An embedded file network server based on a seismic data stream includes a broadband power management module, a main control unit, a serial-port-to-RS232 module, a PHY bridge layer, an SD card, and a network interface. The main control unit includes serial port, an SDIO interface, an internal RAM, DMA units, and a MAC drive layer. The main control unit performs seismic data interaction with an external device through the serial port, and receives seismic data through an internal interruption, and the received seismic data stream is stored in the internal RAM. The internal RAM transfers the received seismic data stream to the SDIO interface and MAC driver layer through the DMA units. The SDIO interface stores the seismic data stream in the SD card for data backup. The MAC driver layer is coupled to the PHY bridge layer for inputting and outputting the seismic data stream.

A mobile docking device is configured to receive seismic acquisition units. The mobile docking device includes a container having a front opening, a docking module located within the container, the docking module having plural docking bays, each docking bay being configured to receive one of the seismic acquisition units through the front opening, a removable front wall configured to be attached to the container to cover the front opening to secure the seismic acquisition units, and handles attached to the container. The removable front wall biases the seismic acquisition units to maintain a direct electrical connection between tubular pins of the plural docking bays and pins of the seismic acquisition units during transport of the mobile docking device.

A method of correcting clock drift in at least one slave clock in a seismic node. The method comprises obtaining a number of clock drift measurements of the at least one slave clock in the at least one seismic node. A clock drift correction function as a function of time is calculated by curve fitting the number of clock drift measurements to a 2nd order polynomial. A time of reference of the recorded seismic sensor data is corrected by the 2nd order polynomial clock drift correction function.

A method for customized canonical data standardization, ingestion, and storage includes: receiving a configuration set defining a formatting parameter, a unit conversion parameter, and a transmission parameter, receiving a data record from a data source, wherein the data record includes oilfield-related data, converting units within the data record to a standardized unit defined based at least partially on the unit conversion parameter, formatting the data record based at least partially on the formatting parameter, wherein the formatting parameter defines one or more modifications to make to the data record, and providing the data record to a cloud hosting system for storage after converting the units and the formatting the data record, wherein the providing the data record comprises transmitting the data record in a manner defined by the configuration set.

An embedded file network server based on a seismic data stream includes a broadband power management module, a main control unit, a serial-port-to-RS232 module, a PHY bridge layer, an SD card, and a network interface. The main control unit includes serial port, an SDIO interface, an internal RAM, DMA units, and a MAC drive layer. The main control unit performs seismic data interaction with an external device through the serial port, and receives seismic data through an internal interruption, and the received seismic data stream is stored in the internal RAM. The internal RAM transfers the received seismic data stream to the SDIO interface and MAC driver layer through the DMA units. The SDIO interface stores the seismic data stream in the SD card for data backup. The MAC driver layer is coupled to the PHY bridge layer for inputting and outputting the seismic data stream.

The adjustable voltage regulator under control of a microcontroller applies controlled amplitude voltage in the range of 5 to 9VDC to the sensor transmitter to adjust the output amplitude of the transmitter. The adjustable amplitude transmitter allows an occupancy sensor to have its total output energy adjusted to reduce environmental noise-induced false triggering and to conform to the area to be covered. Lowering the total ultrasonic energy in the monitored space lowers the sensitivity of the receiver to inappropriate activations. Lowering the input power to the transmitter also lowers the total internal system noise and provides an improved signal to noise ratio in the receiver.

A method for hydrocarbon exploration based on imaging tunnel valleys is disclosed. The method includes obtaining a 3D seismic volume data corresponding to a target formation having at least one tunnel valley, interpreting a key horizon at or above the target formation as preparation for paleo-depositional environment restoration, flattening and decimating the 3D seismic volume data using the key horizon for paleo-depositional environment restoration to obtain a conditioned 3D seismic volume data, analyzing the conditioned 3D seismic volume data for frequency content and decomposing the conditioned 3D seismic volume data into at least three attributes, blending the at least three attributes to form a single seismic volume data to illuminate key features, and displaying, on a map, a distribution of the tunnel valleys in the 3D seismic volume data of the target formation.

A submersible node and a method and system for using the node to acquire data, including seismic data is disclosed. The node incorporates a buoyancy system to provide propulsion for the node between respective landed locations by varying the buoyancy between positive and negative. A first acoustic positioning system is used to facilitate positioning of a node when landing and a second acoustic positioning system is used to facilitate a node transiting between respective target landed locations.

A system for collecting subsurface formation data in a petroleum exploration environment includes a drilling tool and a subsurface formation data hub. A drilling tool may include drill pipe, a geophone, a drilling hammer, and a drill bit. The subsurface formation data hub may comprise a seismic data processor and a user interface. The seismic data processor may be operable to drive the drilling hammer at a frequency and an energy, synchronize the geophone to sense seismic vibration at a frequency, and determine subsurface formation properties. The user interface may be operable to display subsurface formation data. A method of collecting subsurface formation data in a petroleum exploration environment may include defining a drilling hammer frequency and energy, synchronizing a geophone to sense seismic vibration at a frequency, generating an impact in the petroleum exploration environment, receiving a returning seismic vibration at the geophone, and collecting subsurface formation data.

The adjustable voltage regulator under control of a microcontroller applies controlled amplitude voltage in the range of 5 to 9 VDC to the sensor transmitter to adjust the output amplitude of the transmitter. The adjustable amplitude transmitter allows an occupancy sensor to have its total output energy adjusted to reduce environmental noise-induced false triggering and to conform to the area to be covered. Lowering the total ultrasonic energy in the monitored space lowers the sensitivity of the receiver to inappropriate activations. Lowering the input power to the transmitter also lowers the total internal system noise and provides an improved signal to noise ratio in the receiver.