Systems and methods for surveying a seafloor utilize two or more of seismic data, acoustic data and electrical potential or resistivity data to identify the locations of objects on or beneath the seafloor. The methods involve moving survey equipment over a geographic area of the seafloor and conducting a plurality of sensing or detecting operations while moving the survey equipment over the geographic area. The plurality of operations include two or more of: (1) a seismic operation that emits seismic energy toward the seafloor and collects seismic data based on seismic energy that returns from the seafloor, (2) an acoustic operation that emits acoustic energy toward the seafloor and collects acoustic data based on acoustic energy that returns from the seafloor, and/or (3) an electrical operation that supplies electrical power into seawater and that collects electric potential data indicative of electric potential that is induced into the seawater.

Systems and methods for surveying a seafloor utilize two or more of seismic data, acoustic data and electrical potential or resistivity data to identify the locations of objects on or beneath the seafloor. The methods involve moving survey equipment over a geographic area of the seafloor and conducting a plurality of sensing or detecting operations while moving the survey equipment over the geographic area. The plurality of operations include two or more of: (1) a seismic operation that emits seismic energy toward the seafloor and collects seismic data based on seismic energy that returns from the seafloor, (2) an acoustic operation that emits acoustic energy toward the seafloor and collects acoustic data based on acoustic energy that returns from the seafloor, and/or (3) an electrical operation that supplies electrical power into seawater and that collects electric potential data indicative of electric potential that is induced into the seawater.

The present invention belongs to the field of environment monitoring, particularly relates to a CO.sub.2 storage state networking monitoring device, system and method with multi-information fusion. The present invention comprises: obtaining orientation electrical signal data and real-time pressure signals, analyzing a fluid flowing state at a view of a pressure sensor through the real-time pressure signals, and obtaining a CO.sub.2 flowing state through the orientation electrical signal data; and obtaining a CO.sub.2 regional storage state by combining an orientation CO.sub.2 content, a CO.sub.2 flowing state and the fluid flowing condition at the view of the pressure sensor. By combining accurate short-range CO.sub.2 boundary monitoring of orientation electrodes with long-range monitoring of pressure senors to achieve a wide range of CO.sub.2 flowing state monitoring, the present invention can observe more data with higher reliability and effectively aims at the problem of strong inter-well heterogeneity.

The present invention belongs to the field of environment monitoring, particularly relates to a CO.sub.2 storage state networking monitoring device, system and method with multi-information fusion. The present invention comprises: obtaining orientation electrical signal data and real-time pressure signals, analyzing a fluid flowing state at a view of a pressure sensor through the real-time pressure signals, and obtaining a CO.sub.2 flowing state through the orientation electrical signal data; and obtaining a CO.sub.2 regional storage state by combining an orientation CO.sub.2 content, a CO.sub.2 flowing state and the fluid flowing condition at the view of the pressure sensor. By combining accurate short-range CO.sub.2 boundary monitoring of orientation electrodes with long-range monitoring of pressure senors to achieve a wide range of CO.sub.2 flowing state monitoring, the present invention can observe more data with higher reliability and effectively aims at the problem of strong inter-well heterogeneity.

In a proximity sensor including a circuit board on which a detection circuit is printed, and a first drive electrode and a lock electrode mounted on one surface of the circuit board and electrically connected to the detection circuit, the first planar drive electrode and the planar lock electrode are formed in a standing manner on one surface of the circuit board to face each other. A second planar drive electrode and a planar unlock electrode are formed in a standing manner on the other surface of the circuit board to face each other. The proximity sensor is used in a keyless entry device of vehicle, and the controller that controls driving of an actuator for locking or unlocking a vehicle door based on detection of the proximity sensor determines that the proximity sensor is turned on when decrease in output of the proximity sensor exceeds a predetermined threshold value.

In a proximity sensor including a circuit board on which a detection circuit is printed, and a first drive electrode and a lock electrode mounted on one surface of the circuit board and electrically connected to the detection circuit, the first planar drive electrode and the planar lock electrode are formed in a standing manner on one surface of the circuit board to face each other. A second planar drive electrode and a planar unlock electrode are formed in a standing manner on the other surface of the circuit board to face each other. The proximity sensor is used in a keyless entry device of vehicle, and the controller that controls driving of an actuator for locking or unlocking a vehicle door based on detection of the proximity sensor determines that the proximity sensor is turned on when decrease in output of the proximity sensor exceeds a predetermined threshold value.

Sensor assembly, for an ostomy appliance, comprising a support layer and a planar electrode assembly arranged on a surface of the support layer. The electrode assembly comprises at least a first electrode. The first electrode comprises a first main branch extending along a first main path and a first plurality of subbranches connected to the first main branch. Each of the subbranches are connected to the first main branch at respective connection points and extend in a direction at an angle relative to a tangent to the first main path at the respective connection point. Thereby is provided that a rupture of one of the subbranches does not compromise the functionality of the first electrode as such.

Sensor assembly, for an ostomy appliance, comprising a support layer and a planar electrode assembly arranged on a surface of the support layer. The electrode assembly comprises at least a first electrode. The first electrode comprises a first main branch extending along a first main path and a first plurality of subbranches connected to the first main branch. Each of the subbranches are connected to the first main branch at respective connection points and extend in a direction at an angle relative to a tangent to the first main path at the respective connection point. Thereby is provided that a rupture of one of the subbranches does not compromise the functionality of the first electrode as such.

A method for a multichannel geophysical data acquisition system is provided in the field of electrical resistivity tomography. Individual and autonomous node operating systems are provided. Separate communication channels for upstream and downstream data transfer, high voltage transfer and synchronization signals are provided. A novel use of high voltage isolation barriers is also provided. A direct memory access data transfer process is provided.

A system for detecting precipitation is disclosed. In an embodiment, the system includes a capacitive sensor configured to detect a presence of precipitation, a piezo sensor configured to be powered on in response to detection of the presence of the precipitation by the capacitive sensor, and a processor configured to detect a characteristic of the precipitation based at least in part on an output of the piezo sensor. In an embodiment, a method includes receiving a signal from a piezo sensor, sampling the signal at a sampling rate, determining a frequency domain representation of the sampled signal, determining that a magnitude of a resonant frequency associated with the sampled signal meets a threshold, and determining a valid precipitation event based at least in part on the determination that the magnitude of the resonant frequency meets the threshold.