Abstract: A receiver apparatus is configured to receive a first and second signal from one or more sensors, the first signal comprising a measure of one or more exercise parameters of the user at a first time period of an exercise session, and the second signal comprising a measure of the one or more exercise parameters at a second time period. A processor is configured to store the first and second signals in a memory, generate a fatigue signal based on a comparison of the measured one or more exercise parameters of the first signal to the respective measured one or more exercise parameters of the second signal, generate an exercise efficiency signal based on a comparison of the measured one or more exercise parameters of the second signal to an a priori exercise parameter threshold, and cause the exercise efficiency signal and the fatigue signal to be simultaneously displayed.

Abstract: A method of operating a fitness tracking system includes generating movement data corresponding to movement of a user, sampling the generated movement data at a first sampling rate as first sampled data when operating the fitness tracking system in an activity detection mode, and sampling the generated movement data at a second sampling rate as second sampled data when operating the fitness tracking system in a workout mode. The second sampling rate is greater than the first sampling rate.

Abstract: A method of operating a fitness tracking system includes generating movement data corresponding to movement of a user, sampling the generated movement data at a first sampling rate as first sampled data when operating the fitness tracking system in an activity detection mode, and sampling the generated movement data at a second sampling rate as second sampled data when operating the fitness tracking system in a workout mode. The second sampling rate is greater than the first sampling rate.

Abstract: A physiological monitoring system includes a first handheld computing device, a second handheld computing device, and a biometric sensor device provided on an article of apparel. A method of operating the physiological monitoring system comprises receiving, at the second handheld computing device, user physiological data transmitted from the biometric sensor device, the second handheld computing device configured for wireless communication with the biometric sensor device and the first handheld computing device according to a communications protocol in a device network. The method further comprises operating the second handheld computing device in a first mode wherein the second handheld computing device operates as a slave controlled by the first handheld computing device in the device network. The method also comprises operating the second handheld computing device in a second mode wherein the second handheld computing device operates independent of the first handheld computing device in the device network.

Abstract: A shoe is provided for use by a user and for use with a communication device that transmits a physiological signal based on a detected physiological parameter of the user. The shoe includes a sole, a force actuating mechanism, a receiver and a controller. The sole has a top surface for supporting the foot of the user when being worn by the user. The force actuating mechanism provides a force to the top surface of the sole and is disposed at the sole so as to provide the force to a plantar venous plexus of the foot. The receiver receives the physiological parameter signal. The controller generates a control signal to control the force actuating mechanism. The controller further modifies the control signal based on the received physiological parameter signal.

Abstract: An aspect of the present invention is drawn to a patch for use with application against the skin of a user. The patch includes a substrate, a material detector, a memory, a comparator, an output component, and a power source. The material detector is disposed on the substrate and has a contact portion disposed so as to contact the skin. The material detector generates a material signal based on the amount of material contacting the contact portion. The memory has a priori material data stored within. The comparator outputs a compared signal based on the comparison of the material signal and the a priori material data. The output component outputs a readiness signal based on the compared signal and the a priori data. The power source provides power to the output component.

Abstract: A physiological monitoring system includes a first handheld computing device, a second handheld computing device, and a biometric sensor device provided on an article of apparel. A method of operating the physiological monitoring system comprises receiving, at the second handheld computing device, user physiological data transmitted from the biometric sensor device, the second handheld computing device configured for wireless communication with the biometric sensor device and the first handheld computing device according to a communications protocol in a device network. The method further comprises operating the second handheld computing device in a first mode wherein the second handheld computing device operates as a slave controlled by the first handheld computing device in the device network. The method also comprises operating the second handheld computing device in a second mode wherein the second handheld computing device operates independent of the first handheld computing device in the device network.

Abstract: A garment comprising a sensor, a body portion, a receptacle provided on the body portion, and an electronics module positioned in the receptacle. The receptacle comprises a receptacle housing, a sensor lead, and a receptacle contact. The receptacle housing forms a socket including a back wall and at least one sidewall. The sensor lead abuts the receptacle contact and is retained within a channel extending through the at least one sidewall. The receptacle contact includes a contact surface exposed to the socket with the contact surface oriented substantially perpendicular to the back wall of the socket. The electronics module is releasably positioned within the socket and includes at least one module contact. The at least one module contact abuts the receptacle contact and is electrically connected to the sensor lead when the electronics module is positioned within the socket.

Abstract: A method of monitoring biometric data for an individual includes detecting that the individual has moved within a predetermined range of a fixed display device. The method further includes wirelessly receiving a sensed biometric parameter of the individual at a receiver associated with the fixed display device. After determining that the individual has moved within the predetermined range and that the sensed biometric parameter is an authorized parameter for display based on a user profile of the individual, the sensed biometric parameter is displayed on the fixed display device. The method further includes detecting that the individual has moved outside of the predetermined range, and removing the sensed biometric parameter from the fixed display device.

Abstract: A method of operating a fitness tracking system includes generating movement data corresponding to movement of a user, sampling the generated movement data at a first sampling rate as first sampled data when operating the fitness tracking system in an activity detection mode, and sampling the generated movement data at a second sampling rate as second sampled data when operating the fitness tracking system in a workout mode. The second sampling rate is greater than the first sampling rate.

