A hand strength appliance is provided that may be used in multiple or selected configurations for grip and pinch strength assessment as well as grip and pinch exercises. The appliance includes a frame and a sliding internal handle fitted within and slidable within the frame, and may be positioned for multiple test positions and exercises. The appliance may include and be used with a force sensing device that may transmit information to a computing device.

Methods and devices to diagnose and treat male urinary incontinence and sexual dysfunction are provided. A multiple sensor-enabled catheter for rectal insertion in a male patient allows for the visualization and manipulation or positioning of the bladder. A multiple sensor-enabled catheter for rectal insertion in a male patient allows for the visualization and implementation of efficient and effective exercises to strengthen pelvic floor muscles.

System and techniques for tracking caloric expenditure using sensor driven fingerprints are described herein. A set of outputs may be obtained from a plurality of sensors. A fingerprint may be generated using the set of outputs. The fingerprint may correspond to an activity observed by the plurality of sensors. The generated fingerprint may be compared to a set of fingerprints stored in a database. Each fingerprint of the set of fingerprints may correspond to a respective caloric expenditure. A caloric expenditure may be calculated for the activity based on the comparison. An exercise profile of a user may be updated using the caloric expenditure

Robotic customer service agents may require verification of a human. The verification may be of the identity of the human and/or a capability of the human. If verified, the robot operates in a verified mode and otherwise operates in a non-verified mode. The robot performs a customer service task in one of the verified mode or the non-verified mode, which may alter, omit, or substitute actions as appropriate for the mode.

A method and device for evaluating muscle tension, the method comprising: obtaining the elastic modulus values of the measured skeletal muscle under different joint angles and each of the joint angles (S11); determining the changing trend of the elastic modulus value of the measured skeletal muscle according to the elastic modulus values of the measured skeletal muscle under different joint angles and each of the joint angles (S12); and evaluating the muscle tension level of the measured skeletal muscle according to the changing trend of the elastic modulus value of the measured skeletal muscle (S13). The method can be used to evaluate the muscle tension level.

An apparatus for testing and exercising pelvic floor musculature, the apparatus comprising an elongate housing adapted for a pelvic floor aperture. The housing accommodates an oscillator and an accelerometer connected to a signal processor configured for communicating signals representative of values read from the accelerometer. A result is calculated from an applied oscillation and a response measured, and used for characterizing the musculature. In one embodiment the frequency resulting in the greatest response from the musculature is measured, and this frequency is applied during exercise.

An electronic skin is manufactured by disposing an oxide thin film transistor (TFT), a pressure sensor, and a temperature sensor on a flexible substrate. The pressure sensor and the temperature sensor are respectively located on two sides of the flexible substrate. The oxide TFT includes a first TFT and a second TFT. The pressure sensor is configured to drive the first TFT, and the temperature sensor is configured to drive the second TFT. The method for preparing the electronic skin is to form an oxide TFT, a pressure sensor, and a temperature sensor by means of etching and deposition on a flexible substrate whose double sides are covered with conductive materials. The electronic skin provided in the present invention may simultaneously measure pressure and temperatures, and has a simple structure, a low working voltage, small power consumption, high sensitivity, and small interference between sensor signals.

An electronic skin is manufactured by disposing an oxide thin film transistor (TFT), a pressure sensor, and a temperature sensor on a flexible substrate. The pressure sensor and the temperature sensor are respectively located on two sides of the flexible substrate. The oxide TFT includes a first TFT and a second TFT. The pressure sensor is configured to drive the first TFT, and the temperature sensor is configured to drive the second TFT. The method for preparing the electronic skin is to form an oxide TFT, a pressure sensor, and a temperature sensor by means of etching and deposition on a flexible substrate whose double sides are covered with conductive materials. The electronic skin provided in the present invention may simultaneously measure pressure and temperatures, and has a simple structure, a low working voltage, small power consumption, high sensitivity, and small interference between sensor signals.

An electric training apparatus is configured to apply, by a load motor, a load on a rotating body configured to apply a load on an exercising person, detect an exercise physiological response value of the exercising person and a number of revolutions of the rotating body, perform control for gradually increasing the load of the load motor toward a set load upper limit value so that a detection result of the exercise physiological response value of the exercising person approaches a target exercise physiological response value set in advance, and change, before an exercise or during the exercise by the exercising person, the load upper limit value in response to a control command input based on a state of the exercising person, a state of the control, and a perceived exertion scale for the exercising person.

A probe system includes a finger-mountable housing having a distal end and a proximal receptacle end. The proximal receptacle end defines an opening to receive a finger. The probe system also includes a probe assembly disposed on or within the finger-mountable housing and having at least a first sensor. The first sensor is positioned to measure a physical characteristic of a first tissue when the finger-mountable housing and probe assembly are inserted in a rectum of the patient.