Abstract: Described herein is a wearable device for impact measurement with wireless power and communication capability. The wearable device includes a base member configured for placement on a human body, an electronic board affixed to the base member, and a rechargeable battery affixed to the base member. The device also includes a dual-band antenna printed on the electronic board for wireless power and data communication. Also provided are methods for charging the wearable device with different power sources.

Abstract: A control method includes empirically constructing for a flexible manipulator an estimated mapping between an end-effector movement and a plurality of values representing movement of at least one actuator, measuring an actual end-effector movement and an actual movement of the at least one actuator, and, based on the measuring, updating the estimated mapping while the flexible manipulator is active such that the mapping is adapted to the present environment of the flexible manipulator.

Abstract: Provided is a device for placement on a human subject to detect impacts on the human subject. The device includes a base member, one or more engagement sensors to detect whether the device is properly placed on the human subject, and one or more motion sensors to detect the kinematics of the human subject. The device also includes a processing unit that includes methodology to detect false positives such as chewing, dropping, and throwing.

Abstract: A magnetic force control system for guiding a medical instrument within a body includes: a controlled magnet coupled to the medical instrument; a controller magnet that exerts a magnetic force on the controlled magnet; a magnetically permeable shield, placed between the controlled magnet and the controller magnet, that selectively modulates the magnetic force by rerouting magnetic field lines; and a control system. A method for guiding a medical instrument within a body with magnetic force control includes: providing a controlled magnet coupled to the medical instrument, inserting the controlled magnet and medical instrument into the body, providing a controller magnet outside the body, placing a magnetically permeable shield between the controlled magnet and the controller magnet, applying magnetic force, and selectively modulating the magnetic force with the shield to vary at least one of amplitude and orientation of the magnetic force, thereby guiding the controlled magnet within the body.

Abstract: A robotic catheter manipulator includes a guide catheter including proximal and distal ends and lumen extending there through. A flexible bellows is secured at one end to the proximal end of the guide catheter and at the other end to a seal configured to receive a working catheter. In a loaded state, the working catheter is fixed relative to the seal. A ditherer is operatively connected to the seal for dithering the working catheter relative to the guide catheter when placed therein. The robotic catheter manipulator includes at least one force sensor for measuring the force applied to the working catheter by the ditherer. Force measurements may be translated into an estimated force that is experienced at the distal end of the working catheter which may then be displayed to the physician via a monitor or display.

Abstract: A robotic catheter manipulator includes a guide catheter including proximal and distal ends and lumen extending there through. A flexible bellows is secured at one end to the proximal end of the guide catheter and at the other end to a seal configured to receive a working catheter. In a loaded state, the working catheter is fixed relative to the seal. A ditherer is operatively connected to the seal for dithering the working catheter relative to the guide catheter when placed therein. The robotic catheter manipulator includes at least one force sensor for measuring the force applied to the working catheter by the ditherer. Force measurements may be translated into an estimated force that is experienced at the distal end of the working catheter which may then be displayed to the physician via a monitor or display.

Abstract: Mosaicing methods and devices are implementing in a variety of manners. One such method is implemented for generation of a continuous image representation of an area from multiple images consecutively received from an image sensor. A location of a currently received image is indicated relative to the image sensor. A position of a currently received image relative to a set of previously received images is indicated with reference to the indicated location. The currently received image is compared to the set of previously received images as a function of the indicated position. Responsive to the comparison, adjustment information is indicated relative to the indicated position. The currently received image is merged with the set of previously received images to generate data representing a new set of images.

Abstract: A magnetic force control system for guiding a medical instrument within a body includes: a controlled magnet coupled to the medical instrument; a controller magnet that exerts a magnetic force on the controlled magnet; a magnetically permeable shield, placed between the controlled magnet and the controller magnet, that selectively modulates the magnetic force by rerouting magnetic field lines; and a control system. A method for guiding a medical instrument within a body with magnetic force control includes: providing a controlled magnet coupled to the medical instrument, inserting the controlled magnet and medical instrument into the body, providing a controller magnet outside the body, placing a magnetically permeable shield between the controlled magnet and the controller magnet, applying magnetic force, and selectively modulating the magnetic force with the shield to vary at least one of amplitude and orientation of the magnetic force, thereby guiding the controlled magnet within the body.

Abstract: Robotic instrument systems and control implementations are disclosed. In one such system, an elongate guide instrument such as a guide catheter includes tension or deflection element such as a stainless steel wire or pull wire. An actuator, such as a servo motor, is operably coupled to the controller. The controller is configured to control actuation of the servo motor based on execution of a control model including a mechanics model that accounts for a force on the guide instrument. The control model may also utilize both kinematics and mechanics models. The controller is configured to control actuation of the actuator based the control model that includes the mechanics model such that the elongate guide instrument bends when the actuator moves the deflection member.