Abstract: A MEMS/MOEMS sensor and method for using such sensor to detect a person's breath or other fluid for purposes of controlling a user interface of an electronic device.

Abstract: Aspects of a method and system for interfacing with an electronic device via respiratory and/or tactual input are provided. In this regard, respiratory and tactual input may be utilized to interact with an electronic device via a user interface. The user interface may comprise a control region that may enable navigating and selecting objects, a fixed region that may enable display of information that may be independent of a state of, or activity in, the control region, and a content region that may enable display of information that may depend on a state of, or activity in, the control region. Accordingly, objects and/or information displayed on the electronic device may be affected and/or manipulated via tactual and respiratory input. Additionally, each region of the user interface may comprise one or more zones and a size, shape, and/or location of each region may be customized by a user.

Abstract: A device to facilitate a user interface of a computer system utilizing breath includes a body, a user side inlet defined by the body to receive a fluid flow generated by a user, an exhaust opening defined by the body, a conduit positioned between the user side inlet and the one exhaust opening, at least one segment positioned inside the body and one or more contactors positioned to be intermittently in contact with the at least one segment. The contact may occur responsive to the fluid flow generated by the user. The device may include a sensor to react to a movement of the at least one segment.

Abstract: A method and system for processing signals for a MEMS detector that enables control of a device using expulsion of air via human breath, a machine and/or a device are provided. A microprocessor may receive one or more signals from the MEMS detector that may comprise various component sensor(s), sensing member(s) or sensing segment(s) that may detect movement of air caused by the expulsion of human breath. The signals may be processed by the microprocessor and an interactive output comprising one or more control signals that may enable control of a user interface such as 107a-107e on the multimedia device 106a-106e may be generated. For each component sensor(s), sensing member(s) or sensing segment(s) in the MEMS detector, ranges or gradients may be measured and evaluated to determine which of the sensor(s), sensing member(s) or sensing segment(s) of the MEMS detector 212 may have been activated, moved or deflected.

Abstract: A method and system for processing signals for a MEMS detector that enables control of a device using expulsion of air via human breath, a machine and/or a device are provided. A microprocessor may receive one or more signals from the MEMS detector that may comprise various component sensor(s), sensing member(s) or sensing segment(s) that may detect movement of air caused by the expulsion of human breath. The signals may be processed by the microprocessor and an interactive output comprising one or more control signals that may enable control of a user interface such as 107a-107e on the multimedia device 106a-106e may be generated. For each component sensor(s), sensing member(s) or sensing segment(s) in the MEMS detector, ranges or gradients may be measured and evaluated to determine which of the sensor(s), sensing member(s) or sensing segment(s) of the MEMS detector 212 may have been activated, moved or deflected.

Abstract: Aspects of a method and system for reliable and fast mobile marketing are provided. In this regard, a mobile marketing device may redeem at a point of sales, one or more coupons that are received by a user device. The mobile marketing device may verify the redeemed one or more coupons based on a generated secure unique code corresponding to each of the redeemed one or more coupons. The mobile marketing device may schedule payment associated with a monetary value of each of the redeemed one or more coupons to a retailer based on the verification of the redeemed one or more coupons with the generated secure unique code.

Abstract: Certain aspects of a method and system for controlling a user interface of a device using human breath may include detecting movement caused by expulsion of human breath by a user. In response to the detection of movement caused by expulsion of human breath, one or more control signals may be generated. The generated control signals may control the user interface of a device and may enable navigation and/or selection of components in the user interface. The generated one or more control signals may be communicated to the device being controlled via a wired and/or a wireless signal. The expulsion of the human breath may occur in open space and the detection of the movement caused by the expulsion may occur without the use of a channel. The detection of the movement and/or the generation of the control signals may be performed by a MEMS detector or sensor.

Abstract: Certain aspects of a method and system for controlling a user interface of a device using human breath may include a device comprising an embedded micro-electro-mechanical system (MEMS) sensing and processing module. The MEMS sensing and processing module may detect movement caused by expulsion of human breath by a user. In response to the detection of movement caused by expulsion of human breath, one or more control signals may be generated. The generated control signals may control the user interface of the device and may enable navigation and/or selection of components in the user interface.

Abstract: Certain aspects of a method and system for controlling a user interface of a device using human breath may include detecting movement caused by expulsion of human breath by a user. In response to the detection of movement caused by expulsion of human breath, one or more control signals may be generated. The generated control signals may control the user interface of a device and may enable navigation and/or selection of components in the user interface. The generated one or more control signals may be communicated to the device being controlled via a wired and/or a wireless signal. The expulsion of the human breath may occur in open space and the detection of the movement caused by the expulsion may occur without the use of a channel. The detection of the movement and/or the generation of the control signals may be performed by a MEMS detector or sensor.

Abstract: Aspects of a system and method for seamlessly integrated navigation of applications are provided. A communication device comprising a display enabled to display media content may be operable to receive a first stimulus in a pre-defined section of the display. The communication device may be operable to display a semi-transparent interaction grid that is superimposed onto the content based on the received first stimulus. The communication device may enable one or more applications in the displayed semi-transparent interaction grid based on one or more received stimuli.

