Patent application number | Description | Published |
20080211766 | MULTITOUCH DATA FUSION - A method for performing multi-touch (MT) data fusion is disclosed in which multiple touch inputs occurring at about the same time are received to generating first touch data. Secondary sense data can then be combined with the first touch data to perform operations on an electronic device. The first touch data and the secondary sense data can be time-aligned and interpreted in a time-coherent manner. The first touch data can be refined in accordance with the secondary sense data, or alternatively, the secondary sense data can be interpreted in accordance with the first touch data. Additionally, the first touch data and the secondary sense data can be combined to create a new command. | 09-04-2008 |
20080303681 | Methods and systems for providing sensory information to devices and peripherals - Peripherals and data processing systems are disclosed which can be configured to interact based upon sensor data. In at least certain embodiments, a method for sensing motion and orientation information for a device includes receiving a motion event from at least one sensor located in a device. The method further includes determining an orientation for a display of the device. The method further includes determining whether the device is currently moving. The method further includes determining whether the device moves within an angle with respect to a ground reference for a first time period. The method further includes switching the orientation of the display of the device if the device moves in excess of the angle. | 12-11-2008 |
20080309625 | Multiple simultaneous frequency detection - The use of multiple stimulation frequencies and phases to generate an image of touch on a touch sensor panel is disclosed. Each of a plurality of sense channels can be coupled to a column in a touch sensor panel and can have multiple mixers. Each mixer in the sense channel can utilize a circuit capable generating a demodulation frequency of a particular frequency. At each of multiple steps, various phases of selected frequencies can be used to simultaneously stimulate the rows of the touch sensor panel, and the multiple mixers in each sense channel can be configured to demodulate the signal received from the column connected to each sense channel using the selected frequencies. After all steps have been completed, the demodulated signals from the multiple mixers can be used in calculations to determine an image of touch for the touch sensor panel at each frequency. | 12-18-2008 |
20080309626 | Speed/positional mode translations - Gestures for converting from a position control mode to a motion continuation mode are disclosed. A position control mode can be invoked when the user simultaneously places two or more fingers upon a sensor panel. The fingers can then be moved around to effect position control. A motion continuation mode can be invoked when one or more fingers are lifted off (but at least one finger remains in contact with the sensor panel). If the motion continuation mode is invoked, a virtual control ring can be generated, and scrolling of the viewable area or dragging of the cursor or object can continue in a particular direction specified by a velocity vector pointed in the direction of finger movement at the time the motion continuation mode is invoked, and having a magnitude proportional to the velocity of the finger at the time the motion continuation mode was invoked. | 12-18-2008 |
20080309628 | Detection of low noise frequencies for multiple frequency sensor panel stimulation - The identification of low noise stimulation frequencies for detecting and localizing touch events on a touch sensor panel is disclosed. Each of a plurality of sense channels can be coupled to a separate sense line in a touch sensor panel and can have multiple mixers, each mixer using a demodulation frequency of a particular frequency, phase and delay. With no stimulation signal applied to any drive lines in the touch sensor panel, pairs of mixers can demodulate the sum of the output of all sense channels using the in-phase (I) and quadrature (Q) signals of a particular frequency. The demodulated outputs of each mixer pair can be used to calculate the magnitude of the noise at that particular frequency, wherein the lower the magnitude, the lower the noise at that frequency. Several low noise frequencies can be selected for use in a subsequent touch sensor panel scan function. | 12-18-2008 |
20080309629 | Bottom up watershed dataflow method and region-specific segmentation based on historic data - The application of a watershed algorithm to pixels and their touch values obtained from a scan of a touch sensor panel to determine patches corresponding to images of touch is disclosed. Prior to applying the watershed algorithm, background pixels having little or no touch values can be eliminated. A primary merge algorithm can then merge adjacent patches together when the saddle point between them is shallow as compared to the peak represented by the patches. However, if two candidate patches for merging have a total number of pixels below a certain threshold, these two patches may not be merged under the assumption that the patches might have been caused by different fingertips. Conversely, if two candidate patches for merging have a total number of pixels above a certain threshold, these two patches can be merged under the assumption that the patches were caused by a single thumb or palm. | 12-18-2008 |
