A method of providing feedback for a piece of cue-sport equipment, a cue ball or cue stick, during a game play first collect spatial positioning and orientation data from a plurality of measurement sensors that is integrated into the cue-sport equipment. Then, the collected data is analyzed to generate a virtual movement model of the cue-sport equipment as the virtual movement model includes a calculated impact force diagram, an animated travel path, and a calculated absolute orientation for the cue-sport equipment. Then, the player can view the virtual movement model through an external computing device to improve their cue-sport skills effectively and efficiently.

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

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

The present invention relates to a power measuring device capable of obtaining accurate measurement values corresponding to changes in the state or environment of a target to be struck, and in variable striking conditions, such as being struck in a state in which movement of the target occurs, and the like. To this end, the present invention includes an air pocket group (11g) configured such that air pockets (11) are respectively formed in regions leading to a score according to striking in a target when the power measuring device (10) corresponding to variable striking conditions is installed on a target used in a fighting exercise; a piping tubes (12) formed to transmit pressure to a pressure sensor (13a) on the other side according to a change in volume on the air pocket (11) to increase the efficiency of score determination, by measuring a power at the time of strike by determining a strength (power) of the strike with an impulsive force applied to the air pocket (11); and a check valve (12a) formed in each piping tube (12) connecting each air pocket (11) at a front end of the pressure sensor (13a) to prevent air discharged when the air pocket (11) corresponding to a target point is struck from flowing to another air pocket (11) through the piping tube (12) connected to the pressure sensor (13a).

A medical examination, treatment, or examination and treatment device is provided. The medical examination, treatment, or examination and treatment device includes a cover panel. The cover panel includes a sensor for detecting a collision. The sensor includes a first plate mounted on the examination, treatment, or examination and treatment device, and a second plate mounted on the inside of the cover panel and spaced apart from the first plate. Spring elements are disposed between the first plate and the second plate.

An electronic device that enables identification of application of an impact is provided. The electronic device includes a module case including a first structure and a second structure having different deformation quantities, a first impact identification part formed between the first structure and the second structure and configured to generate a deformation according to the difference between the deformation quantities of the first and second structures at the time of applying the impact, and a second impact identification part that enables identification of whether the impact was applied based on the deformation of the first impact identification part.

A sensor device includes: a detection device that detects a predetermined physical quantity and converts the physical quantity into a detection signal; a communication device that is to be connected to a controller through a first line and a second line, performs at least one of reception from the controller or transmission to the controller by a differential transmission method and, based on a request signal received from the controller, transmits the detection signal generated by the detection device; and a conductive shield member that is applied with a constant potential and covers the detection device and the communication device. The conductive shield member reduces radiation noise generation and simplifies the sensor device structure.

An impact detection methodology is disclosed. Systems and methods can be utilized to detect impacts of concern such as collisions, falls, or other incidents. Systems and methods can be utilized to monitor an area and detect falls or collisions of an individual, for instance, as may require intervention to aid the subject. A system can include two or more accelerometers and a controller. The accelerometers can be in communication with the structure (e.g., within or on the walls or floor of a structure) and can monitor the structure for vibrations. The accelerometers can be coupled to a controller that is configured to process data obtained from the accelerometers and provide output with regard to the force and/or location of an impact within the structure.

The present invention generally relates to a system and method for the precise measurement of acceleration, movement, and other forces imparted on a body or object. Specifically, the invention relates to a system and method for measuring head accelerations in helmeted activities including, but not limited to, football, ice hockey, and lacrosse. Certain embodiments of the invention may include a wireless link to a remote recording station with near real-time data analysis and reporting of force and kinetics measured by the system.

The present invention discloses a diode array-based digitized miniature ultra-low-power-consumption impact monitoring system, which belongs to the technical field of aircraft structural health monitoring. The impact monitoring system consists of a miniature sensor array interface, a passive band-pass filter array, a diode array, a digital conversion and management module, an on-board bus communication module, a monitoring data storage module, a self-powering module, and a miniature communication and power supply interface. According to the impact monitoring system, the amplitudes of impact response signals are controlled within a clamp voltage range of diodes by using the diode array, thereby realizing the first-stage digitization; and the second-stage digitization of the impact response signals is realized by using the digital conversion and management module consisting of a miniature field programmable gate array of ultra-low-power-consumption. The impact monitoring system can realize on-line, real-time and uninterrupted impact monitoring on large-scale aircraft structures, thereby improving the safety and maintenance efficiency of the aircraft structures.