Abstract: A ranging workflow to interpret the ultradeep harmonic anisotropic attenuation (UHAA) measurements and estimate the distance and orientation of the existing cased well from the well being drilled is presented herein. The ranging workflow applies to scenarios in which the wells are near parallel to each other and performs reasonably well in boreholes which are more or less perpendicular to the formation layers. The ranging workflow generally includes deploying a deep directional resistivity (DDR) tool into a new wellbore; collecting UHAA data via the DDR tool; determining resistivity values based at least in part on the UHAA data; and determining a distance of the DDR tool from a casing of an existing wellbore proximate the new wellbore based at least in part on the resistivity values and a UHAA response table for the DDR tool.

Abstract: An internal combustion engine and method for simultaneously regulating the exhaust gas temperature and the charge pressure of an internal combustion engine. An internal combustion engine that includes: an exhaust gas turbocharger (17) including a turbine (19) that is situated in an exhaust duct (8), and including a compressor (18) that is situated in an intake duct (4); a bypass valve (13) via which at least a portion of an exhaust gas mass flow of the internal combustion engine may be led past the turbine (19); and an exhaust gas flap (15) that is situated in the exhaust duct (8), downstream from the turbine (19) and the bypass valve (13).

Abstract: Disclosed is a storage management system comprising: sending, by a user device manager running at a user space of an operating system, a first request for partition table data to a block device; receiving, by the user device manager, first partition data of the block device; sending, by the user device manager, a second request for partition data of the block device to a kernel of the operating system; receiving, by the user device manager, second partition data from the kernel, wherein the second partition data is associated with the block device and cached by the kernel; determining whether the first partition data and the second partition data are identical; and in response to determining that the first partition data is different from the second partition data, performing a device discovery operation on the block device.

Abstract: A first node of a plurality of nodes is determined based on a node UID that is included in a physical extent (PE) universally unique identifier (UUID). Each of the plurality of nodes includes one or more groups of arrays. A local disk manager (LDM) that is associated with the first node is identified based on an LDM UID that is included in the PE UUID. The LDM manages a physical disk that includes a plurality of physical extents. A disk object is obtained based on a disk UID that is included in the PE UUID. The disk object is used to access a physical extent (PE) of the physical disk, using a PE offset that is included in the PE UUID. Other embodiments are described and claimed.

Abstract: A method, apparatus, and system for processing Redundant Array of Independent Disks (RAID) Input/Output (I/O) requests for a plurality of nodes in a cluster is disclosed. A file system request including a byte offset is received. Then, a Physical Extent (PE) row that matches the file system request and a RAID stripe within the identified PE row based on the byte offset is identified. Next, a plurality of RAID I/O requests to be routed to a physical disk is generated. Each of the plurality of the RAID I/O requests includes information associated with the PE and a type of operation. Thereafter, each of the RAID I/O requests is processed based on the information associated with the PE and the type of operation.

Abstract: A method of reassembling a local disk manager (LDM) and array group (AGRP) includes starting a physical extent manager (PEM) configured to run on a number of nodes. The PEM on each node is configured to manage an AGRP running on the same node. A number of LDMs are reassembled, and each LDM is configured to manage virtual disks on each of the nodes. Once enough LDMs are reassembled, an AGRP can be reassembled.

Abstract: A method of managing extents of a file system having a protection pool includes collecting and initializing physical extent manager (PEM) metadata, using a PEM daemon thread. The PEM is configured to run on each of a number of nodes. The method also includes creating a request queue, using the PEM daemon thread, for all requests submitted to the PEM. The method also includes scanning the request queue, using a PEM worker thread, to handle incoming requests submitted to the PEM. The method also includes listening for multicast messages, using a PEM multicast listener thread, to be handled by the PEM worker thread.

Abstract: A first node of a plurality of nodes is determined based on a node UID that is included in a physical extent (PE) universally unique identifier (UUID). Each of the plurality of nodes includes one or more groups of arrays. A local disk manager (LDM) that is associated with the first node is identified based on an LDM UID that is included in the PE UUID. The LDM manages a physical disk that includes a plurality of physical extents. A disk object is obtained based on a disk UID that is included in the PE UUID. The disk object is used to access a physical extent (PE) of the physical disk, using a PE offset that is included in the PE UUID. Other embodiments are described and claimed.

Abstract: A method of managing extents of a file system having a protection pool includes collecting and initializing physical extent manager (PEM) metadata, using a PEM daemon thread. The PEM is configured to run on each of a number of nodes. The method also includes creating a request queue, using the PEM daemon thread, for all requests submitted to the PEM. The method also includes scanning the request queue, using a PEM worker thread, to handle incoming requests submitted to the PEM. The method also includes listening for multicast messages, using a PEM multicast listener thread, to be handled by the PEM worker thread.

Abstract: A storage node can include one or more processors and one or more storage disks, where the one or more storage disks include one or more local physical extents (PEs) that are local to the storage node. The storage node can include a protection pool driver executed by the one or more processors to run in a kernel space of the storage node, where the protection pool driver includes a local disk manager (LDM) and an array group module (AGRP). The LDM can be configured to manage the one or more local PEs at the one or more storage disks. The AGRP can include a number of storage arrays, where each of the storage arrays includes one or more virtual disks, where each of the one or more virtual disks is associated to at least a local PE or an external PE external to the storage node.

