Devices that take a novel approach to parameter measurement and output or transmission of signals, medicine, heat, etc. These devices are compact, versatile, relatively inexpensive, and require minimal training to be effectively used. These devices can be configured as interchangeable devices incorporated into a wearable article or device.

The smart wearable with embedded NFC (Near Field Communication) tags, vital health sensors and UV-C germicidal irradiation sources is provided for Prevention of spread of pathogens. The smart wearables is any of a hand glove, a footwear, a vest, a full body suit, a face mask, a footwear cover or a smart portables where all the smart wearables includes a plurality of re-programmable tags to facilitate touch less activities, and a plurality of body health monitoring sensors to monitor health of the wearer in real time for early warning health mechanisms, an Ultraviolet Germicidal Irradiation (UVGI) source to disinfect the surfaces coming in contact with the smart wearables with maximum efficacy and spread prevention. Further, the inner layer of the smart wearables which makes contact with the skin of the wearer is made of a Celliant synthetic polymer fabric material that traps the body's infrared energy and cycle it back to improve oxygenation and resolve minor aches and pains.

The present invention is disclosing a performance improvement system comprising a smart athletic flexible accessory and an electronic device communicably coupled with smart athletic flexible accessory. Smart athletic flexible accessory comprises a plurality of fabric sensors configured to measure data associated with a physical activity performed by a user and a first transceiver configured to transmit measured data. Electronic device comprises a second transceiver configured to receive measured data from smart athletic flexible accessory, and a microprocessor. Microprocessor is configured to analyze received data from receiver, generate a recommendation based on analyzed data, and cause a display screen to display generated recommendation.

A grippable haptic device includes an input device that receives a user input, a 9-axis sensor that detects movement of a hand of the user, a vibrator that provides a tactile sensation to the user, and a motion sensor that detects whether the user grips the grippable haptic device. An insole-type haptic device includes an input device that receives a user input, a plurality of 9-axis sensors that detect movement of a foot of the user, a vibrator that provides a tactile sensation to a sole of the foot of the user, and a plurality of pressure sensors that are distributed across the insole-type haptic device and measure a pressure exerted at each position of the sole of the user.

An Internet of Thing (IoT) device includes a camera coupled to a processor; and a wireless transceiver coupled to the processor. Blockchain smart contracts can be used with the device to facilitate secure operation.

A method includes determining that a portion of a force applied to a sensor system was applied to a non-inclusive region of the sensor system. An activation area of the non-inclusive region may be determined. A force distribution of the non-inclusive region may be determined. A corresponding force measurement of the non-inclusive region based on the activation area and the force distribution may be calculated.

A blood pressure detection method is provided. The method comprising: obtaining wrist circumference data, wrist fat thickness data, and blood pressure data and correcting the blood pressure data based on the wrist circumference data and the wrist fat thickness data.

The invention moves the wearable device to the area between the thumb and first finger attached or imbedded into the glove to allow immediate access and in just the correct viewing area and angle to allow the user to use without distraction. The options would allow for both a device to be attached like a traditional watch strap or in a specifically designed holder for the specific wearable device. By imbedding the device can allow for contact with the skin therefore enabling sensors to work effectively. This precise location enables gloves for all activities like Biking, Skiing, Workout, CrossFit, Bowling, Golfing, Swimming, Climbing, Baseball, Hockey, Driving, Work Gloves, Etc. to be manufactured with this capability supporting a better way to both use and interact with these wearable devices.

A fixed-sensor finger action detecting glove has a glove body, five covering sheets, five fixing bases, five sensors, and five fixing assemblies. A side of the glove body forms a hand back section and five finger back sections. The covering sheet is mounted on the finger back section and forms a passage. The fixing base is made from a flexible material, is mounted through the passage, and has two limiting walls. The sensor is located in the passage between the two limiting walls, preventing the sensor from deviating. The fixing assembly is mounted between an end of the sensor and an end of the finger back section, detachably connects the sensor and the finger back section, and prevents the sensor from moving back and forth. Thus, the fixed-sensor finger action detecting glove is capable of detecting actions of the fingers precisely.

The present disclosure provides a finger joint rehabilitation training device, which includes a control member, a data acquisition member, a gas circuit system, and a wearable training member. The wearable training member is provided with a pneumatic component that can expand and contract. The data acquisition member is configured for acquiring hand motion information of a first hand and transmitting the hand motion information to the control member. The hand motion information includes hand pressing information. The control member controls the gas circuit system to inflate the pneumatic component or to draw air from the pneumatic component according to the hand motion information, to make the wearable training member change between a flexion condition and a stretching condition, so as to realize a hand mirror training of a second hand. The hand pressing information is simple and convenient to acquire, which is convenient for the first hand to realize the flexion condition and the stretching condition, and the condition of the second hand is adjusted through the condition of the first hand, so that the wearable training member can be better adjusted, different hand training intensity requirements are met, and a better training effect is achieved.