Abstract: A method and system for detecting whether the position of a user's hand gripping a mobile communication device chassis affects an external antenna is provided. A sectioned metal band about a periphery of a mobile communication device has a radiating antenna in at least one metal section. The radiating antenna section is bounded on both sides by electrically floating metal sections. Each of the electrically floating metal sections is bounded on the side distal from the antenna section by a ground metal section. Each metal section separated from an adjacent metal section by an insulating gap. Embodiments measure a differential capacitance between the antenna section and the floating metal section and measure a single and capacitance between the floating metal section and the grounded section to determine whether a user's hand is bridging one or more of the insulating gaps.

Abstract: A method and system performs antenna tuning using detected changes in antenna self-capacitance in a wireless communication device. A modem detects changes in antenna self-capacitance by utilizing multiple antenna elements. The modem determines a current antenna loading condition using the detected changes in antenna self-capacitance. The modem determines appropriate tuning states for each antenna matching and tuning circuit (AMTC) associated with a respective antenna element. In order to determine the appropriate tuning states, the modem utilizes pre-established antenna self-capacitance information which is mapped to antenna tuning states. The antenna tuning states which are respectively mapped to pre-established antenna self-capacitance are empirically pre-determined by correlating antenna self-capacitance changes to antenna impedance changes.

Abstract: A method and system for detecting whether the position of a user's hand gripping a mobile communication device chassis affects an external antenna is provided. A sectioned metal band about a periphery of a mobile communication device has a radiating antenna in at least one metal section. The radiating antenna section is bounded on both sides by electrically floating metal sections. Each of the electrically floating metal sections is bounded on the side distal from the antenna section by a ground metal section. Each metal section separated from an adjacent metal section by an insulating gap. Embodiments measure a differential capacitance between the antenna section and the floating metal section and measure a single and capacitance between the floating metal section and the grounded section to determine whether a user's hand is bridging one or more of the insulating gaps.

Abstract: A method and system performs antenna tuning using detected changes in antenna self-capacitance in a wireless communication device. A modem detects changes in antenna self-capacitance by utilizing multiple antenna elements. The modem determines a current antenna loading condition using the detected changes in antenna self-capacitance. The modem determines appropriate tuning states for each antenna matching and tuning circuit (AMTC) associated with a respective antenna element. In order to determine the appropriate tuning states, the modem utilizes pre-established antenna self-capacitance information which is mapped to antenna tuning states. The antenna tuning states which are respectively mapped to pre-established antenna self-capacitance are empirically pre-determined by correlating antenna self-capacitance changes to antenna impedance changes.

Abstract: A method of operating an electronic device, and an electronic device, are disclosed in which occurrences of unintended operations of the electronic device, such as can occur in response to inadvertent actuations of actuators of the electronic device, are reduced. In one example embodiment, the method 500 includes detecting 510 an actuation of a first sensor that is associated with a first touch-sensitive component of the electronic device, and acquiring 512 data from an additional sensor of the electronic device. The method also includes determining 518, based at least in part upon the data, whether the actuation is valid, and either performing 524 or refraining 522 from performing at least one operation based at least in part upon the determining. In at least one additional embodiment, the first sensor is a piezoelectric sensor and the additional sensor is an accelerometer.

Abstract: A portable electronic device comprising an external surface of a user interface, a piezoelectric transducer coupled to the external surface, and a controller. The piezoelectric transducer generates an electrical output originating at the piezoelectric transducer in response to mechanical actuation applied at the external surface. The controller performs an electronic function of the portable electronic device in response to the piezoelectric transducer generating the electrical output.

Abstract: There is described portable electronic devices having one or more proximity sensors with adaptive capabilities that can help reduce power consumption. The proximity sensors of the portable electronic device in accordance with the present invention may be adjusted to operate in multiple and/or different modes. These modes are environmentally and contextually driven. An adaptive sensor is dynamically adjusted based on different criteria. In particular, adjustments are based on correlations of input signals from one or more sensors of the device, data signals received from the device's processor and/or external data signals received from an external source, which provide characterization values of environmental, contextual and/or ambient light characteristics. Adjustments are made to pulse power to affect the range of the sensor, pulse frequency, filtering of noise of the sensor input signal to attenuate interference and the spectrum of a proximity detector.

Abstract: A method of operating an electronic device, and an electronic device, are disclosed in which occurrences of unintended operations of the electronic device, such as can occur in response to inadvertent actuations of actuators of the electronic device, are reduced. In one example embodiment, the method 500 includes detecting 510 an actuation of a first sensor that is associated with a first touch-sensitive component of the electronic device, and acquiring 512 data from an additional sensor of the electronic device. The method also includes determining 518, based at least in part upon the data, whether the actuation is valid, and either performing 524 or refraining 522 from performing at least one operation based at least in part upon the determining. In at least one additional embodiment, the first sensor is a piezoelectric sensor and the additional sensor is an accelerometer.

Abstract: A portable electronic device comprising an external surface of a user interface, a piezoelectric transducer coupled to the external surface, and a controller. The piezoelectric transducer generates an electrical output originating at the piezoelectric transducer in response to mechanical actuation applied at the external surface. The controller performs an electronic function of the portable electronic device in response to the piezoelectric transducer generating the electrical output.

Abstract: A portable electronic device having one or more proximity sensors. The portable electronic device comprises a housing, one or more signal emitters to direct source signal(s) based on the orientation of the housing, and one or more signal receivers to receive return signals corresponding to the source signal(s). The device may include multiple signal emitters and a sensor to identify an orientation of the housing. The appropriate signal emitter may be selected based on the orientation of the housing as identified by the sensor.