Abstract: A method, apparatus, and system for processing Redundant Array of Independent Disks (RAID) Input/Output (I/O) requests for a plurality of nodes in a cluster is disclosed. A file system request including a byte offset is received. Then, a Physical Extent (PE) row that matches the file system request and a RAID stripe within the identified PE row based on the byte offset is identified. Next, a plurality of RAID I/O requests to be routed to a physical disk is generated. Each of the plurality of the RAID I/O requests includes information associated with the PE and a type of operation. Thereafter, each of the RAID I/O requests is processed based on the information associated with the PE and the type of operation.

Abstract: A redundant array of independent disks (raid) array can include one or more virtual disks representing a raid configuration of the raid array. Each of the one or more virtual disks includes a number of physical extents (PEs), where a first PE and a second PE of the PEs have a same size. The first PE is located at a first storage disk of a first storage node of a cluster and the second PE is located at a second storage disk of a second storage node of the cluster.

Abstract: A method of reassembling a local disk manager (LDM) and array group (AGRP) includes starting a physical extent manager (PEM) configured to run on a number of nodes. The PEM on each node is configured to manage an AGRP running on the same node. A number of LDMs are reassembled, and each LDM is configured to manage virtual disks on each of the nodes. Once enough LDMs are reassembled, an AGRP can be reassembled.

Abstract: Methods and systems for characterizing subterranean formations are described herein. One method includes performing electromagnetic logging measurements along a portion of a borehole traversing the subterranean formation using an electromagnetic logging tool to obtain electromagnetic data. The method also includes processing the electromagnetic data to determine a plurality of one dimensional formation models associated with the portion of the borehole. A two dimensional pixel grid is determined using the plurality of one dimensional formation models. The method further includes determining a two dimensional formation model for the subterranean formation by performing an inversion of the electromagnetic data using the two dimensional pixel grid. The methods and systems described herein can be used to steer a bottom-hole assembly during well placement.

Abstract: Apparatuses, systems and methods are provided for generating a vehicle driver signature. More particularly, apparatuses, systems and methods are provided for generating a vehicle driver signature based on current image data, previously classified image data, and vehicle dynamics data.

Abstract: Inversion-based workflows are provided for real-time interpretation of the electromagnetic (EM) look-around and look-ahead measurements. The profile of a look-around zone is determined by interpreting EM measurements of a look-around zone. The profile of the look-around zone characterizes formation dip as well as vertical resistivity or resistivity anisotropy of one or more formation layers of the look-around zone. The profile of a look-ahead zone is determined by interpreting EM measurements of the look-ahead zone. The profile of the look-ahead zone characterizes formation dip as well as horizontal resistivity, vertical resistivity or anisotropy of one or more formation layers of the look-ahead zone. The workflows can also involve interpretation of look-around resistivity measurements to aid in the characterization of the look-around zone.

Abstract: A method and system is provided for drilling a wellbore that traverses a geological formation using a drilling tool. The method and system derives a plurality of formation models that characterize the geological formation. The number of formation models represent layer structures with a heterogeneity (such a fault) offset laterally at variable distance relative to position of the drilling tool. Simulated directional resistivity data of the drilling tool is derived from the plurality of formation models. Certain simulated directional resistivity data are combined or selected for processing as multi-dimensional cross-plot data. Measured directional resistivity data obtained by the drilling tool is used to evaluate the multi-dimensional cross-plot data to determine distance of the heterogeneity relative to position of the drilling tool.

Abstract: Apparatuses, systems and methods are provided for generating a vehicle driver signature. More particularly, apparatuses, systems and methods are provided for generating a vehicle driver signature based on vehicle interior image data and vehicle dynamics data. The vehicle interior image data may be representative of an identification of a particular individual. The vehicle dynamics data may be representative of a particular driving style, or driving behavior, associated with a particular individual.

Abstract: A waveguide assembly which includes an elongated waveguide element (1) and a connector body (2). The connector body (2) is connected to an end of the elongated waveguide element (1) and has a substantially planar bottom surface (24) and an opposing top surface (23). The connector body is made from a single piece of partially metallized dielectric. The connector body has a waveguide coupling element (21) adjacent to the elongated waveguide element (1). The connector body further has an arrangement of electromagnetic band gap elements (27) adjacent to the waveguide coupling element (21).

Abstract: A method for characterizing a subterranean formation, the method comprising: performing electromagnetic logging measurements along a portion of a borehole traversing the subterranean formation using an electromagnetic logging tool to obtain electromagnetic data; determining one or more initial approximations for one or more electromagnetic properties associated with a two dimensional imaging plane modeling the subterranean formation; determining one or more initial approximations for a relative orientation between the two dimensional imaging plane and an orientation of a trajectory along the portion of the borehole; and performing a first inversion using (i) the one or more initial approximations of the one or more electromagnetic properties, (ii) the one or more initial approximations for the relative orientation between the two dimensional imaging plane and the orientation of the trajectory, and (iii) the electromagnetic data to estimate an orientation of the two dimensional imaging plane relative to the or