Athletic performance monitoring and tracking may provide multiple ways in which to track athletic movement and activity. In one example, an athletic monitoring device may include or be associated with multiple types of movement sensors and switch between the sensors or use both depending on various factors including type of workout. Workouts may also be tagged with various parameters including mood, weather, terrain, athletic equipment used and the like. In one or more examples, the parameters may be automatically determined based on location. User workouts and accomplishments may also be celebrated through messages from celebrities, family, friends and other users. In some cases, the messages may be triggered by various conditions. Coaching may also be provided to the user to help improve workouts and overall athletic performance. Running routes may also be automatically tracked, stored and shared.
A portable apparatus (10) providing both substantially automated performance monitoring and audio entertainment features. In a preferred embodiment the apparatus (10) broadly comprises a portable housing (12); an attachment mechanism (14); a GPS component (16); a heart rate monitor component (17); an audio component (18); a user interface (20); a processor (26); and a power supply (30). The housing (12) may include a headset (1112a) wherein the GPS component (16) is located, and a second housing component (1112b) wherein the processor (26) is located, wherein the GPS component (16) communicates with the processor (26) in a wireless manner. The apparatus (10) is adapted to determine a number of laps or a distance, to provide an elapsed time, and to determine a speed.
A network performancemonitoring system uses a plurality of user modules, each user operating on a unique usermachine coupled to one or more provider servers and an experience test server for collecting data from the plurality of user modules. The collected data includes at least one performance datum relating to user experience with a link from the user machine to the provider server. The system also cleanses the collected data to account for variable user configurations, user errors and the like.
Performance measurements for a network, such as delay, delay variation, and loss, are performed over layer-2. A PM frame is sent from a source MEP (Maintenance End Point) to a destination MEP. The PM frame is timestamped immediately prior to transmission, and the local clock at the destination MEP is noted immediately upon arrival. MIPs (Maintenance Intermediate Points) may also time stamp the PM frame. Preferably, each PM frame has an interval (session) identifier and a sequence number within the interval. The PM frames are received by and sent by PM modules within the nodes of the network. The PM modules include a Sender function for sending an interval of one or more PM frames and a Receiver function for receiving PM frames and computing measurements.
A quality assurance benchmark system tests a target executable application under load stress conditions over an extended period of time. The system has user-controlled parameters to benchmark performance, scalability, and regression testing before deploying the application to customers. The system includes a display processor and a test unit. The display processor generates data representing a display image enabling a user to select: input parameters to be provided to the target executable application, and output data items to be received from the target executable application and associated expected range values of the data items. The test unit provides multiple concurrently operating executable procedures for interfacing with the target executable application to provide the input parameters to the target executable application, and to determine whether data items received from the target executable application are within corresponding associated expected range values of the data items.
A method and system for optimizing routing traffic to a destination when multiple routes are available. A performance monitoring and inference component measures the performance of the available paths to a large set of subnetworks, and uses those measurements to infer the performance of all available paths to an even larger set of subnetworks. A routing optimization component uses a cost function that assigns a cost to a routing table based on information from the performance monitoring and inference component, as well as other path characteristics, and further uses a minimization methodology to find a routing table with a very low cost, as defined by the cost function. A BGP bridge takes the routing table generated by the routing optimization component and communicates that information to the routers using BGP, thereby ensuring that the routers will route traffic in accordance with the routing table.