Abstract: The present invention contemplates a method of activating a wearable device, the method comprising the step of detecting an electromagnetic field generated by a Near Field Communication (“NFC”) transmitter within a detection range of an electromagnetic field detection circuit of the wearable device. In response to detecting the electromagnetic signal, the method further contemplates emitting a trigger signal to trigger a flip-flop, wherein triggering the flip-flop causes a switching transistor to switch between at least one of an activated state and a deactivated state, and wherein causing the switching transistor to switch between at least one of the activated state and the deactivated state, switches a connection between an electronic circuit and a power supply between at least one of a on state and an off state.

Abstract: The present invention contemplates a method of activating a wearable device, the method comprising the step of detecting an electromagnetic field generated by a Near Field Communication (“NFC”) transmitter within a detection range of an electromagnetic field detection circuit of the wearable device. In response to detecting the electromagnetic signal, the method further contemplates emitting a trigger signal to trigger a flip-flop, wherein triggering the flip-flop causes a switching transistor to switch between at least one of an activated state and a deactivated state, and wherein causing the switching transistor to switch between at least one of the activated state and the deactivated state, switches a connection between an electronic circuit and a power supply between at least one of a on state and an off state.

Abstract: A core body temperature sensor system which has multiple pairs of temperature sensors across a first insulating layer. The sensed temperatures are monitored as well as the rate of change of sensed temperature at the temperature sensors. The core body temperature is obtained based on a first representative temperature for the first set of temperature sensors, a second representative temperature for the second set of temperature sensors and rate of change information.

Abstract: The present invention relates to a wearable device and a system. The wearable device (20, 40) comprises an electronic circuit (21), a power supply (22), a switching circuit (23, 43) coupled between the electronic circuit and the power supply, and an electromagnetic field detection circuit (24) coupled to the switching circuit (23, 43) for detecting an electromagnetic field generated by an NFC transmitter within the detection range of the electromagnetic field detection circuit and for generating a trigger signal if an electromagnetic field generated by an NFC transmitter is detected within the detection range of the electromagnetic field detection circuit. The switching circuit (23, 43) comprises a flip-flop (231) or a transistor circuit (431) including an input transistor (432) and a fuse (433) to switch the connection between the electronic circuit and the power supply on in response to the trigger signal.

Abstract: The invention describes a single heat flux sensor arrangement (1) comprising a sensor (10) comprising a layer (100) of thermally insulating material, an inner temperature measurement means (S1) arranged at an inner region of the insulating layer (100) and an outer temperature measurement means (S2) arranged at an outer region of the insulating layer (100); an evaluation unit (11) adapted to receive a temperature input from the inner 5 temperature measurement means (S1) and to receive a temperature input from the outer temperature measurement means (S2); and a heating means (12, S2) realized to deliberately raise the temperature of a region of the insulating layer (100). The invention further describes a non-invasive method of measuring a core body temperature (T0) of a subject (3).

Abstract: The invention describes a passive heat-flow sensor (1) comprising a contact face (11) for placement on a subject (8) during a temperature monitoring procedure; and a plurality of combined thermistor arrangements, wherein a combined thermistor arrangement comprises an inner thermistor (S1) arranged at an inner face of the sensor (1); an upper thermistor (S2) arranged at the upper surface of the sensor (1) and arranged relative to the inner thermistor (S1) to measure a vertical heat flow outward from the subject (8); and a lateral thermistor (S3) arranged relative to the inner thermistor (S1) to measure a horizontal heat flow along the contact face (11). The invention further describes a method of measuring the temperature of a subject (8) using a heat-flow sensor (1); and a temperature sensing arrangement (10) for monitoring the temperature of a subject (8) using a heat-flow sensor (1).

Abstract: The present invention relates to multi-pin connector plugs (10-18) for coupling with a multi-pin connector socket along a coupling direction and to multi-pin connector sockets (20-25, 27, 28) for coupling with a multi-pin connector plug along a coupling direction. The present invention relates further to a wearable device, such as sensors or wearables.

