A parallel computer that includes a plurality of nodes assigns to each of the nodes a partial region that is a division of a region in which a plurality of types of particles are distributed, and executes a plurality of programs for a particle simulation by each of the nodes. Then, according to a type of a processing-target particle of each of the plurality of programs and an execution time of each of the plurality of programs, the parallel computer determines a computation cost for each of a plurality of processing-target particles of each of the plurality of types. Subsequently, the parallel computer changes a position of a region boundary of the partial region according to the computation cost and the number of the processing-target particles of each of the plurality of types.

A computer-implemented method for simulating blood flow through one or more coronary blood vessels may first involve receiving patient-specific data, including imaging data related to one or more coronary blood vessels, and at least one clinically measured flow parameter. Next, the method may involve generating a digital model of the one or more coronary blood vessels, based at least partially on the imaging data, discretizing the model, applying boundary conditions to a portion of the digital model that contains the one or more coronary blood vessels, and initializing and solving mathematical equations of blood flow through the model to generate computerized flow parameters. Finally, the method may involve comparing the computerized flow parameters with the at least one clinically measured flow parameter.

A method to model a complex system of pipes. The model takes into account the physical processes in a tree-type piping system and provides for an accurate modeling of a real world tree-type piping system. In a preferred embodiment, a computer program is provided for analyzing models of dry pipe systems. The computer program includes a user interface and a computational engine. The user interface allows a model of a dry pipe system to be defined and the computational engine determines a liquid flow time through the model of the dry pipe system. The computational engine provides a verification of the liquid flow time in a model of a referential dry pipe system within 20% of an actual liquid flow time in the referential dry pipe system.

A method to model a complex system of pipes. The model takes into account the physical processes in a tree-type piping system and provides for an accurate modeling of a real world tree-type piping system. In a preferred embodiment, a computer program is provided for analyzing models of dry pipe systems. The computer program includes a user interface and a computational engine. The user interface allows a model of a dry pipe system to be defined and the computational engine determines a liquid flow time through the model of the dry pipe system. The computational engine provides a verification of the liquid flow time in a model of a referential dry pipe system within 20% of an actual liquid flow time in the referential dry pipe system.

The disclosed embodiments include a method, apparatus, and computer program product for generating hybrid computational meshes around complex and discrete fractures for the purpose of reservoir simulation. For example, one disclosed embodiment includes a method that comprises receiving a set of 3D fracture surfaces with geometry that has been discretized in a 2D manifold by a collection of polygons. The method defines a family of non-intersecting 2D slicing surfaces for slicing the set of 3D fracture surfaces. The method then uses the intersection of the 2D slicing surface with the 2D manifolds defining the fracture surfaces to create a set of 2D fractures on each slicing surface. Following a series of steps, the method generates three-dimensional shells connecting a set of stadia corresponding to each fracture on each 2D slicing surface to a corresponding set of stadia on a neighboring 2D slicing surface for creating a three-dimensional model.

A method of designing a microwave filter using a computerized filter optimizer, comprises generating a filter circuit design in process (DIP) comprising a plurality of circuit elements having a plurality of resonant elements and one or more non-resonant elements, optimizing the DIP by inputting the DIP into the computerized filter optimizer, determining that one of the plurality of circuit elements in the DIP is insignificant, removing the one insignificant circuit element from the DIP, deriving a final filter circuit design from the DIP, and manufacturing the microwave filter based on the final filter circuit design.

Techniques that facilitate hybrid modeling for a device under test associated with a cooling system (e.g., a two-phase cooling system) are provided. In one example, information indicative of a first model of a device under test associated with a cooling system is determined. Second information indicative of constraints that define values for an operational quantity related to the cooling system is also determined. Information indicative of a second model for the device under test is generated based on the information indicative of the first model and the second information indicative of the one or more constraints. In an aspect, a first simulation process is performed to determine first thermal properties for a first simulation domain associated with the device under test. In another aspect, a second simulation process is performed to determine second thermal properties for a second simulation domain associated with the device under test.

A method for performing light shaping with aid of an adaptive projector and associated apparatus are provided. The method includes: utilizing an image processing circuit to obtain distance information; utilizing the image processing circuit to determine a distance range according to the distance information; utilizing the image processing circuit to perform projection light-shaping type selection to determine at least one selected projection light-shaping type corresponding to the distance range among multiple predetermined projection light-shaping types; utilizing the adaptive projector to perform projection of the at least one selected projection light-shaping type to perform spatial exposure bracketing, for capturing at least one corresponding image with a camera, to allow the image processing circuit to perform at least one detection operation according to the at least one corresponding image to generate at least one detection result, for performing subsequent processing of the hybrid depth detection device.

A method for performing light shaping with aid of an adaptive projector and associated apparatus are provided. The method includes: utilizing an image processing circuit to obtain distance information; utilizing the image processing circuit to determine a distance range according to the distance information; utilizing the image processing circuit to perform projection light-shaping type selection to determine at least one selected projection light-shaping type corresponding to the distance range among multiple predetermined projection light-shaping types; utilizing the adaptive projector to perform projection of the at least one selected projection light-shaping type to perform spatial exposure bracketing, for capturing at least one corresponding image with a camera, to allow the image processing circuit to perform at least one detection operation according to the at least one corresponding image to generate at least one detection result, for performing subsequent processing of the hybrid depth detection device.

A method of designing a microwave filter using a computerized filter optimizer, comprises generating a filter circuit design in process (DIP) comprising a plurality of circuit elements having a plurality of resonant elements and one or more non-resonant elements, optimizing the DIP by inputting the DIP into the computerized filter optimizer, determining that one of the plurality of circuit elements in the DIP is insignificant, removing the one insignificant circuit element from the DIP, deriving a final filter circuit design from the DIP, and manufacturing the microwave filter based on the final filter circuit design.