Some examples of monitoring hydrocarbon reservoirs using induced polarization effect includes inducing polarization in a subterranean zone using an induced polarization fluid. The subterranean zone includes first formations and second formations. A quantity of hydrocarbons in the first formations is greater than quantity of hydrocarbons in the second formations. The induced polarization data is obtained from the subterranean zone. A portion of the induced polarization data from the first formations is different from a portion of the induced polarization data from the second formations. The second formations in the subterranean zone are identified based on the obtained induced polarization data

Some embodiments of the invention relate to a mobile detection device for an evaluation of a distance value from the mobile detection device to an occluded AC-current carrying structure according to its emanated magnetic field, like a location of underground services. The mobile detection device may include multiple detection coils arranged with a spacing with respect to one another and an electronic signal evaluation unit for detecting the structure according to an electrical signal induced in the detection coils by the magnetic field and to evaluate the distance value according to a difference of the electrical signal in-between at least two of the detection coils.

Some embodiments of the invention relate to a mobile detection device for an evaluation of a distance value from the mobile detection device to an occluded AC-current carrying structure according to its emanated magnetic field, like a location of underground services. The mobile detection device may include multiple detection coils arranged with a spacing with respect to one another and an electronic signal evaluation unit for detecting the structure according to an electrical signal induced in the detection coils by the magnetic field and to evaluate the distance value according to a difference of the electrical signal in-between at least two of the detection coils.

Rim of steering wheel has a rim body and mounting component mounted to the rim body so as to be exposed from a portion of the rim body. Occupant information detection sensor for a steering wheel disposed in rim includes: sensor wire disposed in the rim body; and conductive member located on at least a surface side of mounting component and electrically connected or capacitively coupled with a portion of sensor wire.

Rim of steering wheel has a rim body and mounting component mounted to the rim body so as to be exposed from a portion of the rim body. Occupant information detection sensor for a steering wheel disposed in rim includes: sensor wire disposed in the rim body; and conductive member located on at least a surface side of mounting component and electrically connected or capacitively coupled with a portion of sensor wire.

A system and method of for underground line location includes an underground line locator. The underground line locator includes an antenna system configured to generate signal information based on a proximity and an orientation of an underground line relative to the antenna system, a positioning system configured to generate position information based on the location of the underground line locator, and a controller coupled to the antenna system and the positioning system. The controller is configured to receive the signal information from the antenna system and the positioning information from the positioning system.

A system and method of for underground line location includes an underground line locator. The underground line locator includes an antenna system configured to generate signal information based on a proximity and an orientation of an underground line relative to the antenna system, a positioning system configured to generate position information based on the location of the underground line locator, and a controller coupled to the antenna system and the positioning system. The controller is configured to receive the signal information from the antenna system and the positioning information from the positioning system.

A pest monitoring system generally includes a circuit, wherein the circuit is initially in a first impedance state that is configured to change to a second impedance state due to pest activity, wherein the second impedance state is lower than the first impedance state.

A pest monitoring system generally includes a circuit, wherein the circuit is initially in a first impedance state that is configured to change to a second impedance state due to pest activity, wherein the second impedance state is lower than the first impedance state.

Some examples of monitoring hydrocarbon reservoirs using induced polarization effect includes inducing polarization in a subterranean zone using an induced polarization fluid. The subterranean zone includes first formations and second formations. A quantity of hydrocarbons in the first formations is greater than quantity of hydrocarbons in the second formations. The induced polarization data is obtained from the subterranean zone. A portion of the induced polarization data from the first formations is different from a portion of the induced polarization data from the second formations. The second formations in the subterranean zone are identified based on the obtained induced polarization data