Abstract: A system for dynamic registration of autonomy using augmented reality can include an augmented reality system, an imaging system, a measuring system, and a computer system. The augmented reality system can be configured to display an augmented representation. The imaging system can be configured to image an anatomical feature of the patient and can generate anatomical imaging data. The measuring system can be configured to measure an anatomical movement of the patient and can generate an anatomical movement data. The computer system can be configured to receive the anatomical imaging and positional data and the anatomical movement data, generate the augmented representation based on the anatomical imaging data, associate the augmented representation with the anatomical movement data, render the augmented representation on the augmented reality system, and selectively update the augmented representation based on the anatomical movement data.

Abstract: A wireless communication device or a split band diversity antenna arrangement (10, 20, 30 or 41) has a first multi-band antenna (22 or 14) located at a bottom portion (11) of the wireless communication device and selectively coupled to a diversity receiver (26), a second multi-band antenna (24 or 12) located at a top portion (13) of the wireless communication device and selectively coupled to a dual band transceiver (28), a band splitter (25) splitting an input from the first antenna into a first output and a second output where the first output serves as an input to the diversity receiver, and a band combiner (27) that combines the second output of the band splitter with a signal from the second antenna to provide an input signal to the dual band transceiver.

Abstract: Embodiments include systems and methods for controlling radiation of radio frequency (RF) energy by a wireless communication device that includes a transmitter, an antenna, a vector field sensor, and a processing system. The transmitter produces an analog RF signal, and the antenna radiates the analog RF signal into an environment. The vector field sensor senses an intensity of a vector field resulting from the analog RF signal radiated by at least the antenna (and possibly other portions of the device). The processing system determines whether a value representing the intensity is greater than a first threshold, and when the value is greater than the first threshold, the processing system causes the radiated RF energy produced by the wireless communication device to be decreased.

Abstract: An apparatus (100) that charges a portable electronic device is disclosed. The apparatus can include a portable electronic device housing (110) including a first aperture (111) and at least one second aperture (112). The apparatus can include a battery (120) coupled to the portable electronic device housing and a generator (130) coupled to the battery, where the generator can be configured to charge the battery. The apparatus can include a rotatable turbine (140) enclosed within the portable electronic device housing and coupled to the generator, where the rotatable turbine can be configured to drive the generator. The apparatus can include a conduit (150) coupled to the rotatable turbine and coupled to the first aperture, where the conduit can be configured to provide fluid flow to drive the rotatable turbine.

Abstract: A method (400) and a mobile station (160) for controlling communication via a radio link based on a multi-slot based power class designation are described herein. The mobile station (160) may provide a multi-slot based power class designation to the communication network (110) to establish a radio link for communication service. The designation may be associated with a power level of the mobile station (160) and a number of slots corresponding to the power level. Based on the designation, the mobile station (160) may communicate with the communication network (110) via the radio link.

Abstract: A method for marketing and system for marketing are disclosed. In one embodiment, a method for marketing a product includes identifying the product at a mobile device associated with a user, and generating a message indicative of an endorsement of the product by the user, the generating being performed at least in part by way of the mobile device. The method further includes causing, by way of the mobile device, a sending of the message to at least one receiving device associated with at least one personal social contact of the user. Due to the causing, a seller of the product is also notified that the sending of the message has occurred.

Abstract: Embodiments include systems and methods for controlling radiation of radio frequency (RF) energy by a wireless communication device that includes a transmitter, an antenna, a vector field sensor, and a processing system. The transmitter produces an analog RF signal, and the antenna radiates the analog RF signal into an environment. The vector field sensor senses an intensity of a vector field resulting from the analog RF signal radiated by at least the antenna (and possibly other portions of the device). The processing system determines whether a value representing the intensity is greater than a first threshold, and when the value is greater than the first threshold, the processing system causes the radiated RF energy produced by the wireless communication device to be decreased.

Abstract: A wireless communication device or a split band diversity antenna arrangement (10, 20, 30 or 41) has a first multi-band antenna (22 or 14) located at a bottom portion (11) of the wireless communication device and selectively coupled to a diversity receiver (26), a second multi-band antenna (24 or 12) located at a top portion (13) of the wireless communication device and selectively coupled to a dual band transceiver (28), a band splitter (25) splitting an input from the first antenna into a first output and a second output where the first output serves as an input to the diversity receiver, and a band combiner (27) that combines the second output of the band splitter with a signal from the second antenna to provide an input signal to the dual band transceiver.

Abstract: An electrically small antenna, such as one physically sized appropriate to a mobile device, can be tuned in response to a detected change that can result in poorer reception using the electrically small antenna. Such detected changes include a detected change in the connectivity of a wired accessory relative to the mobile device, a detected change in a position of the mobile device, and a detected change of an audio channel selected by the mobile device. To minimize any user impact of the retuning of the electrically small antenna, a timer can be initiated and the antenna can be retuned during an opportune time, such as when one or more signal metrics associated with a signal being provided to the user drop below a threshold, or when the timer expires, whichever occurs first.

