An exercise feedback system monitors the performance of athletes wearing a garment with sensors while exercising. The sensors generate physiological data such as muscle activation data, heart rate data, or data describing the athlete's movement. The system extracts features from the physiological data and compares the features with reference exercise data to determine metrics of performance and biofeedback. Based on the physiological data, the system may also modify exercise training programs for the athlete. The exercise feedback system can display the biofeedback using visuals or audio, as well as modified exercise training programs, via the athlete's client device in real time while the athlete is exercising. By reviewing the biofeedback, the athlete may correct the athlete's exercise form to properly use the target muscles for the exercise, or change the certain workouts to personalize the training program.

A method performed in a computer-implemented platform includes obtaining sensor data from sensors embedded in a first grip and a second grip of an item of fitness equipment while a user exercises using the item of fitness equipment. The user interacts with the first grip and the second grip while exercising using the item of fitness equipment. The method also includes analyzing the sensor data to determine differences in performance between the left side of the user's body and the right side of the user's body and providing personalized activity for the user to compensate for the differences.

An athletic garment includes sensors at different locations of the garment. The sensors are electrically coupled to a processing unit and/or a power source via one or more conduits that are printed onto the garment. The conduits are designed for improved flexibility to accommodate stretching in the garment that occurs as a user wearing the garment performs an exercise and for improved durability to resist corrosion due to friction, sweat, or washing of the garment. In one embodiment, the conduits are designed for decreased stress concentrations at seams of the garment. In one embodiment, the conduits are designed to create a conductive pathway between different surfaces of the garment to electrically couple sensors on a first side (skin side) of the garment and a processing unit and/or a power source on a second side (outer side) of the garment.

The present disclosure is directed to a system for sensor-based objective determination. An example apparatus includes memory, instructions, and processor circuitry to execute the instructions to at least compare time-synchronization data between a first signal and a second signal, the first and second signals received in response to a detected contact between a first participant and a second participant in an event, wherein the first signal is received from a first sensor operably coupled to the first participant, the first sensor to measure at least one first physical parameter of the first participant while the first participant is engaged in the event, and wherein the second signal is received from a second sensor operably coupled to the second participant, the second sensor to measure at least one second physical parameter of the second participant while the second participant is engaged in the event, and determine, based on (a) the time-synchronization data, (b) the at least one first physical parameter, and (c) the at least one second physical parameter, whether the detected contact between the first participant and the second participant exceeds one or more thresholds corresponding to a rules-based infraction associated with the event.

An Internet of Thing (IoT) device includes a body with a processor, a camera and a wireless transceiver coupled to the processor.

Safe and effective exercise poses a specific set of challenges for subjects diagnosed with diabetes. These challenges include the coordination of exercise with blood glucose monitoring and insulin administration. Failure to coordinate these factors effectively can lead to various pathologies related to aberrant blood glucose levels. Presented herein are methods, systems, algorithms, computer program products, web portals, real-time live instruction, and computer-executable code for exercise guidance and instruction specific to diabetes relief and management. The systems as disclosed herein can help ameliorate, slow, or reduce a likelihood of developing a diabetic condition.

An apparatus includes a first cable, a first motor configured to provide first tension to the first cable, a second cable coupled to the first cable at an end effector, and a second motor configured to provide second tension to the second cable. The first cable and the second cable are routed such that the first tension and the second tension combine to provide a force on the end effector. At least one of the first tension or the second tension is directed at least partially in a downward direction.

During a personalized monitoring procedure facilitating safe and effective sport or rehabilitation activities, in the preparatory section user anamnesis and activity protocol data are recorded; at an idle phase, based on current heart rate measurement, we decide whether the activity can be continued; at a load phase, we monitor changes in physiological parameters, related to the physical activity, primarily the parameters that determine safe heart operation and, if necessary, provide a warning; in a regeneration phase, heart rate deceleration stage is monitored, heart rate variability parameters are calculated, and the result obtained is taken into account when monitoring in relation to the next training, while evaluating the idle phase. Related apparatus comprises a data processing unit connected to measuring electrodes and sensors and a display unit in wireless communication with the data processing unit. The latter is preferably a smartphone, while the data processing unit includes expert knowledge of the physiology of the monitored training that enables procedure execution.

A wireless power system for an exercise machine for providing electrical power wirelessly to an electrical energy storage device or electrical energy consuming device attached to a movable carriage of an exercise machine. The wireless power system for an exercise machine generally includes an exercise machine which includes a frame having one or more rails. A carriage is movably positioned upon the rails to allow an exerciser to move the carriage when performing an exercise. A wireless power receiver is attached to the carriage that wirelessly receives electrical energy transferred from a wireless power transmitter. An electrical energy storage device or an electrical energy consuming device attached to the movable carriage is electrically connected to the wireless power receiver to receive electrical power from the wireless power receiver.

A head guard is provided. The head guard includes one or more sensors as part of an sensory input and communications system. The head guard wirelessly communicates data to remote computing devices for intelligent data collection.