A nuclear magnetic resonance (NMR) apparatus includes at least one magnet configured to induce a static magnetic field in a sample of material to be analyzed. At least one radio frequency antenna is configured to induce a radio frequency magnetic field in the sample of material to be analyzed. The sample chamber is disposed in a substantially longitudinally continuous sample holder separated into discrete sample chambers. Each sample chamber has an internal opening dimension such that substantially all of each sample is affected by surface contact phenomena with an internal wall of each sample chamber.

Disclosed herein is a device defining a generally closed volume therein, henceforth known as a “shuttle”, not permanently fixed to a probe or other surface inside the cryostat, into which gas and/or liquid—most preferably helium gas or liquid—can pass into or out of in a controlled and predictable manner. The passage of gas or liquid into the shuttle is preferably via a porous barrier so that sterile conditions can be maintained in the interior of the shuttle.

A drilling area network hub is located proximate to a drill rig and includes an uphole transceiver in bidirectional communication with a downhole transceiver by utilizing the drill string as an electrical conductor. Certain information is collected including rig-based and/or location information. At least one field report is generated based on the certain information to characterize at least one of an inground operation, an operational condition of the downhole transceiver, an operational condition of the uphole transceiver, and an operational condition of the drill rig. A drilling area network server receives the field report from the Internet at a remote location and can generate a custom report and/or recommended actions based on field data. Region specific parameters can be applied to the operation of a drilling system. The drilling area network hub can transfer data logs to the remote location according to assigned priorities.

An NMR probe including an RF coil, a sample region defined within the coil, and a thermal control apparatus comprising a thermal control fluid circuit having a thermal control fluid inlet and a thermal control fluid outlet to control the temperature of the sample region.

The invention is a petroleum well downhole logging tool (0) comprising —a wireline telemetry controller unit (6) comprising —a downhole modem (61) for transmitting data at a first bitrate uplink on a wireline (8) to a surface telemetry unit (106) connected to a surface read-out unit (SRO) with a memory (123)), a server toolbus controller (62) connected between said downhole modem (61) and an internal tool databus (7) operating at a second bitrate (r2) higher than the first bitrate; —one or more logging tools (4) each with sensors (40a, 40b, 40c, . . . ), each with a client toolbus controller (42) connected on said tool databus (7), said downhole logging tool (0) further comprising —a memory tool unit (2) with a memory section (21) with relatively high IO speed and capacity and connected to said internal tool databus (7) via a memory tool client toolbus controller (42m) connected to said tool databus (7) and arranged for communicating with said server toolbus controller (62), said memory tool (2) further provided with —an internal local high speed data bus (3) operating at a third bitrate (r3) higher than said second bitrate (r2), to —a high-resolution logging tool (1) with one or more sensors (1s) which provides high-resolution data (11), —said memory tool (2) arranged for transmitting a part (11s) of said high-resolution data (11) via said internal tool databus (7) online to said server toolbus controller (62) during logging, and —for uploading more of or all of said high-resolution data (11) via said server toolbus controller (62) to said surface telemetry unit (106) and said surface read-out unit (SRO).

An electronic frame for use in a downhole component coupling mechanism includes: a first frame element including at least one retaining structure configured to retain an electronic component; and a second frame element configured to be disposed at the first frame element, the second frame element permanently joined to the first frame element to isolate the electronic component from downhole fluids and form the electronic frame, the electronic frame configured to be disposed in a coupling assembly of a first downhole component and a second downhole component and constrained axially by the coupling assembly.

Provided are high-speed magnetic resonance imaging methods and apparatuses that enable simultaneously obtaining magnetic resonance images with different resolutions. The present embodiments may produce magnetic resonance images with different resolutions more quickly by decreasing time taken to complete scan operations that are performed for producing the magnetic resonance images.

A sensing apparatus for detecting and determining the magnitude of a static magnetic field has a first set of coils capable of producing a sweeping, quasi static, magnetic field when driven by a direct current and a second set of coils, for magnetic field modulation, positioned between the first set of coils capable of producing a low-frequency (audio), oscillating magnetic field when driven by an oscillating current. The magnetic fields induce a current through the semiconductor device which sampled to identify changes as a function of sweeping, quasi static magnetic field. To create an apparatus for detecting and identifying atomic scale defects in fully processed devices, a radio frequency circuit with a resonant component is added which provides an oscillating electromagnetic field in a direction perpendicular to that of the static magnetic field produced by the first set of coils.

An apparatus for measuring radio frequency output for a magnetic resonance imaging apparatus includes a plurality of directional couplers, a comparator, a switcher and a converter. The plurality of directional couplers are different in degree of coupling from each other, and attenuate an RF signal which is generated in an RF signal generator and amplified in an RF power amplifier. The comparator compares input-level information of a signal inputted into the RF power amplifier with a threshold value. The switcher switches to any one of the plurality of the directional couplers based on a result of the comparison so as to output an RF signal by the one directional coupler. The converter performs a digital conversion of the RF signal from the one directional coupler so as to output a digital signal.

A method and system for resistivity imaging. A method may comprise disposing a downhole tool into a borehole, applying a voltage difference between the array of injector electrodes, constructing a first set of formation images for each of the plurality of frequencies, applying a mud effect removal algorithm to produce a second set of formation images for each of the plurality of frequencies, applying a dielectric correction algorithm to each of the plurality of frequencies to produce a third set of formation images for each of the plurality of frequencies, and combining the first set of formation images, the second set of formation images, and the third set of formation images to obtain a blended image. A system for resistivity imaging may comprise a downhole tool. The downhole tool may comprises a pad, an array of injector electrodes, and one or more return electrodes.