Abstract: A device, to facilitate a user control of a computer system, includes a movable portion movable by a fluid flow of a generated by a user of the device, and a converter to convert movement of the movable portion into an electrical signal to facilitate control of the computer system.

Abstract: Aspects of a method and system for interfacing with an electronic device via respiratory and/or tactual input are provided. In this regard, respiratory and tactual input may be utilized to interact with an electronic device via a user interface. The user interface may comprise a control region that may enable navigating and selecting objects, a fixed region that may enable display of information that may be independent of a state of, or activity in, the control region, and a content region that may enable display of information that may depend on a state of, or activity in, the control region. Accordingly, objects and/or information displayed on the electronic device may be affected and/or manipulated via tactual and respiratory input. Additionally, each region of the user interface may comprise one or more zones and a size, shape, and/or location of each region may be customized by a user.

Abstract: Methods and systems for a MEMS detector that enables control of a device using human breath are disclosed and may include detecting air flow caused by human breath via a microelectromechanical systems (MEMS) detector, which may include deflectable members operable to detect the movement of air. The deflection of the members may be limited via a spacer within the MEMS detector. The amount of deflection may be determined by measuring reflected light signals, piezoelectric signals, capacitance changes, or current generated by the deflection in a magnetic field. Output signals may be generated based on the detected movement. The MEMS detector may include a substrate, a spacer, and the MEMS deflectable members. The substrate may include a ceramic material and/or silicon, and may include embedded devices and interconnects. An integrated circuit may be electrically coupled to the substrate. Air flows may be directed out of the side of the MEMS detector.

Abstract: Certain aspects of a method and system for processing signals that control a device using human breath may include receiving at the device, one or more signals from a detection device operable to function as a human interface device (HID). The signals may be generated in response to detection of movement of air caused by expulsion of human breath. Human interfacing with a graphical user interface (GUI) of the device may be enabled via the received signals. The detection device may comprise a micro-electro-mechanical system (MEMS) detector. The received signals may be formatted into a HID profile. The HID profile may comprise one or more drivers and/or libraries that enables the interfacing with the GUI of the device. The drivers may enable one or more of initiation, establishment and/or termination of communication by the device.

Abstract: A method and system are provided for a user interface that enables control of a device via respiratory and/or tactual input. A mobile device comprising a graphical user interface may receive data from a second device and/or locally from within the mobile device. The data may be associated with and/or mapped to multimedia content that may be retrievable from a content source. The content source may be external to the mobile device and the second device. The associating and/or mapping may occur at either the mobile device or the second device and the associated or mapped data may be operable to function as at least a portion of the graphical user interface of the mobile device. The graphical user interface may be customized utilizing the data that is associated and/or mapped to the media content. The second device may map the received data to the media content.

Abstract: A device, to facilitate a user control of a computer system, includes a movable portion movable by a fluid flow of a generated by a user of the device, and a converter to convert movement of the movable portion into an electrical signal to facilitate control of the computer system.

Abstract: The invention relates to a musical instrument having free reeds set into vibration by a flow of air generated by a supply (17) and capable of flowing from the supply in two directions referred to respectively as in and out, the instrument comprising: at least two boxes (2, 3) that are movable relative to each other by moving towards each other or apart from each other; a series of free reeds (27) mounted inside said boxes; and a valve actuator mechanism (31) where opening and closing the valves enables the reeds to be engaged or not engaged by the flow of air, the mechanism including in particular actuator keys (11) mounted on the moving boxes. The instrument of the invention includes means (5) for supporting and guiding displacement of the boxes relative to each other along a determined trajectory.

Abstract: A method and system for processing signals for a MEMS detector that enables control of a device using expulsion of air via human breath, a machine and/or a device are provided. A microprocessor may receive one or more signals from the MEMS detector that may comprise various component sensor(s), sensing member(s) or sensing segment(s) that may detect movement of air caused by the expulsion of human breath. The signals may be processed by the microprocessor and an interactive output comprising one or more control signals that may enable control of a user interface such as 107a-107e on the multimedia device 106a-106e may be generated. For each component sensor(s), sensing member(s) or sensing segment(s) in the MEMS detector, ranges or gradients may be measured and evaluated to determine which of the sensor(s), sensing member(s) or sensing segment(s) of the MEMS detector 212 may have been activated, moved or deflected.

Abstract: Certain aspects of a method and system for controlling a user interface of a device using human breath may include detecting movement caused by expulsion of human breath by a user. In response to the detection of movement caused by expulsion of human breath, one or more control signals may be generated. The generated control signals may control the user interface of a device and may enable navigation and/or selection of components in the user interface. The generated one or more control signals may be communicated to the device being controlled via a wired and/or a wireless signal. The expulsion of the human breath may occur in open space and the detection of the movement caused by the expulsion may occur without the use of a channel. The detection of the movement and/or the generation of the control signals may be performed by a MEMS detector or sensor.

Abstract: A device to facilitate a user interface of a computer system utilizing breath includes a body, a user side inlet defined by the body to receive a fluid flow generated by a user, an exhaust opening defined by the body, a conduit positioned between the user side inlet and the one exhaust opening, at least one segment positioned inside the body and one or more contactors positioned to be intermittently in contact with the at least one segment. The contact may occur responsive to the fluid flow generated by the user. The device may include a sensor to react to a movement of the at least one segment.