A system and method for controlling a monitoring mode or treatment mode of an implantable medical device based on the detection of an external signal. The system and related method allow for more frequent monitoring of medical parameters at times where more frequent monitoring is necessary, such as during or after a dialysis session, with less frequent monitoring at other times, allowing for a more efficient medical device. The invention also allows for the frequency or mode of treatment by the implantable medical device, or the transmission of data from the implantable medical device to be controlled based on the external signal.

This disclosure relates to systems, media, and methods for providing near-instantaneous feedback from real-time motion sensor data. In an embodiment, the system may perform operations including loading at least one target motion trigger. Disclosed embodiments may receive real-time sensor data from the first motion sensor detachably fixed to a user. Additionally, disclosed embodiments may include calculating a motion profile based on the real-time sensor data, the motion profile describing a multi-dimensional representation of acceleration of a motion performed by the user. Disclosed embodiments may also include comparing the at least one target motion trigger to the calculated motion profile to determine if the motion performed by the user corresponds to the target motion. Further, disclose embodiments may include transmitting, based on the comparison, an instruction to provide an alert to a user.

Athletic performance monitoring systems and methods, many of which utilize, in some manner, global positioning satellite (GPS) data, provide data and information to athletes and/or to equipment used by athletes during an athletic event. Such systems and methods may provide route information to athletes and/or their trainers, e.g., for pre-event planning, goal setting, and calibration purposes. Such systems and methods optionally may provide real time information to the athlete while the event takes place, e.g., to assist in reaching the pre-set goals. Additionally, data and information collected by such systems and methods may assist in post-event analysis for athletes and their trainers, e.g., to evaluate past performances and to assist in improving future performances.

The present disclosure is directed to a system for sensor-based objective determination. In general, sensor data may be used to render objective determinations that were not previously possible due to the unavoidable subjectivity of human-based officiating systems. For example, at least one device may be configured to make objective determinations during the course of a sporting event. Data collection circuitry may receive data from sensor devices coupled to players, equipment, playing surfaces, etc. Data analysis circuitry may categorize the data and input the data into a model to determine if an infraction occurred. For example, categorization may involve determining a type of infraction that may have occurred based on the sensor data. The model may then be selected based on the type of infraction, the model being developed utilizing prior sensor data, rules for the sporting event, etc. Output circuitry may generate a notification based on the infraction determination.

Systems, media and methods for an interactive speed ladder are provided. A system includes a speed ladder that has parallel side members and parallel cross members each connecting each of the side members. The system may further include a receiving module configured to receive light path sequence data and foot movement data of a user relative to the speed ladder, wherein the light path sequence data and the foot movement data are received from different sources. The system may also further include lights, located within the cross members, configured to display a light path sequence based upon sequence data received prior to a start of the sequence and an output module configured to output user foot movement data.

A portable shield made for individuals who practice boxing, martial arts, or any combat sport. The portable shield comprises a central striking area, a resilient neck-like striking area, a head-like striking area that are suitable for kicking and/or punching. The portable shield also comprises holding arms for steering the shield and a spring within the resilient neck-like striking area for allowing movement of the head-like striking area when it is stricken by a user/athlete. The head-like striking area, the resilient neck-like striking area and the central striking area are covered with padding material to prevent injuring the user/athlete when kicking and/or punching.

A multiplayer sports formation arrangement prompting method adapted to monitor, by a computing device, a formation of a plurality of athletes participating in a multiplayer sport to prompt each of the athletes to adjust a position is provided, in which at least two wind sensors and a positioning device are disposed on or around each of the athletes. In this method, relative positions of the athletes with respect to each other are detected by using the positioning device, a wind direction is detected by using the at least two wind sensors disposed on or around a first athlete of the athletes, a second athlete behind the first athlete is prompted to adjust the position to enter a low wind resistance zone according to the relative position of the first athlete with respect to the second athlete and the detected wind direction, and the second athlete is prompted to adjust a position within the low wind resistance zone based on values detected by the at least two wind sensors disposed on or around the second athlete.

Tracking and monitoring athletic activity offers individuals with additional motivation to continue such behavior. An individual may track his or her athletic activity by completing goals. These goals may be represented by real-world objects such as food items, landmarks, buildings, statues, other physical structures, toys and the like. Each object may correspond to an athletic activity goal and require an amount of athletic activity to complete the goal. For example, a donut goal object may correspond to an athletic activity goal of burning 350 calories. The user may progress from goal object to goal object. Goal objects may increase in difficulty (e.g., amount of athletic activity required) and might only be available for selection upon completing an immediately previous goal object, a number of goal objects, an amount of athletic activity and the like.

Aspects of the present disclosure provide methods, apparatuses, and systems for non-linear breathing entrainment. As described herein, breathing entrainment refers to guiding a user's breath or breathing. According to an aspect, an initial breathing period and a final breathing period are selected. Based on the initial and final breathing periods, a non-linear breath rate per minute sequence is determined. A guiding stimulus is output and aligned with the non-linear breath rate per minute sequence. The guiding stimulus is non-linearly altered with the non-linear breath rate per minute sequence to align with the final breathing period over an interval of time. The non-linear alterations of the guiding stimulus vary based on an amount of time the guiding stimulus has been output.

A portable apparatus includes an exercise-measurement circuitry that measures exercise-related measurement data related to a user carrying out an exercise, a communication circuitry configured to provide the portable apparatus with wireless communication capability, and a processing circuitry configured to a perform operations. The operations include receiving the exercise-related measurement data from the exercise-measurement circuitry, receiving configuration data from an external user interface apparatus over a bidirectional wireless communication connection established through the communication circuitry and capable of transferring payload data to both directions, processing the exercise-related measurement data according to the received exercise-related parameters in order to obtain advanced exercise-related data, and communicating the advanced exercise-related measurement data to the user interface apparatus over the bidirectional wireless communication connection.