Patents by Inventor Peter T. Wu
Peter T. Wu has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20240094233Abstract: The present invention relates to methods, devices and systems for associating consumable data with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system adjusts one or more steps of an assay protocol based on consumable data specific for that consumable. Various types of consumable data are described, as well as methods of using such data in the conduct of an assay by an assay system. The present invention also relates to consumables (e.g., kits and reagent containers), software, data deployable bundles, computer-readable media, loading carts, instruments, systems, and methods, for performing automated biological assays.Type: ApplicationFiled: July 18, 2023Publication date: March 21, 2024Inventors: Jacob N. WOHLSTADTER, Manish KOCHAR, Peter J. BOSCO, Ian D. CHAMBERLIN, Bandele JEFFREY-COKER, Eric M. JONES, Gary I. KRIVOY, Don E. KRUEGER, Aaron H. LEIMKUEHLER, Pei-Ming WU, Kim-Xuan NGUYEN, Pankaj OBEROI, Louis W. PANG, Jennifer PARKER, Victor PELLICIER, Nicholas SAMMONS, George SIGAL, Michael L. VOCK, Stanley T. SMITH, Carl C. STEVENS, Rodger D. OSBORNE, Kenneth E. PAGE, Michael T. WADE, Jon WILLOUGHBY, Lei WANG, Xinri CONG, Kin NG
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Patent number: 11092713Abstract: A method for making downhole electromagnetic logging measurements of a subterranean formation is disclosed. An electromagnetic logging tool is rotated in a subterranean wellbore. The tool includes a transmitter axially spaced apart from a receiver. The transmitter may include an axial transmitting antenna and at least one transverse transmitting antenna and the receiver may include an axial receiving antenna and at least one transverse receiving antenna. The transmitting antennas transmit corresponding electromagnetic waves into the subterranean wellbore. The receiving antennas receive corresponding voltage measurements which are processed to compute harmonic voltage coefficients. Ratios of the selected harmonic voltage coefficients are processed to compute gain compensated, azimuthally invariant measurement quantities.Type: GrantFiled: October 14, 2016Date of Patent: August 17, 2021Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Mark T. Frey
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Patent number: 10935690Abstract: A two-step inversion method for computing multi-layer subterranean formation properties includes processing gain compensated electromagnetic measurement quantities using a first inversion to compute a corresponding set of borehole corrected gain compensated measurement quantities. The first inversion includes a mathematical model of the tool and the borehole in a uniform, anisotropic formation. The set of borehole corrected gain compensated measurement quantities are then processed using a second inversion to compute multi-layer anisotropic formation properties. The second inversion includes a 1D inversion employing a point dipole model and a multi-layer formation model.Type: GrantFiled: October 14, 2016Date of Patent: March 2, 2021Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventor: Peter T. Wu
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Patent number: 10627536Abstract: A method for making gain compensated electromagnetic logging measurements of a subterranean formation includes rotating an electromagnetic logging tool in a subterranean wellbore. The logging tool includes a transmitter having at least one transmitting antenna axially spaced apart from a receiver having at least one receiving antenna. Electromagnetic waves are transmitted into the subterranean wellbore using the at least one transmitting antenna. Voltage measurements corresponding to the transmitted electromagnetic waves are received at the receiving antenna. The voltage measurements are processed to compute real and imaginary directional resistivity measurement quantities.Type: GrantFiled: October 14, 2016Date of Patent: April 21, 2020Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Helen Xiaoyan Zhong, Mark T. Frey, Peter T. Wu
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Patent number: 10508535Abstract: A method for drilling a wellbore includes drilling a well along a path substantially along a bedding direction of a selected subsurface formation having at least one substantially vertical fracture therein. A direction of the at least one substantially vertical fracture is determined with respect to a direction of the prior to drilling therethrough. A direction of the path is adjusted so that the well will intersect the at least one substantially vertical fracture substantially perpendicularly to the direction.Type: GrantFiled: October 30, 2014Date of Patent: December 17, 2019Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventor: Peter T. Wu
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Patent number: 10408965Abstract: A method for logging a formation or sample includes obtaining a plurality of multiaxial conductivity measurements from the formation or sample. A horizontal resistivity measurement, a dip measurement and a dip azimuth measurement are derived from the plurality of multiaxial conductivity measurements. A sharp vertical resistivity measurement is derived from a subset of the plurality of multiaxial conductivity measurements.Type: GrantFiled: September 9, 2012Date of Patent: September 10, 2019Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Gong Li Wang, Thomas D. Barber, Charles A. Johnson
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Patent number: 10386528Abstract: A method for making downhole electromagnetic logging measurements includes using an electromagnetic measurement tool to acquire the measurements while rotating in a subterranean wellbore. Received electromagnetic waves are processed to obtain harmonic voltage coefficients, ratios of which are in turn further processed to compute gain compensated measurement quantities. The gain compensated measurement quantities are further processed to compute at least one of an apparent formation azimuth of the formation through which the wellbore traverses, an apparent tool eccentering azimuth, and an eccentering distance of the logging tool in the wellbore.Type: GrantFiled: September 14, 2015Date of Patent: August 20, 2019Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Mark T. Frey
