Abstract: An athlete (1) measures sprint time by locating a smartphone (3) having a camera and crystal oscillator clock which is first activated at the finish line. The sprint end time is recorded by a photo stamp time app activated by a video trigger causing the smartphone (3) to send a RF stop event signal to the athlete's wrist mounted motion sensor (2). Before this a sensor timer or clock is started via the sprinter's start event. The sprinter's start activates the sensor's clock and saves the captured start time including time drift error. Upon the phone app selecting the run time function, a sync command sent to the sensor (2) by the app zeros out the phone and sensor timers. A one-time crystal calibration routine correcting for drift errors caused by the smartphone's operating system is activated which provides the sprint with a corrected start time.

Abstract: An athlete measures sprint time by locating a smartphone having a camera and clock start button which is first activated at the finish line. The sprint end time is recorded by a photo stamp time app. This sprint end time activates a video trigger causing the smartphone to send a RF stop event signal to a wrist mounted motion sensor worn by the athlete. A sensor timer is started via the start event by track or self starting. In track starting, the athlete pushes a start button on the sensor to initiate a variable 2-5 second delayed sound READY-SET-GO series of beeps to start the sprint. In self starting, the sensor detects threshold motion parameters of the sprinter's start which activates the sensor's free running clock and saves the start time. The time base on the sensor is used to calculate run time.

Abstract: An athlete (1) measures sprint time by locating a smartphone (3) having a camera and crystal osillator clock which is first activated at the finish line. The sprint end time is recorded by a photo stamp time app activated by a video trigger causing the smartphone (3) to send a RF stop event signal to the athlete's wrist mounted motion sensor (2). Before this a sensor timer or clock is started via the sprinter's start event. The sprinter's start activates the sensor's clock and saves the captured start time including time drift error. Upon the phone app selecting the run time function, a sync command sent to the sensor (2) by the app zeros out the phone and sensor timers. A one-time crystal calibration routine correcting for drift errors caused by the smartphone's operating system is activated which provides the sprint with a corrected start time.

Abstract: A universal 6-DOF mems sensor combined with six degree of motion algorithms and human motion parameters permits individualized real time motion analysis of a user to enable accurate measurements. Data derived thereby is wirelessly sent for viewing to a Bluetooth® enabled smartphone or combination smartphone and eyeglass device, such as the Google Glass® headset. The sensor is worn on a wrist or ankle band or in combination with a chest mounted cardio heart rate monitor dependent on the biometric parameters measured. Typical physical exercise data gathered includes reps, sets, 10-100 yard dash times, vertical, horizontal and broad jump distances, a range of shuttle times, RAST, steps taken, distance traveled, velocity, acceleration, and calories burned. The heart rate monitor provides cardio assessment and the 6-DOF sensor measures a runner's pace and cadence data.

Abstract: An athlete measures sprint time by locating a smartphone having a camera and clock start button which is first activated at the finish line. The sprint end time is recorded by a photo stamp time app. This sprint end time activates a video trigger causing the smartphone to send a RF stop event signal to a wrist mounted motion sensor worn by the athlete. A sensor timer is started via the start event by track or self starting. In track starting, the athlete pushes a start button on the sensor to initiate a variable 2-5 second delayed sound READY-SET-GO series of beeps to start the sprint. In self starting, the sensor detects threshold motion parameters of the sprinter's start which activates the sensor's free running clock and saves the start time. The time base on the sensor is used to calculate run time.

Abstract: A universal 6-DOF mems sensor combined with six degree of motion algorithms and human motion parameters permits individualized real time motion analysis of a user to enable accurate measurements. Data derived thereby is wirelessly sent for viewing to a Bluetooth® enabled smartphone or combination smartphone and eyeglass device, marketed as the Google Glass® headset. The sensor is worn on a wrist or ankle band or in combination with a chest mounted cardio heart rate monitor dependent on the biometric parameters measured. Typical physical exercise data gathered includes reps, sets, 10-100 yard dash times, vertical, horizontal and broad jump distances, a range of shuttle times, RAST, steps taken, distance traveled, velocity, acceleration, and calories burned. The heart rate monitor provides cardio assessment and the 6-DOF sensor measures a runner's pace and cadence data.

