Abstract: Systems, devices, and techniques for controlling a compression unit associated with cardiopulmonary resuscitation (CPR) are described herein. For example, a medical system may include a compression unit configured to apply pressure to a torso region of a patient. The compression unit may be configured to move within space according to at least one degree of freedom. The medical system may further include processing circuitry configured to receive one or more sets of data representative of one or more patient parameters of the patient. Additionally, the medical system may generate, using a deep learning model, an output data set representing a predicted trajectory of at least one patient parameter of the one or more patient parameters, determine a set of control parameters, and control the compression unit to apply the pressure to the torso region of the patient.

Abstract: The present disclosure relates to domain swap by accessing an image from a first domain and is processed using a machine learning model to generate a virtual synthetic image in a second domain. This approach can eliminate or reduce the need to separately collect an image in the second domain, which can save time and cost. Leveraging tools that are available in the second domain to perform image processing on the virtual synthetic image. Results or analysis from the image processing in the second domain can then be directly applied to the first domain and to assess the image further. Since spatial reference points (size, scale, view etc.) are same, pixels identifying a boundary of a region depicted in the virtual synthetic image are the same pixels in the first domain.

Abstract: A method includes selecting an operation mode for a pressure control equipment and determining whether a power distribution system has sufficient power available to support the selected operation mode.

Abstract: An interactive monitoring and control system for a mineral extraction system includes one or more processors configured to receive sensor data indicative of properties of components of the mineral extraction system and to provide a user interface for display via a display screen. The user interface includes a representation of the components of the mineral extraction system, includes the sensor data indicative of the properties of the components of the mineral extraction system, and enables a user to provide inputs to adjust the components of the mineral extraction system.

Abstract: An apparatus for controlling a subsea blowout preventor (BOP) includes a control system for controlling a subsea BOP of a subsea stack assembly installed over a subsea oil and gas well. The control system includes a first topside control device and a second topside control device, and a first subsea control device and a second subsea control device. The first topside control device, the second topside control device, the first subsea control device, and the second subsea control device are each communicatively connected with the BOP and operable to control operation of the BOP. The first subsea control device is a portion of a first control pod of the subsea stack assembly. The second subsea control device is a portion of a second control pod of the subsea stack assembly. The first topside control device is communicatively connected with the second topside control device via a ring communication network.

Abstract: A system can include a processor, a memory, and processor-executable instructions stored in the memory and executable by the processor to instruct the system to: generate a graphical user interface that includes one or more vector graphics renderings of equipment of a system for well operations, one or more data graphic renderings of real-time sensor data values of the system, and one or more graphical controls actuatable to issue a control instruction for control of the system, where the system includes an uninterruptible power supply (UPS) and a blowout preventer (BOP), and where the UPS is selectively, operatively coupled to one or more electric actuators for changing a state of the BOP; responsive to operation of the system, receive sensor data; and update the data graphic based at least in part on the sensor data.

Abstract: A method includes actuating a blow-out preventer (BOP) by moving a ram using an electric motor. The method also includes capturing sensor data with one or more sensors as the BOP is electrically-actuated. The method also includes determining one or more parameters with a controller based upon the sensor data. The method also includes controlling the electric motor based upon the one or more parameters.

Abstract: An apparatus for controlling a subsea blowout preventor (BOP) includes a control system for controlling a subsea BOP of a subsea stack assembly installed over a subsea oil and gas well. The control system includes a first topside control device and a second topside control device, and a first subsea control device and a second subsea control device. The first topside control device, the second topside control device, the first subsea control device, and the second subsea control device are each communicatively connected with the BOP and operable to control operation of the BOP. The first subsea control device is a portion of a first control pod of the subsea stack assembly. The second subsea control device is a portion of a second control pod of the subsea stack assembly. The first topside control device is communicatively connected with the second topside control device via a ring communication network.

Abstract: A method can include generating a graphical user interface that includes vector graphics representations of equipment of a system for well operations, a data graphic for rendering sensor data of the system, and a graphical control actuatable to issue a control instruction for control of the system, where the system includes an uninterruptible power supply (UPS) and a blowout preventer (BOP), and where the UPS is selectively, operatively coupled to one or more electric actuators for changing a state of the BOP; responsive to operation of the system, receiving sensor data; and updating the data graphic based at least in part on the sensor data.

