Abstract: Cookware identification includes exciting a cooking vessel using an excitation component. It further includes sensing an acoustic response of the cooking vessel to the excitation using a sensor. It further includes determining a type of the cooking vessel based at least in part on the acoustic response of the cooking vessel to the excitation that is sensed via the sensor. Ingredient state detection includes sensing, using an acoustic sensor, vibrations pertaining to cooking of an ingredient in a cooking vessel. It further includes monitoring, over time, a signal that is based on the vibrations sensed by the acoustic sensor. It further includes, based on detecting a change in the signal that is based on the vibrations sensed by the acoustic sensor, determining a state of the ingredient.

Abstract: Providing a universal cooking interface that is adaptive to the context of different types of cookware includes recognizing a type of a cookware object that is in a presence of a cooking device. It further includes adapting a contextual user interface of the cooking device based on the recognized type of the cookware object.

Abstract: A sustainable non-stick cookware system that includes an inductive component that interacts with an induction coil. The system further includes a thermal distribution component that distributes heat throughout the thermal distribution component, including laterally. The system further includes a cooking surface on which a polymerized layer of seasoning is able to be formed, where: the polymerized layer of seasoning makes the cooking surface non-stick; and the polymerized layer of seasoning is able to be reformed a plurality of times on the cooking surface.

Abstract: Providing a universal cooking interface that is adaptive to the context of different types of cookware includes recognizing a type of a cookware object that is in a presence of a cooking device. It further includes adapting a contextual user interface of the cooking device based on the recognized type of the cookware object.

Abstract: Adaptive temperature control for cooking includes recognizing a type of a cookware object that is in a presence of a cooking device. It further includes controlling a heating element of the cooking device according to a set of closed loop temperature control parameters corresponding to the recognized type of the cookware object.

Abstract: Generating a programmatic representation of a recipe for playback on a cooking device includes receiving a log of timestamped sensor events recorded during user control of a first cooking device. It further includes converting the log of timestamped sensor events into a recipe program that is executable on a second cooking device.

Abstract: Techniques for operating a kinematic structure by manual motion of a link coupled to the kinematic structure include a system comprising a first manipulating means and processing means. The processing means is for detecting whether a first means for accessing an internal worksite is mounted to the first manipulating means; detecting an input indicating the system is to be in a set-up mode; and inhibiting, in response to detecting that the first means is mounted to the first manipulating means, transition of the system to the set-up mode.

Abstract: Techniques for operating a kinematic structure by manual motion of a link coupled to the kinematic structure include a system having a kinematic structure configured to support an instrument and a processor. The processor is configured to place the system in a clutching mode; transition the system from the clutching mode to a set-up mode in response to detecting a joint operation of the kinematic structure; while in the set-up mode, determine an input displacement of a link from an initial positional relationship relative to a portion of the kinematic structure to a displaced positional relationship relative to the portion of the kinematic structure; and while in the set-up mode and in response to the determined input displacement, drive the kinematic structure so that the link returns toward the initial positional relationship relative to the portion of the kinematic structure.

Abstract: A method includes moving a stabilization device comprising a stabilization surface relative to a base of a surgical cart, wherein the moving comprises moving the stabilization device from a retracted position in which the stabilization surface is spaced from the ground surface to a deployed position in which the stabilization surface is in contact with the ground surface, and wherein the moving comprises overcoming a biasing force biasing the stabilization device toward the retracted position.

Abstract: User-initiated break-away clutching includes a robotic system having a joint, a brake or drive unit coupled to the joint, and a control system coupled with the brake or drive unit. The control system is configured to determine a first manual effort applied to the joint; inhibit, using the brake or drive unit, manual articulation of the joint in response to the first manual effort being below an articulation threshold; facilitate, using the brake or drive unit, the manual articulation of the joint in response to the first manual effort exceeding the articulation threshold; and inhibit, using the brake or drive unit, further manual articulation of the joint in response to a determination that a speed of the manual articulation of the joint is below a speed threshold.

Abstract: Robotic and/or surgical devices, systems, and methods include a robotic device. The robotic device includes a manipulator, a drive unit coupled to the manipulator, and a processor coupled with the drive unit. The processor is configured determine that a cannula is mounted to the manipulator and inhibit, using the drive unit, manual articulation of the manipulator in response to determining that the cannula is mounted to the manipulator. In some embodiments, the robotic device further includes a linkage. The processor is further configured to determine a manual effort against the manipulator; inhibit, using the drive unit, the manual articulation of the linkage in response to the manual effort being below an articulation threshold; and facilitate, using the drive unit and in response to not determining that the cannula is mounted to the manipulator, the manual articulation of the linkage in response to the manual effort exceeding the articulation threshold.

