Abstract: A mobile device can be used to control a computing device different from the mobile device. The mobile device includes a processor configured to receive user input through a graphical user interface (GUI) of the mobile device. The processor can be configured to generate the GUI after detecting a magnetic field generated by a wireless power transmitter. The GUI includes a simulated button and/or an interface configured to receive tactile input indicative of spatial information. The processor is configured to provide information indicative of user input to the computing device to control the computing device.

Abstract: A wireless power transmitter may receive a request from a wireless power receiver to perform recalibration for a first type of foreign object detection (FOD) in response to the wireless power receiver attempting to change an electromagnetic parameter supplied by the wireless power transmitter. In response to receiving the request, the wireless power transmitter may perform a second type of FOD to produce a FOD result. When the FOD result indicates a foreign object is present or likely present, the wireless power transmitter may discontinue or limit wireless power transfer, and/or communicate the FOD result to the wireless power receiver. When the FOD result indicates a foreign object is not present or likely not present, the wireless power transmitter may communicate the FOD result to the wireless power receiver, perform the recalibration and continue with wireless power transfer.

Abstract: An apparatus and method for performing foreign object detection for a wireless power transmitter. A matching network and transmit coil are energized, and a resonance is excited. The resonance is allowed to decay. A temporal characteristic of the decay is measured. The temporal characteristic is analyzed to determine whether a foreign object is coupled to an electromagnetic field generated by the transmit coil.

Abstract: Foreign object detection for a wireless power transmitter can be performed using a reference Q-factor and measured Q-factor. The reference and measured Q-factors are compared to determine where a foreign object is present. The comparison is adjusted based on one or more additional parameters.

Abstract: Foreign object detection for a wireless power transmitter can be performed using a reference Q-factor and reference frequency for a wireless power receiver. A figure of merit may be calculated using the reference Q-factor and reference frequency. A Q-factor and resonant frequency may be measured, and a measurement figure of merit can be calculated. The figures of merit can be compared to determine where a foreign object is present.

Abstract: Techniques and examples pertaining to combined wireless charging and position tracking are described. A method may involve a processor of an apparatus operating in a first mode to effect wireless charging via at least a first coil of a plurality of coils of the apparatus. The method may also involve the processor operating in a second mode to effect position tracking via at least a second coil of the plurality of coils of the apparatus.

Abstract: Techniques and examples pertaining to combined wireless charging and position tracking are described. A method may involve a processor of an apparatus operating in a first mode to effect wireless charging via at least a first coil of a plurality of coils of the apparatus. The method may also involve the processor operating in a second mode to effect position tracking via at least a second coil of the plurality of coils of the apparatus.

Abstract: A network security system for wireless devices derives a fingerprint from the modulation imperfections of the analog circuitry of the wireless transceivers. These fingerprints may be compared to templates obtained when the wireless devices are initially commissioned in a secure setting and used to augment passwords or other security tools in detecting intruders on the network.

Abstract: A system for wireless power transfer is provided. The system includes a monitoring function to monitor control parameters and an input source that supplies power to a wireless power transmitter, wherein the wireless power transmitter operates with a wireless power receiver to supply a charging current to a load. A controller can be configured to receive the control parameters from the monitoring function and to control an adjustable operating point for the wireless power transmitter which controls the charging current delivered to the load via the wireless power receiver, wherein the controller commands a maximum power operating point for the wireless power transmitter when the input source is detected at or above a predetermined threshold and commands a reduced power operating point for the wireless power transmitter when the input source to the wireless power transmitter is detected below the predetermined threshold.

Abstract: A network security system for wireless devices derives a fingerprint from the modulation imperfections of the analog circuitry of the wireless transceivers. These fingerprints may be compared to templates obtained when the wireless devices are initially commissioned in a secure setting and used to augment passwords or other security tools in detecting intruders on the network.