Abstract: A method includes actuating a blow-out preventer (BOP) by moving a ram using an electric motor. The method also includes capturing sensor data with one or more sensors as the BOP is electrically-actuated. The method also includes determining one or more parameters with a controller based upon the sensor data. The method also includes controlling the electric motor based upon the one or more parameters.

Abstract: A drilling system includes a surface system comprising a control panel. The drilling system further includes a pressure control equipment configured to be operatively coupled to the control panel, wherein the control panel comprises at least one intrusion prevention system (IPS) enabled device configured to provide for one or more IPS functions.

Abstract: A method can include generating a graphical user interface that includes vector graphics representations of equipment of a system for well operations, a data graphic for rendering sensor data of the system, and a graphical control actuatable to issue a control instruction for control of the system, where the system includes an uninterruptible power supply (UPS) and a blowout preventer (BOP), and where the UPS is selectively, operatively coupled to one or more electric actuators for changing a state of the BOP; responsive to operation of the system, receiving sensor data; and updating the data graphic based at least in part on the sensor data.

Abstract: A computational framework can include a graphical user interface (GUI) generator; a logic generator; and a graphics generator, where the GUI generator generates a GUI for configuring a system of well equipment based on selections of graphical menu items, where the GUI dynamically responds to an interactive selection of one of the graphical menu items based on logic generated by the logic generator, and where the graphics generator generates a vector graphics representation of the system of well equipment as configured.

Abstract: An apparatus for controlling a subsea blowout preventor (BOP) includes a control system for controlling a subsea BOP of a subsea stack assembly installed over a subsea oil and gas well. The control system includes a first topside control device and a second topside control device, and a first subsea control device and a second subsea control device. The first topside control device, the second topside control device, the first subsea control device, and the second subsea control device are each communicatively connected with the BOP and operable to control operation of the BOP. The first subsea control device is a portion of a first control pod of the subsea stack assembly. The second subsea control device is a portion of a second control pod of the subsea stack assembly. The first topside control device is communicatively connected with the second topside control device via a ring communication network.

Abstract: A closing unit system for a blowout preventer (BOP) stack includes a fluid reservoir that stores a fluid at atmospheric pressure, at least one pump system fluidly coupled to the fluid reservoir, and at least one power source electrically coupled to the at least one pump system. At least one valve of the closing unit system is fluidly coupled to the at least one pump system and to an actuator associated with the BOP stack. The closing unit system also includes one or more processors configured to receive at least one input indicative of an instruction to control the actuator, and instruct the at least one power source to provide power to the at least one pump system to cause the at least one pump system to pump the fluid from the reservoir to the at least one valve in response to the at least one input.

Abstract: A method includes actuating a blow-out preventer (BOP) by moving a ram using an electric motor. The method also includes capturing sensor data with one or more sensors as the BOP is electrically-actuated. The method also includes determining one or more parameters with a controller based upon the sensor data. The method also includes controlling the electric motor based upon the one or more parameters.

Abstract: Systems for stowing and deploying an accessory on a watercraft are provided. More particularly, systems for providing watercraft, such as pontoon boats (or other watercraft), with deployment mechanisms for deploying marine accessories are provided. Such accessories can be deployed from a recessed location, such as a compartment within or underneath a deck of the watercraft.

Abstract: A closing unit system for a blowout preventer (BOP) stack includes a first fluid reservoir, a first power source, a first pump system fluidly coupled to the first fluid reservoir and electrically coupled to the first power source, and a valve manifold fluidly coupled to the first pump system via a closing unit hose assembly and configured to couple to the BOP stack. The closing unit system also includes one or more processors that are configured to receive an input indicative of an instruction to adjust an actuator associated with the BOP stack, and instruct the first power source to provide power to the first pump system to cause the first pump system to pump a fluid from the first fluid reservoir to the valve manifold in response to the input.

Abstract: A closing unit system for a blowout preventer (BOP) stack includes a first fluid reservoir, a first power source, a first pump system fluidly coupled to the first fluid reservoir and electrically coupled to the first power source, and a valve manifold fluidly coupled to the first pump system via a closing unit hose assembly and configured to couple to the BOP stack. The closing unit system also includes one or more processors that are configured to receive an input indicative of an instruction to adjust an actuator associated with the BOP stack, and instruct the first power source to provide power to the first pump system to cause the first pump system to pump a fluid from the first fluid reservoir to the valve manifold in response to the input.

Abstract: A method includes selecting an operation mode for a pressure control equipment and determining whether a power distribution system has sufficient power available to support the selected operation mode.