20080309630 | Techniques for reducing jitter for taps - Distinguishing sloppy taps from sliding motions is disclosed using an algorithm that can take into account both a time instability factor Tinst and a touch instability factor Zinst. A limited amount of motion per frame can be subtracted off immediately following the detection of a touch event. Small lateral motions indicative of a sloppy tap can be suppressed, while fast finger motions indicative of a quick, long cursor movement can immediately pass through the filter without being suppressed by a significant amount. A motion pass-through suppression factor can be applied subtractively to motion in particular direction as a function of Zinst and Tinst, wherein Zinst can represent a suppression value given as a finger speed for a particular percentage change in touch instability per frame, and Tinst can represent a suppression value given as finger speed for a particular tpress. | 12-18-2008 |
20080309631 | Integrated multi-touch surface having varying sensor granularity - This relates to an event sensing device that includes an event sensing panel and is able to dynamically change the granularity of the panel according to present needs. Thus, the granularity of the panel can differ at different times of operation. Furthermore, the granularity of specific areas of the panel can also be dynamically changed, so that different areas feature different granularities at a given time. This also relates to panels that feature different inherent granularities in different portions thereof. These panels can be designed, for example, by placing more stimulus and/or data lines in different portions of the panel, thus ensuring different densities of pixels in the different portions. Optionally, these embodiments can also include the dynamic granularity changing features noted above. | 12-18-2008 |
20080309632 | Pinch-throw and translation gestures - The detection of finger pinch, rotate, and tap gestures along with a translation and optionally liftoff motion to initiate certain actions is disclosed. To detect both the gesture and the translation, a certain amount of gesture scaling speed can be detected along with a certain amount of translation speed and distance traveled. For a finger pinch gesture, the scaling speed can be computed as the dot product of the velocity vectors of two or more fingers coming together. For a finger rotation gesture, the scaling speed can be computed as a cross product of the velocity vectors of the rotating fingers. The translation speed of a gesture can be computed as the average of the velocity vectors of any fingers involved in the gesture. The amount of gesture scaling speed and translation speed needed to trigger the recognition of a combined gesture with translation can be a predetermined ratio. | 12-18-2008 |
20080309634 | Multi-touch skins spanning three dimensions - One or more multi-touch skins can placed along three dimensions of an object. The one or more multi-touch skins enable multi-touch inputs during the operation of the object. The multi-touch inputs can be tracked to monitor the operation of the object and provide feedback to the operator of the object. The one or more multi-touch skins can further enable gestures for configuring and operating the object. The one or more multi-touch skins can also be used to implement any number of GUI interface objects and actions. A multi-touch skin that measures the force of a touch in one or more directions is also provided. | 12-18-2008 |
20080316183 | SWIPE GESTURES FOR TOUCH SCREEN KEYBOARDS - Systems, methods, and devices for interpreting manual swipe gestures as input in connection with touch-sensitive user interfaces that include virtual keyboards are disclosed herein. These allow for a user entering text using the virtual keyboard to perform certain functions using swipes across the key area rather than tapping particular keys. For example, leftward, rightward, upward, and downward swipes can be assigned to inserting a space, backspacing, shifting (as for typing capital letters), and inserting a carriage return and/or new line. Various other mappings are also described. The described techniques can be used in conjunction with a variety of devices, including handheld devices that include touch-screen interfaces, such as desktop computers, tablet computers, notebook computers, handheld computers, personal digital assistants, media players, mobile telephones, and combinations thereof. | 12-25-2008 |
