Systems and methods for identifying a condition of a user. A treatment apparatus is configured to be manipulated by the user for performing an exercise, and an interface is communicably coupled to the treatment apparatus. One or more sensors are configured to sense one or more characteristics of an anatomical structure of the user. A processing device and a memory is communicatively coupled to the processing device. The memory includes computer readable instructions, that when executed by the processing device, cause the processing device to: receive, from the sensors, one or more sensor inputs representative of the one or more of characteristics of the anatomical structures; calculate an infection probability of a disease based on the one or more characteristics of the anatomical structures; and output, to the interface, a representation of the infection probability.

A mobile apparatus is adapted to be handheld and configured for electronic processing of blood sugar affecting factors includes a first central processing unit arranged for processing of patient critical information objects, at least one memory comprising a plurality of in advance stored food units and values of at least one related blood sugar affecting parameter, an input unit arranged to provide user input such as a choice of food units and an amount thereof, a display arranged for visualization of food units for said user input, and for visualization of summed up blood sugar affecting parameters, and a second central processing unit arranged for processing of patient non-critical information objects.

A movement tracking device that includes a housing, a rotatable spool secured within the housing, a rotary sensor in operable communication with the spool, and a conductive wire configured to be repeatedly unspooled from and respooled onto the rotatable spool. The conductive wire has a distal end extendable from the housing. The movement tracking device also includes a plurality of resonators and a processor in communication with the plurality of resonators and the rotary sensor. The plurality of resonators are disposed in or on the housing and positioned about the conductive wire. Each of the plurality of resonators is configured to create one or more magnetic fields through which the conductive wire extends. The processor is configured to receive information from the plurality of resonators and the rotary sensor and determine a position of the conductive wire.

A weight training method, a weight training apparatus and a weight training system are provided. In the method, a weight of a load of a user operating the weight training apparatus is detected by a load sensor, a motion of the load is detected by an activity sensor, and thereby an operation power of the weight training apparatus is calculated. A force applied by the muscle portion when the user operates the weight training apparatus is detected by at least one biophysical quantity sensor disposed on at least one muscle portion of the user and used to calculate an energy power consumed by the user. An exercise efficiency value of the user is calculated by using the energy power and the operation power, and the user is prompted to adjust an operation performed on the weight training apparatus when the exercise efficiency value drops beyond a preset ratio.

A wheel frame (16a) includes a cylindrical hub (16c) into which an axle (11b) is rotatably inserted, a six-axis force sensor (16e) having an insertion hole (16e1) into which the hub (16c) is inserted, and an outer flange (16f) extending radially outward from an input section (16e2) of the six-axis force sensor (16e), wherein a hand rim (17) is attached to the outer flange (16f).

Disclosed is an ankle ergometer for measuring a force exerted on a user's ankle joint by muscles involved in ankle mobility, including: a first splint-type portion receiving the lower limb when the user's knee is extended, and including a lower limb immobilizer with the leg in extension, and a second portion including: a) a main body attached to the first portion, b) a counter-supporting unit secured to the main body, c) a rigid plate forming a supporting surface for the lower surface of the foot, the rigid plate being substantially static relative to the counter-supporting unit, d) a force sensor between the plate and the counter-supporting unit, the plate not being secured to the main body so the sensor measures the force exerted on the supporting surface of the plate by the ankle mobility muscles, the force being transmitted from the plate to the counter-supporting unit.

Display and output are performed in such a manner as to allow complex body motions to be comprehended instantaneously. There are provided: a plurality of body motion sensors 40 which are worn on a wearer's 1 parts subject to cyclic motions and which are capable of measuring three-dimensional displacements and accelerations at the respective parts; a memory 114 which records detection results as body motion data; a cycle extraction unit 170c which extracts a cyclic motion of each of the body motion sensors 40 on the basis of accumulated body motion data; an analysis unit 170d which analyzes the characteristic of a change in angular velocity in the extracted cyclic motion; and displays 100a, 100b that display or output the characteristic analyzed by the analysis unit 170d in association with the rotation angle of the cyclic motion extracted by the cycle extraction unit 170c.

Presented is an Isokinetic exercise system having a base, a pedestal, a vertical member, a height adjustable vertical column for resting a rotary actuator on top, a resistance control valve unit with rotatable dials connected to the actuator, wherein the rotatable dials are selectively used to rotatably set a range of resistances for opposing movements to accommodate varying exerted forces by a user performing an intended exercise. The system further includes an electronics module to detect angle and pressure related data (as a measure of voltages) associated with the actuator, an A to D converter to convert the detected voltages in a digital form, a display unit embodying a program product for receiving, and processing the detected voltages to generate and display a muscular performance assessment report, store the received voltages for future comparison and enable printing the muscular performance assessment report, enable configuring next intended exercise.

A system configured to provide feedback to a user in order to motivate said user to reach one or more energy expenditure goals. The one or more energy expenditure goals may be associated with one or more of time periods, or activity sessions, and the feedback may be provided to a user using one or more of a visual display on a sensor device worn by a user, and/or using audible and haptic feedback.

A system for rehabilitation is disclosed. The system for rehabilitation includes a monitoring device comprising a memory device storing instructions and a network interface card, wherein the monitoring device is configured to detect information from a body part of a user. The system for rehabilitation further includes one or more processing devices operatively coupled to the monitoring device. The one or more processing devices are configured to execute the instructions to receive configuration information specified in a treatment plan for rehabilitating the body part of the user. The one or more processing devices are configured to execute the instructions for receiving the information from the monitoring device. The one or more processing devices are further configured to execute the instructions to transmit the configuration information and the information to a computing device controlling an electromechanical device, via the network interface card.