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Patent number: 10371851Abstract: A method for characterizing fractures traversing a wellbore includes input to a computer multiaxial electromagnetic induction measurements corresponding to measurements made along two mutually orthogonal magnetic dipole moment axes perpendicular to an axis of the wellbore. The measurements correspond to at least one receiver spacing from a transmitter. The measurements represent induced voltage in a receiver having a same dipole moment direction as a dipole moment direction of a transmitter. A first derivative with respect to wellbore depth of the multiaxial electromagnetic induction measurements is calculated. At least one peak and an amplitude thereof of the first derivatives is calculated. The peak and the amplitude are used to determine a location and an aperture of at least one fracture traversing the wellbore.Type: GrantFiled: October 20, 2015Date of Patent: August 6, 2019Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Samer Alatrach
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Patent number: 10345476Abstract: A method for identifying fractures from measurements made by a multi-axial electromagnetic induction tool in a wellbore traversing subsurface formations includes determining a value of a fracture orientation indicator from in line components of the multi-axial electromagnetic induction measurements made transverse to a tool axis, and parallel to the tool axis. The tool axis is substantially parallel to a bedding plane of the subsurface formations. A value of a vertical fracture indicator is determined using the in line components of the multi-axial electromagnetic induction measurements made transverse to the tool axis, and parallel to the tool axis.Type: GrantFiled: December 12, 2014Date of Patent: July 9, 2019Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventor: Peter T. Wu
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Publication number: 20180335543Abstract: A two-step inversion method for computing multi-layer subterranean formation properties includes processing gain compensated electromagnetic measurement quantities using a first inversion to compute a corresponding set of borehole corrected gain compensated measurement quantities. The first inversion includes a mathematical model of the tool and the borehole in a uniform, anisotropic formation. The set of borehole corrected gain compensated measurement quantities are then processed using a second inversion to compute multi-layer anisotropic formation properties. The second inversion includes a 1D inversion employing a point dipole model and a multi-layer formation model.Type: ApplicationFiled: October 14, 2016Publication date: November 22, 2018Applicant: Schlumberger Technology CorporationInventor: Peter T. Wu
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Publication number: 20180321413Abstract: A method for making gain compensated electromagnetic logging measurements of a subterranean formation includes rotating an electromagnetic logging tool in a subterranean wellbore. The logging tool includes a transmitter having at least one transmitting antenna axially spaced apart from a receiver having at least one receiving antenna. Electromagnetic waves are transmitted into the subterranean wellbore using the at least one transmitting antenna. Voltage measurements corresponding to the transmitted electromagnetic waves are received at the receiving antenna. The voltage measurements are processed to compute real and imaginary directional resistivity measurement quantities.Type: ApplicationFiled: October 14, 2016Publication date: November 8, 2018Inventors: Helen Xiaoyan Zhong, Mark T. Frey, Peter T. Wu
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Publication number: 20180321414Abstract: A method for making downhole electromagnetic logging measurements of a subterranean formation is disclosed. An electromagnetic logging tool is rotated in a subterranean wellbore. The tool includes a transmitter axially spaced apart from a receiver. The transmitter may include an axial transmitting antenna and at least one transverse transmitting antenna and the receiver may include an axial receiving antenna and at least one transverse receiving antenna. The transmitting antennas transmit corresponding electromagnetic waves into the subterranean wellbore. The receiving antennas receive corresponding voltage measurements which are processed to compute harmonic voltage coefficients. Ratios of the selected harmonic voltage coefficients are processed to compute gain compensated, azimuthally invariant measurement quantities.Type: ApplicationFiled: October 14, 2016Publication date: November 8, 2018Inventors: Peter T. Wu, Mark T. Frey
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Patent number: 9606257Abstract: A method for determining existence of a fracture in a formation surrounding a wellbore drilled through subsurface rock formations includes calculating vertical resistivity, horizontal resistivity, apparent formation dip, apparent formation azimuth and axial resistivity for a plurality of longitudinal instrument spacings using measurements from a triaxial induction well logging instrument disposed in the formation. A spread in the axial resistivity values is determined and the axial resistivity spread threshold therefrom. Fracture indicator values and fracture orientation values are calculated from transverse components of the triaxial induction measurements. Presence of a fracture is indicated when at least one of the fracture indicator value exceeds a selected threshold, the axial resistivity spread exceeds the spread threshold and when the apparent formation dip exceeds a selected threshold.Type: GrantFiled: August 25, 2011Date of Patent: March 28, 2017Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Dong Weixin, Thomas D. Barber, Dean Homan