Abstract: The present invention relates to a wearable device and a system. The wearable device (20, 40) comprises an electronic circuit (21), a power supply (22), a switching circuit (23, 43) coupled between the electronic circuit and the power supply, and an electromagnetic field detection circuit (24) coupled to the switching circuit (23, 43) for detecting an electromagnetic field generated by an NFC transmitter within the detection range of the electromagnetic field detection circuit and for generating a trigger signal if an electromagnetic field generated by an NFC transmitter is detected within the detection range of the electromagnetic field detection circuit. The switching circuit (23, 43) comprises a flip-flop (231) or a transistor circuit (431) including an input transistor (432) and a fuse (433) to switch the connection between the electronic circuit and the power supply on in response to the trigger signal.

Abstract: The present invention relates to a wearable device and a system. The wearable device (20, 40) comprises an electronic circuit (21), a power supply (22), a switching circuit (23, 43) coupled between the electronic circuit and the power supply, and an electromagnetic field detection circuit (24) coupled to the switching circuit (23, 43) for detecting an electromagnetic field generated by an NFC transmitter within the detection range of the electromagnetic field detection circuit and for generating a trigger signal if an electromagnetic field generated by an NFC transmitter is detected within the detection range of the electromagnetic field detection circuit. The switching circuit (23, 43) comprises a flip-flop (231) or a transistor circuit (431) including an input transistor (432) and a fuse (433) to switch the connection between the electronic circuit and the power supply on in response to the trigger signal.

Abstract: A core body temperature monitoring system comprises a first, core body temperature, thermometer and a second thermometer comprising a heat flux sensor. The second thermometer is for application to the skin for providing temperature monitoring over time. The second thermometer is calibrated using an output from the first core body temperature thermometer during an initial measurement operation. The first thermometer is removably attached to the second thermometer, wherein the first thermometer is adapted for use while attached to the second thermometer, and is then removed when the second thermometer is to be used. This system provides calibration of a flux sensor which is applied to the skin, by using an initial core body temperature measurement. In this way, the functionality and usage of a classic core body temperature thermometer is combined with a wearable continuous monitoring capability.

Abstract: The present invention relates to a system (100) for combined ablation and ultrasound imaging of associated tissue (40), which is particularly useful for use in an ablation process. The system comprises an interventional device (20) with an ultrasound transducer and an ablation unit. During an ablation process, the interventional device (20) can be applied for both ablation and imaging of the tissue (40) subject to the ablation. A controlling unit (CTRL) is further comprised within the system, and arranged to calculate a predictor value based on one or more signals from the ultrasound transducer, where the predictor value relates to a risk of impending tissue damage due to a rapid release of bubble energy. According to a specific embodiment, a primary signal is sent if the predictor value exceeds a threshold value, so that proper measures can be taken.

Abstract: The invention describes a single heat flux sensor arrangement (1) comprising a sensor (10) comprising a layer (100) of thermally insulating material, an inner temperature measurement means (S1) arranged at an inner region of the insulating layer (100) and an outer temperature measurement means (S2) arranged at an outer region of the insulating layer (100); an evaluation unit (11) adapted to receive a temperature input from the inner 5 temperature measurement means (S1) and to receive a temperature input from the outer temperature measurement means (S2); and a heating means (12, S2) realized to deliberately raise the temperature of a region of the insulating layer (100). The invention further describes a non-invasive method of measuring a core body temperature (T0) of a subject (3).

Abstract: A method of preventing or suppressing a false alarm during administration of food or medicine to a human or animal through a feeding tube having one or more sensors that generate a signal, comprises analyzing the signals to determine whether food or medicine is being administered and, if it is determined that food or medicine is present, preventing or suppressing an alarm. In a further step, the time and length of administration of food or medicine is recorded. When the feeding tube has at least two temperature sensors, differences in the temperatures recorded for the different temperature sensors indicate that food or medicine was administered. In a case where there is only one temperature sensor, the rate and extent of any temperature change of temperatures recorded from that temperature sensor are compared to an algorithm to determine whether feeding occurred.