20090160787 | NEGATIVE PIXEL COMPENSATION - Compensation of pixels that generate erroneous readings (so-called “negative pixels”), produced when multiple touch events are generated by the same poorly grounded object on a touch sensor panel is disclosed. To minimize negative pixels, a thicker cover material and/or a lower dielectric constant can be used. Alternatively, narrower drive and sense lines can be employed. To compensate for negative pixels, a predicted negative pixel value can be computed as an indicator of pixels that are likely to be distorted. The negative pixel value for any particular pixel can be computing by summing up the touch output values for pixels in the drive line of that pixel, summing up the touch output values for pixels in the sense line of that pixel, and then multiplying these two sums. The predicted negative pixel value is added to the measured touch output value for the pixel to compensate for artificially negative readings. | 06-25-2009 |
20090167700 | INSERTION MARKER PLACEMENT ON TOUCH SENSITIVE DISPLAY - In accordance with some embodiments, a computer-implemented method is performed at a portable electronic device with a touch screen display. The method can include: displaying graphics on the touch screen display, detecting a finger contact on the touch screen display, and, in response to the detected finger contact, inserting an insertion marker in the graphics at a first location. The method can further include detecting a finger movement on the touch screen display and, irrespective of initial distance from finger to insertion marker on the touch screen display, moving the insertion marker in accordance with the detected finger movement from the first location to a second location in the graphics. | 07-02-2009 |
20090174676 | MOTION COMPONENT DOMINANCE FACTORS FOR MOTION LOCKING OF TOUCH SENSOR DATA - An image jaggedness filter is disclosed that can be used to detect the presence of ungrounded objects such as water droplets or coins, and delay periodic baseline adjustments until these objects are no longer present. To do otherwise could produce inaccurate normalized baseline sensor output values. The application of a global baseline offset is also disclosed to quickly modify the sensor offset values to account for conditions such as rapid temperature changes. Background pixels not part of any touch regions can be used to detect changes to no-touch sensor output values and globally modify the sensor offset values accordingly. The use of motion dominance ratios and axis domination confidence values is also disclosed to improve the accuracy of locking onto dominant motion components as part of gesture recognition. | 07-09-2009 |
20090174679 | Selective Rejection of Touch Contacts in an Edge Region of a Touch Surface - The selective rejection of touch contacts in an edge region of a touch sensor panel is disclosed. In addition, by providing certain exceptions to the rejection of edge contacts, the functionality of the touch sensor panel can be maximized. Contacts in edge bands around the perimeter of a touch sensor panel can be ignored. However, if a contact in the edge band moves beyond a threshold distance or speed, it can be recognized as part of a gesture. To accommodate different finger sizes, the size of the edge band can be modified based on the identification of the finger or thumb. Furthermore, if contacts in the center region of a touch sensor panel track the movement of contacts in the edge band, the contacts in the edge band can be recognized as part of a gesture. | 07-09-2009 |
20090174688 | IMAGE JAGGEDNESS FILTER FOR DETERMINING WHETHER TO PERFORM BASELINE CALCULATIONS - An image jaggedness filter is disclosed that can be used to detect the presence of ungrounded objects such as water droplets or coins, and delay periodic baseline adjustments until these objects are no longer present. To do otherwise could produce inaccurate normalized baseline sensor output values. The application of a global baseline offset is also disclosed to quickly modify the sensor offset values to account for conditions such as rapid temperature changes. Background pixels not part of any touch regions can be used to detect changes to no-touch sensor output values and globally modify the sensor offset values accordingly. The use of motion dominance ratios and axis domination confidence values is also disclosed to improve the accuracy of locking onto dominant motion components as part of gesture recognition. | 07-09-2009 |
20090315830 | KEYSTROKE TACTILITY ARRANGEMENT ON A SMOOTH TOUCH SURFACE - Disclosed are four arrangements for providing tactility on a touch surface keyboard. One approach is to provide tactile feedback mechanisms, such as dots, bars, or other shapes on all or many keys. In another embodiment, an articulating frame may be provided that extends when the surface is being used in a typing mode and retracts when the surface is used in some other mode, e.g., a pointing mode. The articulating frame may provide key edge ridges that define the boundaries of the key regions or may provide tactile feedback mechanisms within the key regions. The articulating frame may also be configured to cause concave depressions similar to mechanical key caps in the surface. In another embodiment, a rigid, non-articulating frame may be provided beneath the surface. A user will then feel higher resistance when pressing away from the key centers, but will feel a softer resistance at the key center. | 12-24-2009 |