Abstract: An apparatus includes a transceiver, a display, and a processor, operatively coupled to the transceiver and to the display. The processor is operative to interrupt a communication application by displaying a context notification within a graphical user interface (GUI) of the communication application on the display. The processor prevents user input to the communication application until a user selection input is received within the context notification on the GUI. In one embodiment, the processor is operative to display the context notification within a dialog box on the GUI.

Abstract: Methods, methods, apparatus, computer program code and means to evaluate performance via a distributed communication network are provided. In some embodiments, a computer store may contain data for a plurality of source channels, including, for each source channel, historic interaction information. A back-end application server may receive from a remote administrator computer a selected source channel identifier and automatically identify historic interaction information in the computer store associated with the selected source channel identifier. The back-end application server may then evaluate the identified historic interaction information and associated benchmark indications to generate a set of performance metric scores for a selected source channel matching the selected source channel identifier and aggregate the set of performance metric scores to calculate an overall aggregated performance score for the selected source channel.

Abstract: The present invention provides compositions and methods for inhibiting Ikaros in a cell in order to enhance the cytolytic activity of the cell. In one embodiment, the cells may be used in adoptive T cell transfer. For example, in some embodiments, the cell is modified to express a chimeric antigen receptor (CAR). Inhibition of Ikaros in T cells used in adoptive T cell transfer increases cytolytic activity of the T cells and thus may be used in the treatment of a variety of conditions, including cancer, infection, and immune disorders.

Abstract: A universal 6-DOF mems sensor combined with six degree of motion algorithms and human motion parameters permits individualized real time motion analysis of a user to enable accurate measurements. Data derived thereby is wirelessly sent for viewing to a Bluetooth® enabled smartphone or combination smartphone and eyeglass device, marketed as the Google Glass® headset. The sensor is worn on a wrist or ankle band or in combination with a chest mounted cardio heart rate monitor dependent on the biometric parameters measured. Typical physical exercise data gathered includes reps, sets, 10-100 yard dash times, vertical, horizontal and broad jump distances, a range of shuttle times, RAST, steps taken, distance traveled, velocity, acceleration, and calories burned. The heart rate monitor provides cardio assessment and the 6-DOF sensor measures a runner's pace and cadence data.

Abstract: A headset is disclosed having a transmitting unit for each ear. Each unit (2) mounts a first bone vibration sensor (3) in the external auditory canal and a second bone vibration sensor (7) next to the jawbone/skull. Controls on a housing module (4) activate either sensor. The first sensor is moveable outside the auditory canal by a flexible support attached to the module. A digital speech processor shared by both sensors is mounted within the module. Two-way communication is maintained between the user and an external source (40), such as a cellular telephone which has a multi-task processor with memory and applications stored therein for receiving and transmitting user voice commands and text messages. A recently developed Bluetooth® protocol transmitter (50) and antenna used with the external source permits digital wireless simultaneous synchronization signals to be sent to both units for true stereo sound.

Abstract: Digital musical footwear is disclosed having hidden compartments which house a thin integrated multi-plane electronic circuit board assembly (2) and a rechargeable lithium ion battery pack. A transmitter antenna is attached to a hand held device such as a smart phone which antenna sends wireless short wave sound signals to a receiving antenna part of the circuit board assembly. Multiple mini-speakers (6, 7) are footwear mounted to play the music. Bluetooth® version 4.0 wireless protocol technology is employed in the circuit board assembly. The circuit board can be flat and hidden in a recess of a heel or curved and hidden in a wall recess of the footwear as can the battery pack. Advanced lithium ion batteries such as silicon wafer or silicon core-shell nanowire batteries may be used to reduce battery weight. Flexible flat speakers (65) such as the FleXpeaker® may also be used to further reduce weight.

Abstract: A music playing system employing the combination of mini-speaker footwear wirelessly receiving music from a music source (20) external to the footwear using an audio adapter transmitter (13) connected to the music source (20) to wirelessly transmit music to an audio adapter receiver (9) mounted in the footwear is disclosed. A rechargeable lithium-ion polymer battery pack (10) is hidden in a shoe compartment (19). This battery pack powers the speakers (1-4) in the footwear and the audio adapter receiver (9). The external music source (20) may for example be but not limited to an iPod, iPhone, iPad, iPad 3G, iPod nano, iPod Shuffle, iPod Touch, iPad Tablet, smart phone, Droid phone, Android phone, MP3 player, CD player, microchip player or computer. Power for the audio adapter transmitter (13) is provided by the battery power pack of the external music source.

