Abstract: A monitor comprises circuitry to receive a signal and process the signal to monitor at least one characteristic of a subject, and a flexible polymer casing forming a waterproof enclosure for the circuitry. The flexible polymer casing is infused with a conductive material at at least one location to form at least one infused electrode that extends from an exterior of the flexible polymer casing to an interior of the flexible polymer casing, and the at least one infused electrode is coupled to the circuitry so as to allow the signal to pass from outside the flexible polymer casing to the circuitry. A polymer in a portion of the flexible polymer casing that is infused with the conductive material at the at least one location is cross-linked with a polymer in a portion of the flexible polymer casing that is not infused with the conductive material.

Abstract: A monitor comprises circuitry to receive a signal and process the signal to monitor at least one characteristic of a subject, and a flexible polymer casing forming a waterproof enclosure for the circuitry. The flexible polymer casing is infused with a conductive material at location to form infused electrode that extends from an exterior of the flexible polymer casing to an interior of the flexible polymer casing, and the infused electrode is coupled to the circuitry so as to allow the signal to pass from outside the flexible polymer casing to the circuitry. A polymer in a portion of the flexible polymer casing that is infused with the conductive material at the location is cross-linked with a polymer in a portion of the flexible polymer casing that is not infused with the conductive material.

Abstract: A monitor comprises circuitry to receive a signal and process the signal to monitor at least one characteristic of a subject, and a flexible polymer casing forming a waterproof enclosure for the circuitry. The flexible polymer casing is infused with a conductive material at at least one location to form at least one infused electrode that extends from an exterior of the flexible polymer casing to an interior of the flexible polymer casing, and the at least one infused electrode is coupled to the circuitry so as to allow the signal to pass from outside the flexible polymer casing to the circuitry. A polymer in a portion of the flexible polymer casing that is infused with the conductive material at the at least one location is cross-linked with a polymer in a portion of the flexible polymer casing that is not infused with the conductive material.

Abstract: Disclosed are systems and methods for using one or more light sources and associated photodetectors to determine different physiological parameters of a subject based on the subject's activity state. A processor may, for example, be configured to determine, based at least in part on data received from an accelerometer at a first time, that a first physiological parameter of the subject is to be determined, to cause the light source(s) to operate in a first manner and process signals from the photodetector(s) to determine the first physiological parameter, to determine, based at least in part on data received from the accelerometer at a second time, that a second physiological parameter of the subject is to be determined, and to cause the light source(s) to operate in a second manner and process signals from the photodetector(s) to determine the second physiological parameter.

Abstract: Disclosed is apparatus including a power source, an ECG front end, a processor, and a computer-readable medium. The ECG front end is configured to receive a signal corresponding to a cardiac waveform, and the computer-readable medium is encoded with instructions which, when executed by the processor, cause the apparatus to (a) determine a first temporal window during which a first instance of a first portion of a cardiac cycle is expected to appear in the cardiac waveform (b) at a start of the first temporal window, apply a first amount of power from the power source to the ECG front end, and (c) at an end of the first temporal window, at least partially reduce an amount of power applied from the power source to the ECG front end.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used fox outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: In one embodiment, a method for implementing two-way communication between at least first and second devices comprises steps of: (a1) during finite time periods following transmission of respective first messages from the first device to the second device, using the first device to listen for second messages transmitted from the second device to first device; and (a2) after each of the finite time periods following the transmission of the respective first messages from the first device to the second device, ceasing to use the first device to listen for second messages transmitted from the second device to the first device until after the first device transmits another first message to the second device.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used fox outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A health-monitor patch comprising at least one physiological sensor and digital processor is configured to be adhered to the skin of a subject. A health-monitor patch may further include an accelerometer and may detect cardiac waveforms, activity performed by the subject, and a body orientation of the subject. A health-monitor patch may be disposable, in some embodiments, and used for outpatient monitoring. Aspects of noise cancellation and reel-to-reel manufacturing are also described.

Abstract: A securing apparatus may be configured to secure a wearable item to any one of a variety of different graspable articles, in a suitable manner. The securing apparatus may include a securing portion, having multiple securing members. The stiffness of one of the securing members may differ from the stiffness of another securing member. The securing members may be cantilevers. In some embodiments, the anchored end of one of the cantilevers may be attached to the deflecting end of another cantilever. One of the cantilevers may deform plastically due to repeated usage with relatively thick garments, though, by employing at least one additional cantilever in an appropriate manner, the ability to grip thinner garments in a suitable manner remains uncompromised.

Abstract: Apparatuses and methods are disclosed for monitoring and evaluating exercise-related activities performed by a subject. A health monitor comprising an accelerometer, at least one physiological sensor, and digital processor is configured to be supported by a subject and identify an activity type (e.g., running, biking, swimming) from among a plurality of different activities. The health monitor is further configured to determine from motion data and/or cardiac data levels of health benefits received from the exercise. The health benefits may be based on standards established by recognizable health entities, so that the reported health benefits are less susceptible to errors associated with conventional step counting.

Abstract: A network for electronic communications in which disparate anonymous devices may transmit and receive information, such as in a secure manner. A method for collecting health-related data may, for example, comprise detecting, at a first time, that a sensor has moved within a detection range of a link component, the sensor having not been identified to the link component prior to the first time; receiving data collected by the sensor relating to activity by and/or health of a human subject associated with the sensor; and processing the data to determine at least one indicator of the human subject's health.

Abstract: In one embodiment, a method for implementing two-way communication between at least first and second devices comprises steps of (a1) during finite time periods following transmission of respective first messages from the first device to the second device, using the first device to listen for second messages transmitted from the second device to first device; and (a2) after each of the finite time periods following the transmission of the respective first messages from the first device to the second device, ceasing to use the first device to listen for second messages transmitted from the second device to the first device until after the first device transmits another first message to the second device.

Abstract: In one embodiment, a method for implementing two-way communication between at least first and second devices comprises steps of: (a1) during finite time periods following transmission of respective first messages from the first device to the second device, using the first device to listen for second messages transmitted from the second device to first device; and (a2) after each of the finite time periods following the transmission of the respective first messages from the first device to the second device, ceasing to use the first device to listen for second messages transmitted from the second device to the first device until after the first device transmits another first message to the second device.