20100117961 | DETECTING A PALM TOUCH ON A SURFACE - The detection of a palm touch on a touch surface, such as a mouse surface, is disclosed. A palm touch can be determined as the touch on the touch surface that has a radius exceeding a predetermined palm touch radius. Alternatively, a palm touch can be determined as the touch on the touch surface located beyond the expected distance between finger touches. | 05-13-2010 |
20100117962 | Suppressing Errant Motion Using Integrated Mouse and Touch Information - The suppression of errant motion regarding a mouse is disclosed. Mouse and touch information can be integrated to determine whether a gesture made on a surface of the mouse is errant, such as when a mouse is being moved and the fingers holding the mouse inadvertently move on the mouse surface. A gesture motion that is small relative to mouse motion can be considered errant and therefore at least partially suppressed, while a gesture motion that is large relative to mouse motion can be considered an intended gesture and therefore processed. Similarly, mouse and touch information can be integrated to determine whether a mouse motion is errant, such as when a robust gesture being made on the mouse surface inadvertently moves the mouse. A mouse motion that is small relative to gesture motion can be considered errant and therefore at least partially suppressed, while a mouse motion that is large relative to gesture motion can be considered an intended motion and therefore processed. | 05-13-2010 |
20100117963 | Generating Gestures Tailored to a Hand Resting on a Surface - The generation of gestures tailored to a hand resting on a mouse surface is disclosed. Gestures to be made on the mouse surface can be generated based on the natural pose of a hand resting on the mouse surface so that the gestures are comfortable. Fingers that are appropriately posed on the mouse surface to make a gesture can be identified for that gesture. Alternatively, gestures to be made on the mouse surface can be generated based on a user's preference. The user can identify the fingers that the user wishes to use to make a gesture. | 05-13-2010 |
20100139990 | Selective Input Signal Rejection and Modification - Embodiments are related to user input devices that accept complex user input including a combination of touch and push (or pick) input. Embodiments of the invention provide for selective ignoring or rejection of input received from such devices in order to avoid interpreting unintentional user actions as commands. Furthermore, some input signals can be modified. The selective rejection or modification can be performed by the user interface device itself or by a computing device that includes or is attached to the user interface device. The selective rejection or modification may be performed by a module that processes input signals, performs the necessary rejections and modifications and sends revised input signals to higher level modules. | 06-10-2010 |
20100192109 | Detecting and Interpreting Real-World and Security Gestures on Touch and Hover Sensitive Devices - “Real-world” gestures such as hand or finger movements/orientations that are generally recognized to mean certain things (e.g., an “OK” hand signal generally indicates an affirmative response) can be interpreted by a touch or hover sensitive device to more efficiently and accurately effect intended operations. These gestures can include, but are not limited to, “OK gestures,” “grasp everything gestures,” “stamp of approval gestures,” “circle select gestures,” “X to delete gestures,” “knock to inquire gestures,” “hitchhiker directional gestures,” and “shape gestures.” In addition, gestures can be used to provide identification and allow or deny access to applications, files, and the like. | 07-29-2010 |
20100211920 | Detecting and Interpreting Real-World and Security Gestures on Touch and Hover Sensitive Devices - “Real-world” gestures such as hand or finger movements/orientations that are generally recognized to mean certain things (e.g., an “OK” hand signal generally indicates an affirmative response) can be interpreted by a touch or hover sensitive device to more efficiently and accurately effect intended operations. These gestures can include, but are not limited to, “OK gestures,” “grasp everything gestures,” “stamp of approval gestures,” “circle select gestures,” “X to delete gestures,” “knock to inquire gestures,” “hitchhiker directional gestures,” and “shape gestures.” In addition, gestures can be used to provide identification and allow or deny access to applications, files, and the like. | 08-19-2010 |
20110074725 | Negative Pixel Compensation - Negative pixel compensation in a touch sensor panel is disclosed. The panel can compensate for a negative pixel effect in touch signal outputs due to poor grounding of an object touching the panel. To do so, the panel can reconstruct a captured touch image to remove negative pixel values indicative of the negative pixel effect and compute a composite image from the captured image and the reconstructed image to replace the captured image. In addition or alternatively, the panel can reconstruct a captured touch image to remove negative pixel values indicative of the negative pixel effect and replace the captured image with the reconstructed image. | 03-31-2011 |