Abstract: A headset is disclosed having a transmitting unit for each ear. Each unit (2) mounts a first bone vibration sensor (3) in the external auditory canal and a second bone vibration sensor (7) next to the jawbone/skull. Controls on a housing module (4) activate either sensor. The first sensor is moveable outside the auditory canal by a flexible support attached to the module. A digital speech processor shared by both sensors is mounted within the module. Two-way communication is maintained between the user and an external source (40), such as a cellular telephone which has a multi-task processor with memory and applications stored therein for receiving and transmitting user voice commands and text messages. A recently developed Bluetooth® protocol transmitter (50) and antenna used with the external source permits digital wireless simultaneous synchronization signals to be sent to both units for true stereo sound.

Abstract: A method for detecting particulate contamination under a workpiece fixtured by a calibrated material handling system includes performing 3D measurements of a workpiece at multiple of positions to construct a 3D map of the workpiece, calibrating the 3D map by comparing a pre-computed calibration map to the 3D measurements, and detecting particulate contamination by processing the calibrated map.

Abstract: An electronic device may present to a user multiple questions, at least one of which corresponds to a health condition of the user. The electronic device may receive user input information from the user responsive to the questions presented to the user. A storage device may store the user input information. A processor may determine demographic and health behavior indicators based on the user input information. A user interface of the electronic device may present an interactive game to the user that is based on the demographic and health behavior indicators. The interactive game may pertain to the health condition of the user.

Abstract: In one embodiment, a mobile device system capable of viewfinder operation includes a memory device, a photosensitive device capable of receiving light providing an image of an external object, a video screen, and a processing device coupled at least indirectly to each of the memory and photosensitive devices and the screen, where the processing device provides signal(s) to the screen configured to cause the screen to operate as a viewfinder that displays a further image based upon the external object image. The mobile device further includes at least one sensing device either distinct from or associated with the screen, and configured to detect input commands indicated by movement or positioning of at least one object. The processing device causes the screen to display a plurality of options and subsequently to modify the further image displayed by the viewfinder in accordance with the detected commands. Related operational methods are also described.

Abstract: A music playing system employing the combination of mini-speaker footwear wirelessly receiving music from a music source (20) external to the footwear using an audio adapter transmitter (13) connected to the music source (20) to wirelessly transmit music to an audio adapter receiver (9) mounted in the footwear is disclosed. A rechargeable lithium-ion polymer battery pack (10) is hidden in a shoe compartment (19). This battery pack powers the speakers (1-4) in the footwear and the audio adapter receiver (9). The external music source (20) may for example be but not limited to an iPod, iPhone, iPad, iPad 3G, iPod nano, iPod Shuffle, iPod Touch, iPad Tablet, smart phone, Droid phone, Android phone, MP3 player, CD player, microchip player or computer. Power for the audio adapter transmitter (13) is provided by the battery power pack of the external music source.

Abstract: Digital musical footwear is disclosed having hidden compartments which house a thin integrated multi-plane electronic circuit board assembly (2) and a rechargeable lithium ion battery pack. A transmitter antenna is attached to a hand held device such as a smart phone which antenna sends wireless short wave sound signals to a receiving antenna part of the circuit board assembly. Multiple mini-speakers (6, 7) are footwear mounted to play the music. Bluetooth® version 4.0 wireless protocol technology is employed in the circuit board assembly. The circuit board can be flat and hidden in a recess of a heel or curved and hidden in a wall recess of the footwear as can the battery pack. Advanced lithium ion batteries such as silicon wafer or silicon core-shell nanowire batteries may be used to reduce battery weight. Flexible flat speakers (65) such as the FleXpeaker® may also be used to further reduce weight.

Abstract: An easy-open beverage container which can be selectably reclosed and reopened, after it has been opened. A unitary opening and reclosure structure attached to the end wall by a hinge connection permitting selectable movement of the unitary member on a first path normal to the end wall and on a second path parallel to the wall. The end wall having a selectively separable region of predetermined weakness forming an openable panel recessed a limited distance below the level of the wall. A portion of the openable panel retained to the wall by a hinge formed by a disruption in the separable region on predetermined weakness. The recessed region being surrounded by a platform and side wall located a limited distance from the openable panel.