Abstract: Techniques for operating a kinematic structure by manual motion of a link coupled to the kinematic structure include a system having a kinematic structure configured to support an instrument and a processor. The processor is configured to place the system in a clutching mode; transition the system from the clutching mode to a set-up mode in response to detecting a joint operation of the kinematic structure; while in the set-up mode, determine an input displacement of a link from an initial positional relationship relative to a portion of the kinematic structure to a displaced positional relationship relative to the portion of the kinematic structure; and while in the set-up mode and in response to the determined input displacement, drive the kinematic structure so that the link returns toward the initial positional relationship relative to the portion of the kinematic structure.

Abstract: Techniques for operating a kinematic structure by manual motion of a link coupled to the kinematic structure include a system having a kinematic structure configured to support an instrument and a processor. The processor is configured to place the system in a clutching mode, transition the system from the clutching mode to a set-up mode in response to detecting a joint operation of the kinematic structure, establish a desired reference location of a link relative to a portion of the kinematic structure, detect an error between an actual reference location of the link relative to the portion and the desired reference location of the link, and drive the kinematic structure so as to decrease the error. The link is distal to the portion on the kinematic structure. The error is due to manual movement of the link.

Abstract: Methods for minimally invasive electro-surgical systems are disclosed. One method includes determining if an input device is selected at a control console. If the input device is selected then, providing feedback to a user of the selection of the input device, delaying a first predetermined period of time for the user to receive the feedback, determining if the input device is deselected, and if not deselected, then activating an electrosurgical device to couple energy to tissue. If deselected, the method skips activation of the electrosurgical device. While active, a method includes determining if the input device is deselected, and if so, then deactivating the electrosurgical device, determining if the input device is reselected and if the input device is not reselected, then waiting and determining if a second predetermined period of time has lapsed prior to reselection of the input device and if not, then repeating the reselected determining step.

Abstract: A teleoperational medical system for performing a medical procedure in a surgical field includes a dynamic guided setup system having step-by-step setup instructions for setting up a teleoperational assembly having at least one motorized surgical arm configured to assist in a surgical procedure. It also includes a user interface configured to communicate the step-by-step setup instructions to a user. The dynamic guided setup system is configured to automatically recognize completion of a first setup step based on detected physical arrangement of at least one surgical arm on a teleoperational assembly and automatically display a prompt for a subsequent setup step after the recognizing completion of the first setup step.

Abstract: A method for a minimally invasive surgical system is disclosed including capturing camera images of a surgical site; generating a graphical user interface (GUI) including a first colored border portion in a first side and a second colored border in a second side opposite the first side; and overlaying the GUI onto the captured camera images of the surgical site for display on a display device of a surgeon console. The GUI provides information to a user regarding the first electrosurgical tool and the second tool in the surgical site that is concurrently displayed by the captured camera images. The first colored border portion in the GUI indicates that the first electrosurgical tool is controlled by a first master grip of the surgeon console and the second colored border portion indicates the tool type of the second tool controlled by a second master grip of the surgeon console.

Abstract: A method of assigning an auxiliary input device to control a surgical instrument in a computer-assisted surgical system includes detecting a first surgical instrument coupled to a first manipulator interface assembly of a computer-assisted surgical system, the first manipulator interface assembly being controlled by a first input device.

Abstract: A teleoperational medical system for performing a medical procedure in a surgical field includes a dynamic guided setup system having step-by-step setup instructions for setting up a teleoperational assembly having at least one motorized surgical arm configured to assist in a surgical procedure. It also includes a user interface configured to communicate the step-by-step setup instructions to a user. The dynamic guided setup system is configured to automatically recognize completion of a first setup step based on detected physical arrangement of at least one surgical arm on a teleoperational assembly and automatically display a prompt for a subsequent setup step after the recognizing completion of the first setup step.

Abstract: A user interface for a surgical system can include a display configured to output video images of a remote surgical site at which one or more electrosurgical instruments of the surgical system are deployed; and a graphical user interface configured to be output on the display with the video images. The graphical user interface may comprise a visual indication of a state of the one or more electrosurgical instruments that indicates a state of the one or more electrosurgical instruments being ready for activation to deliver energy or actively delivering energy.

Abstract: A method includes moving a stabilization device comprising a stabilization surface relative to a base of a surgical cart, wherein the moving comprises moving the stabilization device from a retracted position in which the stabilization surface is spaced from the ground surface to a deployed position in which the stabilization surface is in contact with the ground surface, and wherein the moving comprises overcoming a biasing force biasing the stabilization device toward the retracted position.