Abstract: A method is provided. The method comprises determining configuration data; wherein the configuration data comprises a resistance of a bypass circuit coupled between a remote radio head and a power cable; using the configuration data, determining the resistance of the power cable coupling a programmable power supply to the remote radio head mounted on a mounting structure, comprising: entering a calibration mode; setting an output voltage of the programmable power supply; measuring an output current of the programmable power supply; storing the output current; and determining the cable resistance; and storing the resistance of the power cable.

Abstract: A method and apparatus reduce power consumption and mitigate declining battery life. In some embodiments, an initial full charge capacity, C(O), of a rechargeable battery is determined. A full charge capacity, C(t), of the rechargeable battery is determined at time t. An average power consumption profile is determined. A reduced power consumption is implemented based on the average power consumption profile and a factor C(t)/C(O). In other embodiments, functions that are not used in an average power consumption profile are deactivated. Other functions that occur in certain use cases of the average power consumption profile are activated and deactivated as needed.

Abstract: The present application provides an electromagnetic coupling interface and a method for managing an electromagnetic coupling capability relative to a particular charge location with an electromagnetic coupling interface. The electromagnetic coupling interface includes a carrier substrate including two or more moveably coupled segments, the carrier substrate having at least two use positions, where in each use position the two or more moveably coupled segments have a different spatial arrangement. The electromagnetic coupling further includes two or more sets of conductors, where each set of conductors is associated with a respective one of the two or more moveably coupled segments of the carrier substrate and is associated with one or more coils in each of the at least two use positions.

Abstract: A method, system, and computer program product for identifying at least one alternate power source to provide power to a portable device during an upcoming time period of use. The method includes monitoring power parameters associated with at least one battery of the portable device and determining, based on the power parameters, whether the at least one battery that is currently coupled to the portable device is capable of powering the portable device for an entirety of an upcoming time period of use. In response to determining the at least one battery is not capable of powering the portable device for the entirety of the upcoming time period of use, identifying at least one alternate power source that may provide power for use during the upcoming time period of use. The method then includes generating and outputting a power management strategy, which utilizes the at least one alternate power source.

Abstract: A wearable charging apparatus configured for charging of a wearable device while the wearable device is in an operative position, such as on the wrist of the user the wearable charging apparatus includes a front housing portion, a rear charging portion, a coupling member and a charge system. The wearable device is positionable between the front housing portion and the rear charging portion. The front portion has a battery and the rear charging portion has a wearable charge coil that is placed in operable position relative to the wearable device and configured to electrically communicate with a coil within the body of the wearable device and coupled to a wearable battery therewith, to, in turn, transfer power from the battery within the cavity to the wearable battery.

Abstract: Systems and methods for providing a smart hydration container or bottle which accurately tracks a user's liquid intake. The smart hydration container utilizes a new capacitive sensing technology which does not require a complicated design for capacitive conductive surfaces and provides accurate capacitive measurements which map to volume measurements. Through the use of calibrated data, the smart hydration container accurately measures capacitance “as a whole” of the entire container's contents even when the container is not resting upright. In some implementations, the smart hydration container utilizes a combination of capacitive sensing, motion sensing, position sensing, and/or temperature sensing to provide an accurate measure of liquid volume in the container. The capacitive sensor may be electrically shielded by a passive conductive sensor shield, a grounded conductive sensor shield, or an active conductive sensor shield.

Abstract: A method, system, and computer program product for identifying at least one alternate power source to provide power to a portable device during an upcoming time period of use. The method includes monitoring power parameters associated with at least one battery of the portable device and determining, based on the power parameters, whether the at least one battery that is currently coupled to the portable device is capable of powering the portable device for an entirety of an upcoming time period of use. In response to determining the at least one battery is not capable of powering the portable device for the entirety of the upcoming time period of use, identifying at least one alternate power source that may provide power for use during the upcoming time period of use. The method then includes generating and outputting a power management strategy, which utilizes the at least one alternate power source.

Abstract: A method, a portable electronic device and a wireless charging system enables a load to be charged by selectively using a detection circuit configuration and a power receiving circuit configuration. A controller is coupled within a wireless power receiver (i) to a sensing circuit having a multi-tapped coil and (ii) to a rectifier that is coupled to the sensing circuit and removably coupled to a load. The controller detects, at an output of the rectifier, a first signal corresponding to an externally transmitted signal that is magnetically coupled to the multi-tapped coil while the sensing circuit is in the detection circuit configuration. In response to detecting the first signal, the controller switches from the detection circuit configuration to the power receiving circuit configuration. The controller then connects the load to the output of the rectifier in order to deliver power to the load.

Abstract: The invention relates to a hydraulic circuit (1) of a torque transmission device, wherein at least two, in particular closed in a non-actuated state (normally closed), clutches (2, 3) of the torque transmission device can be element (12, 13) of the hydraulic circuit, wherein in a clutch opening state, every clutch valve element (12, 13) is connected to a high-pressure line (30) that is applied with the pressure of a high-pressure hydraulic accumulator (31) and/or generator (32), by means of a pressurisation line (22, 23) for the deflection of the clutch (2, 3), and in a closing state, same is connected to a low-pressure tank (40) by means of a tank line (42, 43, 44, 45, 46, 47, 48, 49) for releasing a deflection pressure, and wherein the tank lines (42, 43, 44, 45, 46, 47, 48, 49) of the clutch valve elements (12, 33) are guided to a safety valve (50), in particular by means of a common collection tank line (41), which safety valve can be switched in such a way that the tank lines (42, 43, 44, 45, 46, 47, 48,

Abstract: The present application provides a coil for facilitating an electromagnetic coupling and method for increasing the degree of an electromagnetic coupling. The coil for facilitating an electromagnetic coupling includes one or more loops formed from a material through which an electric current can flow. At least one of the one or more loops is adjustable, including at least one of a size and a shape of the at least one of the one or more loops of the coil being selectively adjustable.

