In one aspect, a seismic data acquisition unit is disclosed including a closed housing containing: a seismic sensor; a processor operatively coupled to the seismic sensor; a memory operatively coupled to the processor to record seismic data from the sensor; and a power source configured to power the
In one aspect, a seismic data acquisition unit is disclosed including a closed housing containing: a seismic sensor; a processor operatively coupled to the seismic sensor; a memory operatively coupled to the processor to record seismic data from the sensor; and a power source configured to power the sensor, processor and memory. The sensor, processor, memory and power source are configured to be assemble as an operable unit in the absence of the closed housing.
대표청구항▼
1. A system for seismic data acquisition, comprising: a seismic data acquisition unit comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records s
1. A system for seismic data acquisition, comprising: a seismic data acquisition unit comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory; anda connection port that electrically connects an external seismic sensor located external to the seismic data acquisition unit and the closed housing to the processor contained in the closed housing; andthe external seismic sensor located external and remote from the seismic data acquisition unit, the external seismic sensor connected to the connection port via an auxiliary cable. 2. The system of claim 1, wherein the seismic sensor, the processor, the memory and the power source are configured to be assembled as an operable unit in the absence of the closed housing. 3. The system of claim 1, wherein the closed housing comprises a cap having one or more pins that provide electrical connection to one or more elements contained in the closed housing. 4. The system of claim 3, further comprising: a flexible electrical connector member disposed under the cap in the closed housing configured to provide electrical connection between the one or more pins and the one or more elements contained in the closed housing;wherein the flexible electrical connector member is configured to flex in response to a deformation of the cap without causing an interruption of the electrical connection between the one or more pins and the one or more elements contained in the closed housing. 5. The system of claim 1, further comprising the connection port configured to electrically connect a plurality of external seismic sensors to the processor contained in the closed housing, the plurality of external seismic sensors located external to the closed housing. 6. The system of claim 1, further comprising a light emitting element included in the closed housing and electrically connected to the processor. 7. The system of claim 6, wherein the processor is configured to modulate output of the light emitting element to transmit data to a receiver external to the seismic sensor. 8. The system of claim 7, wherein the receiver external to the seismic sensor is mounted on a vehicle. 9. A system, comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory;a light emitting element included in the closed housing and electrically connected to the processor, the processor configured to modulate output of the light emitting element to transmit data to a receiver external to the seismic sensor; anda connection port that electrically connects an external seismic sensor located external to the closed housing to the processor contained in the closed housing;the external seismic sensor located external to the closed housing, the external seismic sensor connected to the connection port via an auxiliary cable; andthe receiver. 10. A method, comprising: deploying a seismic data acquisition unit comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory; anda connection port that electrically connects an external seismic sensor located external to the seismic data acquisition unit and the closed housing to the processor contained in the closed housing;providing the external seismic sensor located external to the seismic data acquisition unit, the external seismic sensor connected to the connection port via an auxiliary cable; andacquiring seismic data using the seismic data acquisition unit. 11. A system for ambidextrous seismic data acquisition, comprising: an ambidextrous seismic data acquisition unit comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory; anda connection port that electrically connects an external seismic sensor located external to the closed housing to the processor contained in the closed housing; andthe external seismic sensor located external to the ambidextrous seismic data acquisition unit, the external seismic sensor connected to the connection port via an auxiliary cable. 12. The system of claim 11, wherein the ambidextrous seismic data acquisition unit further comprises: the connection port to electrically connect a plurality of external seismic sensors to the processor, the plurality of external seismic sensors located external to the closed housing. 13. The system of claim 11, wherein the seismic sensor, the processor, the memory, and the power source are configured to be assembled as an operable unit in the absence of the closed housing. 14. The system of claim 11, wherein the closed housing comprises a cap having one or more pins that provide electrical connection to one or more elements contained in the closed housing. 15. The system of claim 14, wherein the ambidextrous seismic data acquisition unit further comprises: a flexible electrical connector member disposed under the cap in the closed housing configured to provide electrical connection between the one or more pins and the one or more elements contained in the closed housing;wherein the flexible electrical connector member is configured to flex in response to a deformation of the cap without causing an interruption of the electrical connection between the one or more pins and the one or more elements contained in the closed housing. 16. The system of claim 11, wherein the ambidextrous seismic data acquisition unit further comprises a light emitting element included in the closed housing and electrically connected to the processor. 17. The system of claim 16, wherein the processor is configured to modulate output of the light emitting element to transmit data to a receiver external to the seismic sensor. 18. The system of claim 17, wherein the receiver external to the seismic sensor is mounted on a vehicle. 19. A system, comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory; anda connection port that electrically connects an external seismic sensor located external to the closed housing to the processor contained in the closed housing;a light emitting element included in the closed housing and electrically connected to the processor,wherein the processor is configured to modulate output of the light emitting element to transmit data to a receiver external to the seismic sensor, the receiver mounted on a vehicle;the external seismic sensor located external to the closed housing, the external seismic sensor connected to the connection port via an auxiliary cable; and the receiver. 20. A method, comprising: deploying an ambidextrous seismic data acquisition unit comprising: a closed housing containing: a seismic sensor contained within the closed housing;a processor electrically connected to the seismic sensor;a memory electrically connected to the processor that records seismic data from the seismic sensor;a power source that powers the seismic sensor, the processor and the memory; anda connection port that electrically connects an external seismic sensor located external to the closed housing to the processor contained in the closed housing;providing the external seismic sensor located external from the ambidextrous seismic data acquisition unit, the external seismic sensor connected to the connection port via an auxiliary cable;acquiring seismic data using the ambidextrous seismic data acquisition unit;reconfiguring the ambidextrous seismic data acquisition unit by electrically connecting a second seismic sensor to the processor via the connection port; andacquiring additional seismic data using the ambidextrous seismic data acquisition unit reconfigured with the second seismic sensor electrically connected to the processor via the connection port.
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