Abstract: An apparatus (100) that charges a portable electronic device is disclosed. The apparatus can include a portable electronic device housing (110) including a first aperture (111) and at least one second aperture (112). The apparatus can include a battery (120) coupled to the portable electronic device housing and a generator (130) coupled to the battery, where the generator can be configured to charge the battery. The apparatus can include a rotatable turbine (140) enclosed within the portable electronic device housing and coupled to the generator, where the rotatable turbine can be configured to drive the generator. The apparatus can include a conduit (150) coupled to the rotatable turbine and coupled to the first aperture, where the conduit can be configured to provide fluid flow to drive the rotatable turbine.

Abstract: The present invention relates generally to wireless communications, and more particularly to a communication system operating in a licensed RF band and an unlicensed RF band. The method comprises exchanging (302) traffic information (410) between a base station (102) and a mobile station (105, 107) on at least one radio channel in the unlicensed RF band (402) and exchanging (304) control information (405) that is associated with the traffic information, in the licensed radio frequency band (404).

Abstract: A method and apparatus is provided for configuring a wireless communication module (220) for optimal performance with a portable communication handset (210). When coupling of a portable electronic handset (210) and a wireless communication module (220) is detected (602, 702) the portable electronic handset (210) uploads configuration information (604, 606, 608, 610) to the wireless communication module (220). The wireless communication module (220) receives the configuration information (704, 706, 708, 710) from the portable communication device (210) and configures the operational parameters of the wireless communication module (220) in response to the configuration information (714, 716, 718, 720).

Abstract: A method and apparatus for modular authentication of a wireless communication device (120) including a portable communication device (210) and a wireless communication module (220) coupleable thereto is disclosed. When the wireless communication module (220) receives information (706) from the portable communication device (210), it determines whether the information received is authentic information (710) and operates together with the portable communication device (210) as a wireless communication device (120) in a communication system (100) in response to the information received being authentic information (720). In addition, a method and apparatus is disclosed for checking subsidy lock in a wireless communication device (120) capable of operating in a communication system (100), the wireless communication device comprising a first module (210), a second module (220) and a subscriber identity module (230) coupled to the first and second modules (210, 220).

Abstract: A wireless transmitter (100) including an amplifier (112), an automatic output controller (116) (AOC) having an output coupled to a control signal input. The AOC detects a second amplifier parameter that changes with a change in load impedance during a transmission, and the AOC reduces a change in transmitter output power related to the change in load impedance based on a first parameter and the detected second parameter during the same transmission during which the second parameter was detected.

Abstract: A communication device 100 includes a first audio output 105; a second audio output 110; an audio transducer 115 for dual mode use; a shuttered acoustic path 120 coupled between the audio transducer 115 and the first audio output 105; and an attenuated acoustic path 125 coupled between the audio transducer 115 and the second audio output 110.

Abstract: A method is provided for on-demand communications in a communication network with support for a plurality of communication units participating in a common communication, which includes multiple signal initiators, each supplying a signal, which are virtually simultaneously conveyed as part of the common communication. At least one example of an on-demand communication includes push to talk. Additionally, a signal initiator is provided, which is adapted to support on-demand communications in a multi-signal initiator environment.

Abstract: A radio frequency identification (RF ID) tag (202) and a method for communicating data from an RF ID card to an electronic device (102) are disclosed. The RF ID tag comprises one or more removable materials that conceal the data (106). The presence of the one or more removable materials disables the RF ID tag.

Abstract: A method in a transmitter for data collision avoidance in an uncoordinated frequency hopping communication system is disclosed. The base station (104) first determines (304) that a first data set to be sent to a first device (105) and a second data set to be sent to a second device (107) are scheduled to be transmitted simultaneously on a first frequency of a frequency hop-set. The device then transmits (310) the first data set on the first frequency of the frequency hop-set. The base station delays (312) transmission of the second data set, and finally transmits (316) the second data set on a second frequency of a frequency hop-set.

Abstract: Disclosed herein is a method and apparatus for inductively charging a battery. The battery comprises a housing (102), at least one battery cell (104) carried in the housing and a multimode near field transceiver (106) carried also in the housing. The near field transceiver is operable in a passive mode to provide information and active mode to exchange information. The battery further comprises a charging coupler (108) coupled to the cell through a charging circuit (110) and a communication coupler (112) or antenna coupled to the transceiver.

Abstract: A polar modulation power amplifier circuit includes a control circuit (101) to determine and provide a load selection signal (127), wherein the load selection signal (127) is determined responsive to a requested power signal (119). A power amplifier (113) is responsive to a power control signal (141), for amplifying an RF signal (139) to produce an amplified signal (145), having an output power level. A variable impedance matching circuit (117) is responsive to the load selection signal (127), to adjust a relationship between the control level and the output power level, to produce a range-adjusted amplified signal (147).