20110102333 | Detection of Gesture Orientation on Repositionable Touch Surface - Detection of an orientation of a gesture made on a repositionable touch surface is disclosed. In some embodiments, a method can include detecting an orientation of a gesture made a touch surface of a touch sensitive device and determining whether the touch surface has been repositioned based on the detected gesture orientation. In other embodiments, a method can include setting a window around touch locations captured in a touch image of a gesture made on a touch surface of a touch sensitive device, detecting an orientation of the gesture in the window, and determining whether the touch surface has been repositioned based on the detected gesture orientation. The pixel coordinates of the touch surface can be changed to correspond to the repositioning. | 05-05-2011 |
20110273475 | METHODS AND SYSTEMS FOR PROVIDING SENSORY INFORMATION TO DEVICES AND PERIPHERALS - Peripherals and data processing systems are disclosed which can be configured to interact based upon sensor data. In at least certain embodiments, a method for sensing motion and orientation information for a device includes receiving a motion event from at least one sensor located in a device. The method further includes determining an orientation for a display of the device. The method further includes determining whether the device is currently moving. The method further includes determining whether the device moves within an angle with respect to a ground reference for a first time period. The method further includes switching the orientation of the display of the device if the device moves in excess of the angle. | 11-10-2011 |
20120011462 | Swipe Gestures for Touch Screen Keyboards - Systems, methods, and devices for interpreting manual swipe gestures as input in connection with touch-sensitive user interfaces that include virtual keyboards are disclosed herein. These allow for a user entering text using the virtual keyboard to perform certain functions using swipes across the key area rather than tapping particular keys. For example, leftward, rightward, upward, and downward swipes can be assigned to inserting a space, backspacing, shifting (as for typing capital letters), and inserting a carriage return and/or new line. Various other mappings are also described. The described techniques can be used in conjunction with a variety of devices, including handheld devices that include touch-screen interfaces, such as desktop computers, tablet computers, notebook computers, handheld computers, personal digital assistants, media players, mobile telephones, and combinations thereof. | 01-12-2012 |
20120019452 | TOUCH INPUT TRANSITIONS - Selection of input of a touch sensing surface is provided. Contacts on or near a surface are tracked to obtain touch information of the contacts. A first gesture is detected corresponding to first touch information of a number of contacts performing an activity, and a first input corresponding to the first gesture is selected. A second gesture is detected corresponding to second touch information of a number of contacts performing an activity. A determination of whether to select a second input corresponding to the second gesture is made. The second input is selected if third information satisfies a predetermined criteria, and the first input is maintained if the third information does not satisfy the predetermined criteria. | 01-26-2012 |
20120019453 | MOTION CONTINUATION OF TOUCH INPUT - Motion continuation of an input is provided. A motion of an input can be tracked based on contacts on a touch sensing surface. The input motion can be continued when one or more of the contacts lifts off from the surface by determining the liftoff of the one or more of the contacts during the input, determining a speed at the liftoff, selecting, based on the speed at liftoff, one of a plurality of decay rates corresponding to a plurality of ranges of speed, and continuing the motion of the input based on the selected decay rate. After motion of the input is continued based on speed at liftoff, the system can determine that the continued motion reaches a next-lower range of speed, the decay rate can be reset based on the decay rate of the next-lower range, and motion can be continued based on the reset decay rate. | 01-26-2012 |
20120162066 | METHODS AND SYSTEMS FOR PROVIDING SENSORY INFORMATION TO DEVICES AND PERIPHERALS - Peripherals and data processing systems are disclosed which can be configured to interact based upon sensor data. In at least certain embodiments, a method for sensing motion and orientation information for a device includes receiving a motion event from at least one sensor located in a device. The method further includes determining an orientation for a display of the device. The method further includes determining whether the device is currently moving. The method further includes determining whether the device moves within an angle with respect to a ground reference for a first time period. The method further includes switching the orientation of the display of the device if the device moves in excess of the angle. | 06-28-2012 |