Abstract: Techniques are provided for displaying exercise information to an individual, including, for example, an exercise readiness indication. A display device receives information of a physiological measurement of a user. The display device determines if the physiological measurement falls within a predetermined range of values. The display device then displays to the user an exercise readiness indication that represents a readiness state of the user to participate in an exercise activity based on the physiological measurement.

Abstract: A shoe is provided for use by a user and for use with an external reset system that is operable to transmit a reset signal. The shoe comprises a sole, a detector, a memory, a controller, and a receiver. The sole has a top surface for supporting the foot of the user when being worn by the user. The detector generates a parameter signal based on a detected parameter. The controller generates a control signal to activate said detector. The controller further generates a modification signal based on the received reset signal. The memory stores parameter data based on the parameter signal. The memory further modifies the stored parameter data based on the modification signal. The receiver receives the reset signal.

Abstract: A shoe is provided for use by a user and for use with a communication device that transmits a physiological signal based on a detected physiological parameter of the user. The shoe includes a sole, a force actuating mechanism, a receiver and a controller. The sole has a top surface for supporting the foot of the user when being worn by the user. The force actuating mechanism provides a force to the top surface of the sole and is disposed at the sole so as to provide the force to a plantar venous plexus of the foot. The receiver receives the physiological parameter signal. The controller generates a control signal to control the force actuating mechanism. The controller further modifies the control signal based on the received physiological parameter signal.

Abstract: A shoe is provided for use by a user and for use with a communication device that transmits a blood pressure signal based on a detected blood pressure of the user. The shoe includes a sole, a force actuating mechanism, a receiver and a controller. The sole has a top surface for supporting the foot of the user when being worn by the user. The force actuating mechanism provides a force normal to the top surface of the sole and is disposed at the sole so as to provide the force to a plantar venous plexus of the foot. The receiver receives the blood pressure signal. The controller generates a control signal to control the force actuating mechanism. The controller further modifies the control signal based on the received blood pressure signal.

Abstract: A receiver apparatus is configured to receive a first and second signal from one or more sensors, the first signal comprising a measure of one or more exercise parameters of the user at a first time period of an exercise session, and the second signal comprising a measure of the one or more exercise parameters at a second time period. A processor is configured to store the first and second signals in a memory, generate a fatigue signal based on a comparison of the measured one or more exercise parameters of the first signal to the respective measured one or more exercise parameters of the second signal, generate an exercise efficiency signal based on a comparison of the measured one or more exercise parameters of the second signal to an a priori exercise parameter threshold, and cause the exercise efficiency signal and the fatigue signal to be simultaneously displayed.

Abstract: A shoe pod includes a positioning component and an altimeter. The positioning component determines geodetic locations of the shoe, whereas the altimeter determines elevations of the shoe. A golf club pod is disposed at the golf club and includes a golf club parameter detector operable to be detachably fastened to the golf club, to detect a golf club head striking surface position and to transmit the detected club parameter signal based on the detected golf club parameter.

Abstract: A garment comprising a sensor, a body portion, a receptacle provided on the body portion, and an electronics module positioned in the receptacle. The receptacle comprises a receptacle housing, a sensor lead, and a receptacle contact. The receptacle housing forms a socket including a back wall and at least one sidewall. The sensor lead abuts the receptacle contact and is retained within a channel extending through the at least one sidewall. The receptacle contact includes a contact surface exposed to the socket with the contact surface oriented substantially perpendicular to the back wall of the socket. The electronics module is releasably positioned within the socket and includes at least one module contact. The at least one module contact abuts the receptacle contact and is electrically connected to the sensor lead when the electronics module is positioned within the socket.

Abstract: A system includes a shoe and a pod. The pod is disposed at the shoe and includes a positioning component and an altimeter. The positioning component determines a first geodetic location of the shoe at a first time, whereas the altimeter determines a first elevation of the shoe at the first time. The first positioning component additionally determines a second geodetic location of the shoe at a second time and generate shoe distance data based on the first geodetic location and the second geodetic location. The altimeter additionally determines a second elevation of the shoe at the second time. The positioning component additionally determines a total distance traveled based on the shoe distance data, the first elevation and the second elevation.

Abstract: A device is provided for use by a user, wherein the device includes a first sensor, a second sensor and an efficiency generating component. The first sensor detects a first parameter and generates a first detected signal based on the first detected parameter. The second sensor detects a second parameter and generates a second detected signal based on the second detected parameter. The efficiency generating component generates an efficiency signal based on the first detected signal and the second detected signal.

Abstract: A garment includes a fabric portion, an electrode fixedly connected to the fabric portion, a receptacle fixedly connected to the fabric portion, and an electronics module releasably positioned in the receptacle. The receptacle includes a receptacle housing, an electrode lead, and a receptacle contact. The electrode lead is attached to the electrode. The electrode lead engages the receptacle contact to establish an electrical connection with the receptacle contact without being attached to the receptacle contact. The electronics module includes a module contact that engages the receptacle contact when the electronics module is positioned in the socket to establish an electrical connection between the module contact and the receptacle contact.