Abstract: A method and apparatus are provided for performing in-situ fluid analysis. The method involves obtaining a first and second mixture of uncontaminated oil and a contaminant, wherein a percentage of the uncontaminated oil in the first mixture is different from the second mixture. The method may further include establishing a rate of change of a physical property of the first mixture and the second mixture to estimate a mass density of the uncontaminated oil and a mass density of the contaminant. In addition, the method may include obtaining a volume fraction of the uncontaminated oil for the first mixture and second mixture using the mass density of the uncontaminated oil and the mass density of the contaminant. An optical device may be used to determine a composition of the first and second mixtures in order to calculate a composition of the contaminant and a composition of the uncontaminated oil.

Abstract: Downhole imaging systems and methods are disclosed herein. An example method includes projecting flushing fluid into an optical field of view of an imaging system disposed on a downhole tool. The example method also includes directing a pattern of light onto a target in the optical field of view via a light source of the imaging system and determining three-dimensional shape information of the target based on the light directed from the target and received via an image detection plane of the imaging system. The example method further includes determining a characteristic of the target based on the three-dimensional shape information.

Abstract: An imaging-based measurement apparatus includes a light source, and at least one optical element for positioning in a flow conduit, the at least one optical element being part of a light path for light emitted by the light source, where light along the light path passes through a portion of fluid flowing in the flow conduit. An image sensor detects the light and measures content of the portion of the fluid.

Abstract: A method and apparatus are provided for performing in-situ fluid analysis. The method involves obtaining a first and second mixture of uncontaminated oil and a contaminant, wherein a percentage of the uncontaminated oil in the first mixture is different from the second mixture. The method may further include establishing a rate of change of a physical property of the first mixture and the second mixture to estimate a mass density of the uncontaminated oil and a mass density of the contaminant. In addition, the method may include obtaining a volume fraction of the uncontaminated oil for the first mixture and second mixture using the mass density of the uncontaminated oil and the mass density of the contaminant. An optical device may be used to determine a composition of the first and second mixtures in order to calculate a composition of the contaminant and a composition of the uncontaminated oil.

Abstract: Downhole imaging systems and methods are disclosed herein. An example method includes projecting flushing fluid into an optical field of view of an imaging system disposed on a downhole tool. The example method also includes directing a pattern of light onto a target in the optical field of view via a light source of the imaging system and determining three-dimensional shape information of the target based on the light directed from the target and received via an image detection plane of the imaging system. The example method further includes determining a characteristic of the target based on the three-dimensional shape information.

Abstract: An imaging-based measurement apparatus includes a light source, and at least one optical element for positioning in a flow conduit, the at least one optical element being part of a light path for light emitted by the light source, where light along the light path passes through a portion of fluid flowing in the flow conduit. An image sensor detects the light and measures content of the portion of the fluid.

Abstract: An example system for downhole measurement disclosed herein comprises a tool to be positioned downhole in a formation, the tool comprising an imaging system to determine measurement information from imaging information obtained by sensing light, and an illumination system to control source light to be emitted by the tool. The system also comprises an optical cable to sense an optical field of view that is remote from the tool, the optical cable including an optical fiber bundle comprising a bundle of imaging fibers to convey the imaging information from a sensing end of the optical cable to the imaging system, and a plurality of illumination fibers positioned outside the bundle of imaging fibers, the illumination fibers to convey the source light from the tool to the sensing end of the cable, the illumination fibers to emit the source light to illuminate the optical field of view.

Abstract: An example system for downhole measurement disclosed herein comprises a tool to be positioned downhole in a formation, the tool comprising an imaging system to determine measurement information from imaging information obtained by sensing light, and an illumination system to control source light to be emitted by the tool. The system also comprises an optical cable to sense an optical field of view that is remote from the tool, the optical cable including an optical fiber bundle comprising a bundle of imaging fibers to convey the imaging information from a sensing end of the optical cable to the imaging system, and a plurality of illumination fibers positioned outside the bundle of imaging fibers, the illumination fibers to convey the source light from the tool to the sensing end of the cable, the illumination fibers to emit the source light to illuminate the optical field of view.

Abstract: An example system described herein to perform downhole fluid analysis includes an imaging processor to be positioned downhole in a geological formation, the imaging processor including a plurality of photo detectors to sense light that has contacted a formation fluid in the geological formation, each photo detector to determine respective image data for a respective portion of an image region supported by the imaging processor, and a plurality of processing elements, each processing element being associated with a respective photo detector and to process first image data obtained from the respective photo detector and second image data obtained from at least one neighbor photo detector, and a controller to report measurement data via a telemetry communication link to a receiver to be located outside the geological formation, the measurement data being based on processed data obtained from the plurality of processing elements.

Abstract: An example system described herein to perform downhole fluid analysis includes an imaging processor to be positioned downhole in a geological formation, the imaging processor including a plurality of photo detectors to sense light that has contacted a formation fluid in the geological formation, each photo detector to determine respective image data for a respective portion of an image region supported by the imaging processor, and a plurality of processing elements, each processing element being associated with a respective photo detector and to process first image data obtained from the respective photo detector and second image data obtained from at least one neighbor photo detector, and a controller to report measurement data via a telemetry communication link to a receiver to be located outside the geological formation, the measurement data being based on processed data obtained from the plurality of processing elements.

Abstract: A method for updating a software of a sub-sea controller (31) located under the sea level. The sub-sea controller manages a plurality of tools in a sub-sea well. An application module (35) is downloaded into the sub-sea controller. The application module is executed using a virtual machine (36) implemented within the sub-sea controller.

Abstract: An acquisition and control system for use with devices installed in an underground well, comprising: an installation designer, a data server including a database of device specific and installation-specific data; an application builder; and a control and acquisition system; wherein the installation designer comprises a system for defining a hardware and software functional configuration for the devices installed in the well, the functional configuration being provided to the data server; the application builder comprises a system for obtaining software components from the data server and configuring such components to correspond to the functional configuration defined by the installation builder, the application builder outputting the configured software components to the control and acquisition system; and the control and acquisition system installs the configured software components in a data communication and processing environment connected to the devices installed in the well so as to control operation o

Abstract: A method for updating a software of a sub-sea controller (31) located under the sea level. The sub-sea controller manages a plurality of tools in a sub-sea well. An application module (35) is downloaded into the sub-sea controller. The application module is executed using a virtual machine (36) implemented within the sub-sea controller.

Abstract: A method for modeling a synthetic crystal structure formed of a first crystal structure and a second crystal structure by representing the first crystal structure using a first coordinate system and the second crystal structure using a second coordinate system, specifying a first atom, a first lattice and a first crystal face of the first crystal structure, the first crystal face including the first atom and the first lattice; specifying a second atom, a second lattice and a second crystal face of the second crystal structure the second crystal face including the second atom and the second lattice; transforming the second crystal structure system represented by the second coordinate system into a second crystal structure represented by the first coordinate system so that an assembling condition is satisfied, the assembling condition being defined as a condition in which the second atom, the second lattice and the crystal face of the second crystal structure are respectively superposed on the first atom, the f