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Publication number: 20170075024Abstract: A method for making downhole electromagnetic logging measurements includes using an electromagnetic measurement tool to acquire the measurements while rotating in a subterranean wellbore. Received electromagnetic waves are processed to obtain harmonic voltage coefficients, ratios of which are in turn further processed to compute gain compensated measurement quantities. The gain compensated measurement quantities are further processed to compute at least one of an apparent formation azimuth of the formation through which the wellbore traverses, an apparent tool eccentering azimuth, and an eccentering distance of the logging tool in the wellbore.Type: ApplicationFiled: September 14, 2015Publication date: March 16, 2017Inventors: Peter T. Wu, Mark T. Frey
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Publication number: 20160320517Abstract: A method for identifying fractures from measurements made by a multi-axial electromagnetic induction tool in a wellbore traversing subsurface formations includes determining a value of a fracture orientation indicator from in line components of the multi-axial electromagnetic inducion measurements mode transverse to a tool axis, and parallel to the tool axis. The tool axis is sub-stantially parallel to a bedding plane of the subsurface formations. A value of a vertical fracture indicator is determined using the in line components of the multi-axial electromagnetic induction measurements made transverse to the tool axis, and parallel to the tool axis.Type: ApplicationFiled: December 12, 2014Publication date: November 3, 2016Inventor: Peter T. Wu
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Patent number: 9482775Abstract: The present disclosure relates to a method to determine a formation property of a subsurface formation. A downhole logging tool having two or more tri-axial antennas is provided and used to obtain azimuthally sensitive data. Borehole correction is performed on the obtained data and a ZD-inversion is performed on the borehole corrected data for all antenna spacing groups. A formation indicator flag is determined and, depending on the determined formation indicator flag, a 1D-axial inversion and/or a 1D-radial inversion is performed over selected zones, or neither is performed. The best ZD-inversion results are selected and the 1D-axial inversion results and/or the 1D-radial inversion results, if any, are combined with the selected best ZD-inversion results to form a composite inversion result. The formation property of the subsurface formation is determined using the composite inversion result.Type: GrantFiled: January 21, 2011Date of Patent: November 1, 2016Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventors: Peter T. Wu, Thomas D. Barber
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Publication number: 20160299248Abstract: A method for characterizing fractures traversing a wellbore includes input to a computer multiaxial electromagnetic induction measurements corresponding to measurements made along two mutually orthogonal magnetic dipole moment axes perpendicular to an axis of the wellbore. The measurements correspond to at least one receiver spacing from a transmitter. The measurements represent induced voltage in a receiver having a same dipole moment direction as a dipole moment direction of a transmitter. A first derivative with respect to wellbore depth of the multiaxial electromagnetic induction measurements is calculated. At least one peak and an amplitude thereof of the first derivatives is calculated. The peak and the amplitude are used to determine a location and an aperture of at least one fracture traversing the wellbore.Type: ApplicationFiled: October 20, 2015Publication date: October 13, 2016Inventors: Peter T. Wu, Samer Alatrach
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Publication number: 20160124108Abstract: A method uses multiaxial electromagnetic measurements corresponding to measurements made along two mutually orthogonal axes perpendicular to and parallel to an axis of a wellbore corresponding to at least one receiver spacing from a transmitter. An initial orientation of a fracture with respect to the axis of the wellbore and a distance from the fracture are calculated using the multiaxial electromagnetic measurements. An initial model of subsurface formations is made using the initial orientation, distance and formation resistivity adjacent the fracture. An expected response of an electromagnetic instrument to the initial model is generated. The expected response is compared to measurements made by the electromagnetic instrument and a parameter of the initial model is adjusted. The expected response is repeated and the model adjusted until a difference between the expected response and the measurements either (i) falls below a selected threshold or (ii) exceeds a predetermined number of repetitions.Type: ApplicationFiled: October 30, 2014Publication date: May 5, 2016Inventor: Peter T. Wu
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Publication number: 20160123082Abstract: A method for drilling a wellbore includes drilling a well along a path substantially along a bedding direction of a selected subsurface formation having at least one substantially vertical fracture therein. A direction of the at least one substantially vertical fracture is determined with respect to a direction of the prior to drilling therethrough. A direction of the path is adjusted so that the well will intersect the at least one substantially vertical fracture substantially perpendicularly to the direction.Type: ApplicationFiled: October 30, 2014Publication date: May 5, 2016Inventor: Peter T. Wu
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Patent number: 9274242Abstract: A method for estimating fracture aperture from multi-axial electromagnetic induction measurements made in a wellbore includes determining a fracture indicator and a fracture orientation indicator. The value of the fracture indicator is determined from components of the measurements made transverse to the tool axis. A relationship between the value of the fracture indicator and the fracture aperture for the subsurface formation is determined by estimating the fracture indicator using a plurality of values of fracture aperture and a resistivity of drilling fluid in the wellbore over a background formation with estimated horizontal resistivity and vertical resistivity. The fracture aperture is determined using the determined fracture indicator and the determined relationship.Type: GrantFiled: March 4, 2013Date of Patent: March 1, 2016Assignee: SCHLUMBERGER TECHNOLOGY CORPORATIONInventor: Peter T. Wu