Abstract: A sports simulation system comprises a projectile tracking apparatus configured to detect a projectile traveling through a projectile tracking region towards a display surface, a controller comprising one or more actuatable buttons, each actuatable button configured to communicate one or more control signals in response to actuation thereof, and at least one processing stage configured to receive data from the projectile tracking apparatus and determine three-dimensional positions, velocity and acceleration of a detected launched projectile traveling through said projectile tracking region, the three-dimensional positions, velocity and acceleration used by said at least one processing stage to calculate a trajectory of said launched projectile into a three-dimensional sports scene, receive one or more control signals from the controller and determine one or more control commands of one or more animated objects based on the one or more control signals, and use said calculated trajectory and said one or more co

Abstract: A golf simulation system includes a processor configured to receive image data from a launch area sensing unit to determine position, velocity, acceleration and spin of a golf ball and to calculate a trajectory of the golf ball into a golf scene presented on a display surface. The system includes a processor that generates a profile of a golf ball travel path over a plurality of images, determines the golf ball travel path length per image of the plurality of images, identifies regions corresponding to one or more markings on the golf ball, determines the distance between the regions in each image, calculates the spin rate and tilt of the golf ball using the determined distance, and uses the golf ball travel path length and camera device frame rate to estimate a spin tilt axis of the golf ball using the orientation of the regions in each image and the relative angle between the longitudinal axis of the regions and the longitudinal axis of the golf ball travel path.

Abstract: A method and computing device for detecting and outputting notable moments of a performance. The method may be executable by a processor. The method may include receiving, by a processor, an input video stream of a performance. The method may further include determining, by the processor, a notable moment within the input video stream, the notable moment including an amount of motion greater than a threshold value. The method may also include generating, by the processor, a video clip including the determined notable moment, a portion of the input video stream preceding the determined notable moment, and a portion of the input video stream following the determined notable moment. The method may additionally include outputting, by the processor, the video clip.

Abstract: A monitoring device with a pedometer function preferably comprises an article, an optical sensor, an accelerometer and processor. The optical sensor preferably comprises a photodetector and a plurality of light emitting diodes. A sensor signal from the optical sensor is processed with a filtered accelerometer output signal from the accelerometer to generate a pedometer function.

Abstract: A method for synchronizing multiple data feeds includes receiving a first data feed including user-entered textual data and audio segments acquired concurrently with the user-entered textual data from a first device, receiving an additional data feed including audio segments acquired with the additional device, the first data feed and the additional data feed acquired from a common sporting event, identifying one or more distinctive audio events in the one or more audio segments received from the first device and the additional device, determining a timing offset between the first data feed and the additional data feed by comparing the one or more distinctive audio events of the one or more audio segments received from the first device and the additional device and generating a synchronized output feed by establishing a common absolute time for the first data feed and the additional data feed based on the determined timing offset.

Abstract: A mobile plethysmographic device for detecting a Peripheral Artery Disease (“PAD”) event or other arrhythmia event is disclosed herein. The mobile plethysmographic device generates a pleth waveform, which is automatically screened by algorithms that measure the waveform to correlate, detect and store aberrations related to heart anomalies. A peripheral artery disease event for a patient is determined based on a quantative measure of blood flow in the extremities based on the differential in amplitude in the pleth signal between the arm and the two lower extremities. The changes in amplitude from the arm and one or both lower extremities can indicate PAD.

Abstract: A golf simulation system includes imaging devices capturing images of a projectile tracking region in front of a display surface from different vantages to detect a launched projectile traveling through the projectile tracking region towards the display surface. A projectile spin sensing unit captures images of a region at least partially overlapping with the projectile tracking region, and each captured image includes a projectile trail representing a travel path of the projectile. A processing stage receives data from the imaging devices and the projectile spin sensing unit and determines the three-dimensional positions, velocity, acceleration and spin of the projectile, and the three-dimensional positions, velocity, acceleration and spin are used by the processing stage to calculate a trajectory of the launched projectile into a presented golf scene.

Abstract: A mobile plethysmographic device for detecting a premature ventricular contraction event is disclosed herein. The mobile plethysmographic device generates a pleth waveform, which is automatically screened by algorithms that measure the waveform to correlate, detect and store aberrations related to heart anomalies. A premature ventricular contraction event for a patient is determined based on an identification of a time interval of the pleth waveform that is below the threshold minimum time interval followed immediately by a time interval that is above the threshold maximum tine interval.

Abstract: A method for synchronizing multiple data feeds includes receiving a first data feed including user-entered textual data and audio segments acquired concurrently with the user-entered textual data from a first device, receiving an additional data feed including audio segments acquired with the additional device, the first data feed and the additional data feed acquired from a common sporting event, identifying one or more distinctive audio events in the one or more audio segments received from the first device and the additional device, determining a timing offset between the first data feed and the additional data feed by comparing the one or more distinctive audio events of the one or more audio segments received from the first device and the additional device and generating a synchronized output feed by establishing a common absolute time for the first data feed and the additional data feed based on the determined timing offset.

