present invention greatly reduces the time and space necessary to assemble a wire harness enables efficient manufacture of wire harnesses. The present invention comprises at least a wire viewer module, a machine vision and optical character recognition module, a cassette tray platform, designed to receive and hold in place a cassette tray, having one or more receptacles designed to receive and hold in place a wire harness connector, having multiple pin-hole cavities illuminated from below or behind by a light source mounted on a two-axis translation stage or gantry to identify a cavity for wire insertion. Moreover, the present invention may further comprise a portable, computer-implemented system capable of executing a series of automated process steps designed to identify wire markings and guide the error-free insertion of identified wires into wire harness connector pin-hole receptacles for assembly of a wire harness.