Abstract: The present invention relates to a wearable device and a system. The wearable device (20, 40) comprises an electronic circuit (21), a power supply (22), a switching circuit (23, 43) coupled between the electronic circuit and the power supply, and an electromagnetic field detection circuit (24) coupled to the switching circuit (23, 43) for detecting an electromagnetic field generated by an NFC transmitter within the detection range of the electromagnetic field detection circuit and for generating a trigger signal if an electromagnetic field generated by an NFC transmitter is detected within the detection range of the electromagnetic field detection circuit. The switching circuit (23, 43) comprises a flip-flop (231) or a transistor circuit (431) including an input transistor (432) and a fuse (433) to switch the connection between the electronic circuit and the power supply on in response to the trigger signal.

Abstract: The invention describes a passive heat-flow sensor (1) comprising a contact face (11) for placement on a subject (8) during a temperature monitoring procedure; and a plurality of combined thermistor arrangements, wherein a combined thermistor arrangement comprises an inner thermistor (S1) arranged at an inner face of the sensor (1); an upper thermistor (S2) arranged at the upper surface of the sensor (1) and arranged relative to the inner thermistor (S1) to measure a vertical heat flow outward from the subject (8); and a lateral thermistor (S3) arranged relative to the inner thermistor (S1) to measure a horizontal heat flow along the contact face (11). The invention further describes a method of measuring the temperature of a subject (8) using a heat-flow sensor (1); and a temperature sensing arrangement (10) for monitoring the temperature of a subject (8) using a heat-flow sensor (1).

Abstract: The present invention relates to a device, system and method for sensor position guidance to guide a user or the subject to place a wearable sensor to the optimum position at the subject's body. The device comprises an image data input (40) for obtaining image data of at least a subject's body area showing motion of said body area, an analyzer (41) for analyzing the obtained image data to determine one or more locations of the body area showing maximal movement caused by respiration and/or heart beat, and a guidance output (42) for selecting from the determined one or more locations an optimum location based on the strength of movement and for providing guidance information indicating the optimum location, at which a wearable sensor (6) for monitoring respiration and/or heart rate should be placed to said subject's body.

Abstract: Systems and methods for providing infant monitoring and support avoid image degradation, for x-ray imaging, related to sensors used for infant monitoring by separating an infant-supporting body from a sensor-carrying body. The sensor-carrying body, and with it any number of related sensors, is moved out of the way during x-ray imaging.

Abstract: A core body temperature monitoring system comprises a first, core body temperature, thermometer and a second thermometer comprising a heat flux sensor. The second thermometer is for application to the skin for providing temperature monitoring over time. The second thermometer is calibrated using an output from the first core body temperature thermometer during an initial measurement operation. The first thermometer is removably attached to the second thermometer, wherein the first thermometer is adapted for use while attached to the second thermometer, and is then removed when the second thermometer is to be used. This system provides calibration of a flux sensor which is applied to the skin, by using an initial core body temperature measurement. In this way, the functionality and usage of a classic core body temperature thermometer is combined with a wearable continuous monitoring capability.

Abstract: An assistance system for visually handicapped persons with visual impairment in a part of their visual field includes body-worn sensors to inform them actively about objects or movements in the visually impaired sides.

Abstract: A method of preventing or suppressing a false alarm during administration of food or medicine to a human or animal through a feeding tube having one or more sensors that generate a signal, comprises analyzing the signals to determine whether food or medicine is being administered and, if it is determined that food or medicine is present, preventing or suppressing an alarm. In a further step, the time and length of administration of food or medicine is recorded. When the feeding tube has at least two temperature sensors, differences in the temperatures recorded for the different temperature sensors indicate that food or medicine was administered. In a case where there is only one temperature sensor, the rate and extent of any temperature change of temperatures recorded from that temperature sensor are compared to an algorithm to determine whether feeding occurred.