Abstract: Example embodiments of the systems and methods of reduction of parasitic losses in a wireless power system disclosed herein provide a practical means of accurately estimating parasitic losses in a wireless power transfer system irrespective of coupling. Such systems and methods may be used to generate an equation which predicts parasitic losses in a wireless power system. In an offset case, in which the transmitter and receiver are not directly coupled, losses associated with the recirculating current in the primary LC tank dominate the loss, and the transmitted power may be better estimated by measuring the power inputs, power outputs, and injected losses in a controlled environment; making a mathematical fit to an equation, which from the various power measurements and injected loss, predicts the expected transmitter losses; and then, in an operational environment, using the equation to predict parasitic losses based on the power inputs, power outputs and expected loss equation.

Abstract: An improved sports helmet construction with a spaced two-part rigid outer impact shell configuration, each having an independent shock absorbing elastomeric support layer. Each impact outer helmet shell half isolates vector induced force impacts occurring during sports play while maintaining a head padding supportive contiguous inner shell about the player's head. A resilient gasket joins the independent outer shells along a continuous center helmet line maintaining force dependent isolation alignment.

Abstract: Systems and methods of wireless power transfer system with interference detection disclosed herein detects possible excessive energy transfer associated with parasitic metal objects placed in close proximity with system coils by comparing power received on the receiving side of the system with the power consumed on the primary side considering known losses in the system. If the result of such comparison shows that power consumed on the primary side substantially exceeds power received on the secondary side, the system may terminate operation.

Abstract: The present invention employs system and method in for distinguishing between power capabilities of various external power sources and a system that can communicate the identified power capabilities to the secondary side of the wireless power transfer system. Once the secondary side of the wireless power transfer system receives the power capability information, it adjusts the current available for a payload in accordance with the information received on power source capabilities.

Abstract: The invention relates to a method of detecting the presence of an analyte associated with a nanoparticle layer formed at a liquid-liquid interface. The method comprises removing a portion of one of the liquid phases; and detecting the presence of the analyte by Raman spectroscopy, Infra Red spectroscopy and/or fluorescence spectroscopy.

Abstract: The present invention employs system and method in for distinguishing between power capabilities of various external power sources and a system that can communicate the identified power capabilities to the secondary side of the wireless power transfer system. Once the secondary side of the wireless power transfer system receives the power capability information, it adjusts the current available for a payload in accordance with the information received on power source capabilities.

Abstract: The invention provides methods of purifying one or more biological analytes from a sample. The method comprises incubating the sample with nanoparticles and centrifuging a biphasic system. The biological analytes can be one or more of an enzyme, a protein, a nucleic acid, an organelle, a cell, a bacteria, a virus, or any other biological material which requires purification.

Abstract: Example embodiments of the systems and methods of reduction of parasitic losses in a wireless power system disclosed herein provide a practical means of accurately estimating parasitic losses in a wireless power transfer system irrespective of coupling. Such systems and methods may be used to generate an equation which predicts parasitic losses in a wireless power system. In an offset case, in which the transmitter and receiver are not directly coupled, losses associated with the recirculating current in the primary LC tank dominate the loss, and the transmitted power may be better estimated by measuring the power inputs, power outputs, and injected losses in a controlled environment; making a mathematical fit to an equation, which from the various power measurements and injected loss, predicts the expected transmitter losses; and then, in an operational environment, using the equation to predict parasitic losses based on the power inputs, power outputs and expected loss equation.

Abstract: The present invention employs system and method in for distinguishing between power capabilities of various external power sources and a system that can communicate the identified power capabilities to the secondary side of the wireless power transfer system. Once the secondary side of the wireless power transfer system receives the power capability information, it adjusts the current available for a payload in accordance with the information received on power source capabilities.

Abstract: Performance of wireless charging systems may be significantly degraded when parasitic metal objects come in close proximity to the transmitting coil. Some of the transmitted energy may be coupled by these metal objects and wasted as heat. This may create a danger as the metal objects may get hot enough to create a fire hazard, to cause plastic parts deformation, or operator skin burns when touched. Systems and methods of wireless power transfer system with interference detection disclosed herein detects possible excessive energy transfer associated with parasitic metal objects placed in close proximity with system coils by comparing power received on the receiving side of the system with the power consumed on the primary side considering known losses in the system. If the result of such comparison shows that power consumed on the primary side substantially exceeds power received on the secondary side, the system may terminate operation.