Abstract: There is described portable electronic devices having one or more proximity sensors with adaptive capabilities that can help reduce power consumption. The proximity sensors of the portable electronic device in accordance with the present invention may be adjusted to operate in multiple and/or different modes. These modes are environmentally and contextually driven. An adaptive sensor is dynamically adjusted based on different criteria. In particular, adjustments are based on correlations of input signals from one or more sensors of the device, data signals received from the device's processor and/or external data signals received from an external source, which provide characterization values of environmental, contextual and/or ambient light characteristics. Adjustments are made to pulse power to affect the range of the sensor, pulse frequency, filtering of noise of the sensor input signal to attenuate interference and the spectrum of a proximity detector.

Abstract: There is described portable electronic devices having one or more proximity sensors with adaptive capabilities that can help reduce power consumption. The proximity sensors of the portable electronic device in accordance with the present invention may be adjusted to operate in multiple and/or different modes. These modes are environmentally and contextually driven. An adaptive sensor is dynamically adjusted based on different criteria. In particular, adjustments are based on correlations of input signals from one or more sensors of the device, data signals received from the device's processor and/or external data signals received from an external source, which provide characterization values of environmental, contextual and/or ambient light characteristics. Adjustments are made to pulse power to affect the range of the sensor, pulse frequency, filtering of noise of the sensor input signal to attenuate interference and the spectrum of a proximity detector.

Abstract: A portable electronic device having one or more proximity sensors. The portable electronic device comprises a housing, one or more signal emitters to direct source signal(s) based on the orientation of the housing, and one or more signal receivers to receive return signals corresponding to the source signal(s). For one embodiment, the device may include multiple signal emitters and a sensor to identify an orientation of the housing. The appropriate signal emitter may be selected based on the orientation of the housing as identified by the sensor. For another embodiment, the device may include a mechanism to redirect a source signal from a signal emitter in an appropriate direction based on the orientation of the housing.

Abstract: An optical communication system is provided for conveying signals between multiple housing elements of a device, where respective optical detectors and optical light sources interact via respective point to point communication paths, where the point to point communication path is maintained while the multiple housing elements of the device move relative to one another. In at least some instances, the multiple housing elements correspond to at least a pair of housing elements that are incorporated as part of a communication device having a slider configuration. In some of the same or still further instances, the point to point communication paths correspond to channels formed between the multiple housing elements, which in some instances may be at least partially recessed within one or both of the housing elements. In some instances the channels may traverse free space. In still further instances the channel may include a light pipe.

Abstract: A portable electronic device having one or more proximity sensors. The portable electronic device comprises a housing, one or more signal emitters to direct source signal(s) based on the orientation of the housing, and one or more signal receivers to receive return signals corresponding to the source signal(s). The device may include multiple signal emitters and a sensor to identify an orientation of the housing. The appropriate signal emitter may be selected based on the orientation of the housing as identified by the sensor.

Abstract: A method of a portable electronic device for self-calibration of a proximity sensor. A background measurement is obtained by the proximity sensor and a detection threshold of the proximity sensor is adjusted based on the background measurement. The background measurement is a measure of a received signal when no signal is transmitted by the proximity sensor, and the detection threshold is associated with a sensitivity of the proximity sensor to environmental conditions. A source signal is emitted by the proximity sensor based on the adjusted detection threshold of the proximity sensor, and a return signal is received by the proximity sensor corresponding to the source signal. A function of the portable electronic device may be performed base don the received return signal.

Abstract: There is described portable electronic devices having one or more proximity sensors with adaptive capabilities that can help reduce power consumption. The proximity sensors of the portable electronic device in accordance with the present invention may be adjusted to operate in multiple and/or different modes. These modes are environmentally and contextually driven. An adaptive sensor is dynamically adjusted based on different criteria. In particular, adjustments are based on correlations of input signals from one or more sensors of the device, data signals received from the device's processor and/or external data signals received from an external source, which provide characterization values of environmental, contextual and/or ambient light characteristics. Adjustments are made to pulse power to affect the range of the sensor, pulse frequency, filtering of noise of the sensor input signal to attenuate interference and the spectrum of a proximity detector.

Abstract: A portable electronic device having one or more proximity sensors. The portable electronic device comprises a housing, one or more signal emitters to direct source signal(s) based on the orientation of the housing, and one or more signal receivers to receive return signals corresponding to the source signal(s). For one embodiment, the device may include multiple signal emitters and a sensor to identify an orientation of the housing. The appropriate signal emitter may be selected based on the orientation of the housing as identified by the sensor. For another embodiment, the device may include a mechanism to redirect a source signal from a signal emitter in an appropriate direction based on the orientation of the housing.

Abstract: A method of a portable electronic device for self-calibration of a proximity sensor. A background measurement is obtained by the proximity sensor and a detection threshold of the proximity sensor is adjusted based on the background measurement. The background measurement is a measure of a received signal when no signal is transmitted by the proximity sensor, and the detection threshold is associated with a sensitivity of the proximity sensor to environmental conditions. A source signal is emitted by the proximity sensor based on the adjusted detection threshold of the proximity sensor, and a return signal is received by the proximity sensor corresponding to the source signal. A function of the portable electronic device may be performed base don the received return signal.

Abstract: An optical communication system is provided for conveying signals between multiple housing elements of a device, where respective optical detectors and optical light sources interact via respective point to point communication paths, where the point to point communication path is maintained while the multiple housing elements of the device move relative to one another. In at least some instances, the multiple housing elements correspond to at least a pair of housing elements that are incorporated as part of a communication device having a slider configuration. In some of the same or still further instances, the point to point communication paths correspond to channels formed between the multiple housing elements, which in some instances may be at least partially recessed within one or both of the housing elements. In some instances the channels may traverse free space. In still further instances the channel may include a light pipe.