Abstract: A monitoring device with a pedometer is disclosed herein. The monitoring device preferably comprises an article, an optical sensor, an accelerometer and processor. The optical sensor preferably comprises a photodetector and a plurality of light emitting diodes. A sensor signal from the optical sensor is processed with a filtered accelerometer output signal from the accelerometer to generate a pedometer function.

Abstract: A monitoring device (20) and method (200) for monitoring the health of a user is disclosed herein. The monitoring device (20) is preferably an article (25), an optical sensor (30), a circuitry assembly (35) a display member (40) and a control component (43). The monitoring device (20) preferably displays the following information about the user: pulse rate; calories expended by the user of a pre-set time period; target zones of activity; time; and distance traveled.

Abstract: A sports simulation system includes a projectile tracker having a display presenting a three-dimensional sports scene. The projectile tracker captures images of a projectile tracking region disposed in front of the display to detect a launched projectile traveling through the tracking region towards the display. A processing stage, in communication with the projectile tracker, is responsive to data received from camera devices to determine three-dimensional positions, velocity, acceleration and spin of a detected projectile traveling through the tracking region, which are used by the processing stage to calculate a trajectory of the launched projectile into the three-dimensional sports scene.

Abstract: A monitoring device with a pedometer is disclosed herein. The monitoring device preferably comprises an article, an optical sensor, an accelerometer and processor. The optical sensor preferably comprises a photodetector and a plurality of light emitting diodes. A sensor signal from the optical sensor is processed with a filtered accelerometer output signal from the accelerometer to generate a pedometer function.

Abstract: A mobile plethysmographic device for detecting a premature ventricular contraction event is disclosed herein. The mobile plethysmographic device generates a pleth waveform, which is automatically screened by algorithms that measure the waveform to correlate, detect and store aberrations related to heart anomalies. A premature ventricular contraction event for a patient is determined based on an identification of a time interval of the pleth waveform that is below the threshold minimum time interval followed immediately by a time interval that is above the threshold maximum time interval.

Abstract: The subject matter of this specification can be embodied in, among other things, a computer-implemented athletic performance analysis method that includes obtaining, at a computer system, first motion data reflecting motion of a sporting device during one or more drills performed by an athlete. The method also includes creating and storing action data by identifying a plurality of portions of the motion data, where each of the portions correspond to one or more actions by the athlete; comparing the action data for the athlete, with the computer system, to corresponding aggregated action data for a plurality of other athletes to determine a relative skill level for the athlete with respect to the one or more actions; and generating data for a report that reflects the relative development level of the athlete.

Abstract: An optical sensor for a monitoring device for monitoring the vital signs of a user is disclosed herein. The optical sensor preferably includes a photodetector and a two light emitting diodes (“LEDs”) that emit green light. The optical sensor includes a light barrier that includes multiple walls that block any non-reflected light from the LEDs from transmission to the photodetector so that the photodetector only receives light reflected from the artery of the user resulting in a more accurate detection of the heart rate of the user. A sensor signal from the optical sensor is processed with an accelerometer output signal from the accelerometer to generate a real-time vital sign for a user.

Abstract: A sports simulation system (100) comprises at least two imaging devices (128) capturing images of a projectile tracking region disposed in front of a display surface (124) from different vantages to detect a launched projectile traveling through the projectile tracking region towards the display surface; a projectile spin sensing unit (105) capturing images of a region at least partially overlapping with the projectile tracking region, each captured image comprising a projectile trail representing a travel path of the projectile when a projectile is present in the region during image capture; and at least one processing stage (104) receiving data from the imaging devices (128) and the projectile spin sensing unit (105) and determining the three-dimensional positions, velocity, acceleration and spin of a detected launched projectile traveling through the projectile tracking region, the three-dimensional positions, velocity, acceleration and spin being used by the at least one processing stage to calculate a tr

Abstract: A mobile plethysmographic device for detecting a premature ventricular contraction event is disclosed herein. The mobile plethysmographic device generates a pleth waveform, which is automatically screened by algorithms that measure the waveform to correlate, detect and store aberrations related to heart anomalies. A premature ventricular contraction event for a patient is determined based on an identification of a time interval of the pleth waveform that is below the threshold minimum time interval followed immediately by a time interval that is above the threshold maximum tine interval.

Abstract: A method and system for continuous, mobile, ambulatory diagnostic monitoring for heart rate disease and abnormal conditions is disclosed herein. This device overcomes the prior art problems and allows for a continuous heart rate to be collected and recorded for extended time frames equivalent to a Holter monitor or special pulse oximeter.

Abstract: A method and system to monitor a prisoner in a prison is disclosed herein. The prisoner's vital signs are monitored and the movement of the prisoner. The monitoring device measures real-time data for the at least one vital sign of the prisoner, calculates at least a real-time heart rate data, and transmits the real-time heart rate data to the receiving device for display on the display screen.