Abstract: Systems and methods for providing a smart hydration container or bottle which accurately tracks a user's liquid intake. The smart hydration container utilizes a new capacitive sensing technology which does not require a complicated design for capacitive conductive surfaces and provides accurate capacitive measurements which map to volume measurements. Through the use of calibrated data, the smart hydration container accurately measures capacitance “as a whole” of the entire container's contents even when the container is not resting upright. In some implementations, the smart hydration container utilizes a combination of capacitive sensing, motion sensing, position sensing, and/or temperature sensing to provide an accurate measure of liquid volume in the container. The capacitive sensor may be electrically shielded by a passive conductive sensor shield, a grounded conductive sensor shield, or an active conductive sensor shield.

Abstract: Systems and methods for wireless power transmission between a portable communication device and an add-on module allow a resonator coil in the portable communication device to both transmit and receive power. In an embodiment, the portable communication device provide power via various on time duty cycles based on a type of the add-on module.

Abstract: An apparatus, such as a user device, can comprise a battery, a plurality of antennas, a transceiver, a charging pad interface, and a controller. The battery can be configured to power the user device. The plurality of antennas can be configured to send and receive signals to and from a wireless node. The transceiver can be configured to communicate, via the plurality of antennas, with the wireless node. The charging pad interface can be configured to detect that the apparatus is coupled to a charging pad and to receive charging power from the charging pad. The controller can be configured to change a configuration of at least one antenna from the plurality of antennas in response to the charging pad interface detecting that the apparatus is coupled to the charging pad.

Abstract: A wearable charging apparatus configured for charging of a wearable device while the wearable device is in an operative position, such as on the wrist of the user the wearable charging apparatus includes a front housing portion, a rear charging portion, a coupling member and a charge system. The wearable device is positionable between the front housing portion and the rear charging portion. The front portion has a battery and the rear charging portion has a wearable charge coil that is placed in operable position relative to the wearable device and configured to electrically communicate with a coil within the body of the wearable device and coupled to a wearable battery therewith, to, in turn, transfer power from the battery within the cavity to the wearable battery.

Abstract: A method and apparatus reduce power consumption and mitigate declining battery life. In some embodiments, an initial full charge capacity, C(O), of a rechargeable battery is determined. A full charge capacity, C(t), of the rechargeable battery is determined at time t. An average power consumption profile is determined. A reduced power consumption is implemented based on the average power consumption profile and a factor C(t)/C(O). In other embodiments, functions that are not used in an average power consumption profile are deactivated. Other functions that occur in certain use cases of the average power consumption profile are activated and deactivated as needed.

Abstract: A battery charger, which can be configured as a charger or docking station (300), includes one or more control circuits (105). A charging circuit (302) can charge one or more rechargeable batteries (118). A thermal management device (305) can alter a thermal condition of the one or more rechargeable batteries. The one or more control circuits can receive, with a communication circuit (309) an indication of a thermal state of an electronic device (100). The one or more control circuits can cause the thermal management device to alter the thermal condition of the one or more rechargeable batteries such that when the one or more rechargeable batteries are coupled to the electronic device, a thermal mass defined by the electronic device and the one or more rechargeable batteries transitions from the thermal state toward a predefined thermal mass temperature.

Abstract: An extremely small, simple, digitally controlled tracking device provides greater transceiver functionality by being programmable across a wide frequency range and various modulation formats with the same circuit components. Additionally, the programmable nature of the tracking device provides reliable scheduling functionality.

Abstract: An improved electronic communications system 100 features a holder assembly 104 such as a mobile computing device dock station 106 and dock heat exchanger providing an external heat sink 162 which when coupled with a user-friendly heat transfer device 164 such as a heat pipe can transfer heat from internal electronic components 146, 148 and 154 and an internal heat sink 157 of an electronic communications device 102, such as a cellular phone or mobile computing device, via a special headset jack-heat pipe interface 167 to help cool the electronic communications device 102. The electronic communications device 102 can also include one or more thermal couplings 158-160 for coupling and providing a thermal pathway(s) from at least one of the internal electronic components 146, 148 and 154 to the internal heat sink 157.

Abstract: A battery charger, which can be configured as a charger or docking station (300), includes one or more control circuits (105). A charging circuit (302) can charge one or more rechargeable batteries (118). A thermal management device (305) can alter a thermal condition of the one or more rechargeable batteries. The one or more control circuits can receive, with a communication circuit (309) an indication of a thermal state of an electronic device (100). The one or more control circuits can cause the thermal management device to alter the thermal condition of the one or more rechargeable batteries such that when the one or more rechargeable batteries are coupled to the electronic device, a thermal mass defined by the electronic device and the one or more rechargeable batteries transitions from the thermal state toward a predefined thermal mass temperature.

Abstract: The invention relates to novel compounds, processes for their preparation and their use in protecting biological materials from radiation damage (radioprotection).