Techniques for controlling hydrocarbon production includes (i) identifying a plurality of reservoir measurements of a subterranean hydrocarbon reservoir located between at least one injection wellbore and at least one production wellbore; (ii) processing the identified plurality of reservoir measurements to generate a petrophysical model of the subterranean hydrocarbon reservoir; (iii) determining, based on the petrophysical model, a flow of an injectant from the injection wellbore toward the production wellbore; and (iv) adjusting an inflow control device (ICD) positioned about the production wellbore based on the determined flow of the injectant.

Aspects of the present disclosure relate to testing apparatus and methods for measuring forces between objects. The apparatus and methods are used to detect a change in the local gravitational constant resulting from non-Newtonian effects of General Relativity and/or a novel radial dilation influence. Detection is facilitated by measuring a force difference between a stationary state and a spinning state of attractive forces between objects. The apparatus and methods are used to detect a change in electromechanical influence of forces due to the Barnett affect and other anomalous electromagnetic force contributors. A testing apparatus includes a central target arrangement. The central target arrangement includes a pair of masses, and a target coupled to the pair of masses. The testing apparatus includes a detector configured to recognize the target, and a first rotatable mass. The first rotatable mass is supported independently of the target and the pair of target masses.

Aspects of the present disclosure relate to testing apparatus and methods for measuring forces between objects. The apparatus and methods are used to detect a change in the local gravitational constant resulting from non-Newtonian effects of General Relativity and/or a novel radial dilation influence. Detection is facilitated by measuring a force difference between a stationary state and a spinning state of attractive forces between objects. The apparatus and methods are used to detect a change in electromechanical influence of forces due to the Barnett affect and other anomalous electromagnetic force contributors. A testing apparatus includes a central target arrangement. The central target arrangement includes a pair of masses, and a target coupled to the pair of masses. The testing apparatus includes a detector configured to recognize the target, and a first rotatable mass. The first rotatable mass is supported independently of the target and the pair of target masses.

A highly sensitive gravimeter using a magnetic parallel dipole line (PDL) trap system is provided. In one aspect, a gravimeter includes: a vacuum enclosure; a PDL trap within the vacuum enclosure, the PDL trap having a pair of dipole line magnets, and a diamagnetic rod levitating in between the dipole line magnets; and a heater and temperature sensor within the vacuum enclosure configured to maintain a constant temperature within the vacuum enclosure that is greater than a temperature outside of the vacuum enclosure and precision frequency measurement system. The frequency of the oscillation of the trapped diamagnetic rod will yield the local gravitational acceleration. Methods for measuring a local gravitational field using the present gravimeter are also provided.

A highly sensitive gravimeter using a magnetic parallel dipole line (PDL) trap system is provided. In one aspect, a gravimeter includes: a vacuum enclosure; a PDL trap within the vacuum enclosure, the PDL trap having a pair of dipole line magnets, and a diamagnetic rod levitating in between the dipole line magnets; and a heater and temperature sensor within the vacuum enclosure configured to maintain a constant temperature within the vacuum enclosure that is greater than a temperature outside of the vacuum enclosure and precision frequency measurement system. The frequency of the oscillation of the trapped diamagnetic rod will yield the local gravitational acceleration. Methods for measuring a local gravitational field using the present gravimeter are also provided.

An interactive electronic apparatus and an interactive method thereof are provided. The interactive electronic apparatus includes a main device and a casing. The main device is installed in a containing space of the casing. After the main device establishes a connection with the casing, the casing sends at least one of a first distance between the casing and an object to be sensed by a first distance sensor and a second distance between a bottom portion of the casing and a plane detected by a second distance sensor to the main device. The main device determines an interactive state of interaction with the interactive electronic apparatus based on at least one of a movement information sensed by a gravity sensor, the first distance and the second distance, and sends an interactive signal corresponding to the interactive state.

An interactive electronic apparatus and an interactive method thereof are provided. The interactive electronic apparatus includes a main device and a casing. The main device is installed in a containing space of the casing. After the main device establishes a connection with the casing, the casing sends at least one of a first distance between the casing and an object to be sensed by a first distance sensor and a second distance between a bottom portion of the casing and a plane detected by a second distance sensor to the main device. The main device determines an interactive state of interaction with the interactive electronic apparatus based on at least one of a movement information sensed by a gravity sensor, the first distance and the second distance, and sends an interactive signal corresponding to the interactive state.

Techniques for controlling hydrocarbon production includes (i) identifying a plurality of reservoir measurements of a subterranean hydrocarbon reservoir located between at least one injection wellbore and at least one production wellbore; (ii) processing the identified plurality of reservoir measurements to generate a petrophysical model of the subterranean hydrocarbon reservoir; (iii) determining, based on the petrophysical model, a flow of an injectant from the injection wellbore toward the production wellbore; and (iv) adjusting an inflow control device (ICD) positioned about the production wellbore based on the determined flow of the injectant.

Systems and methods for to two dimensional gravity modeling with variable densities are disclosed. The methods may include a method of modeling the density of a subsurface formation is disclosed. The methods may include generating a plurality of cells in a cross section of density values corresponding to a subsurface formation. The methods may further include assigning a density value to each cell. The methods may further include calculating a gravity effect for each cell based upon the density value. The methods may further include recording the gravity effect for each cell in a data structure.

Systems and methods for to two dimensional gravity modeling with variable densities are disclosed. The methods may include a method of modeling the density of a subsurface formation is disclosed. The methods may include generating a plurality of cells in a cross section of density values corresponding to a subsurface formation. The methods may further include assigning a density value to each cell. The methods may further include calculating a gravity effect for each cell based upon the density value. The methods may further include recording the gravity effect for each cell in a data structure.