PATENT DOCUMENT

Publication Number: US-8395590-B2
Application Number: US-47592509-A
Country: US
Kind Code: B2

Title: Integrated contact switch and touch sensor elements

Abstract:
An input device providing integrated contact switch and touch sensor elements is disclosed. A contact switch and touch sensor can be integrated so that they share a common sensor line, achieving space, cost and manufacturing savings over input devices that utilize distinct sensor lines for each of its sensor elements. By configuring a contact switch and touch sensor to share a common sensor line, a controller can use a single pin to scan both the contact switch and touch sensor elements, rather than using distinct pins to scan distinct sensor lines associated with each sensor element. By using fewer pins to scan the same number of sensor elements, a smaller controller can be used which can reduce the size and cost of the input device, and increase manufacturing throughput time associated with the input device.

Claims:
1. A method comprising:
 providing a common sensor line connected to a touch sensor element arranged on a first surface of a substrate and a contact switch element arranged on a second surface of the substrate, 
 capturing scan data based on a scan of the common sensor line for push button input, and 
 estimating scan data for the touch sensor element if the captured scan data indicates push button input. 
 
     
     
       2. The method of  claim 1 , wherein the estimated scan data is based on scan data associated with the touch sensor element from one or more previous scan cycles. 
     
     
       3. The method of  claim 1 , wherein the estimated scan data is based on captured scan data associated with neighboring touch sensor elements. 
     
     
       4. The method of  claim 3 , wherein the estimated scan data is based on an average of the captured scan data associated with the neighboring touch sensor elements. 
     
     
       5. A method comprising:
 capturing scan data from a sensor line common to a touch sensor element arranged on a first surface of a substrate and a contact switch element arranged on a second surface of the substrate, 
 determining that a touch input has occurred if the scan data lies between a first threshold level and a second threshold level, and 
 disregarding the scan data if the scan data exceeds the second threshold level. 
 
     
     
       6. The method of  claim 5 , wherein the scan data indicates a level of capacitance associated with the touch sensor element. 
     
     
       7. The method of  claim 5 , wherein scan data exceeding the second threshold indicates that the contact switch element is being pressed. 
     
     
       8. The method of  claim 5 , further comprising
 disregarding the scan data if the scan data falls below a third threshold level. 
 
     
     
       9. The method of  claim 8 , wherein the third threshold level indicates a noise threshold. 
     
     
       10. An input device comprising:
 a substrate comprising a first surface and a second surface, 
 a touch sensor element arranged on the first surface of the substrate, 
 a contact switch element arranged on the second surface of the substrate, 
 a common sensor line connected to the touch sensor element and the contact switch element, and 
 a controller configured to
 capture scan data based on a scan of the common sensor line for push button input, and 
 estimate scan data for the touch sensor element if the captured scan data indicates push button input. 
 
 
     
     
       11. The input device of  claim 10 , wherein the estimated scan data is based on scan data associated with the touch sensor element from one or more previous scan cycles. 
     
     
       12. The input device of  claim 10 , wherein the estimated scan data is based on captured scan data associated with neighboring touch sensor elements. 
     
     
       13. The input device of  claim 12 , wherein the estimated scan data is based on an average of the captured scan data associated with the neighboring touch sensor elements. 
     
     
       14. An input device comprising:
 a substrate comprising a first surface and a second surface, 
 a touch sensor element arranged on the first surface of the substrate, 
 a contact switch element arranged on the second surface of the substrate, 
 a sensor line common to the touch sensor element and the contact switch element, and 
 a controller configured to
 capture scan data from the sensor line, 
 determine that a touch input has occurred if the scan data lies between a first threshold level and a second threshold level, and 
 disregard the scan data if the scan data exceeds the second threshold level. 
 
 
     
     
       15. The input device of  claim 14 , wherein the scan data indicates a level of capacitance associated with the touch sensor element. 
     
     
       16. The input device of  claim 14 , wherein scan data exceeding the second threshold indicates that the contact switch element is being pressed. 
     
     
       17. The input device of  claim 14 , wherein the controller is configured to disregard the scan data if the scan data falls below a third threshold level. 
     
     
       18. The input device of  claim 17 , wherein the third threshold level indicates a noise threshold.

Description:
CROSS REFERENCE TO RELATED APPLICATION 
     This claims priority under 35 USC 119(e) to U.S. Provisional Application No. 61/138,524, filed Dec. 17, 2008, and U.S. Provisional Application No. 61/165,188, filed Mar. 31, 2009, the entireties of which are incorporated herein by reference. 
    
    
     FIELD OF THE DISCLOSURE 
     This relates generally to input devices, including input devices with shared contact switch and touch sensor lines. 
     BACKGROUND 
     Several kinds of input devices exist for performing operations in an electronic device. Some examples of input devices include buttons, switches, keyboards, mice, trackballs, touch pads, joy sticks, touch screens and the like. Some examples of electronic devices include media players, remote controls, personal digital assistants (PDAs), cellular phones, etc. Operations performed by the input devices generally include moving a cursor or highlighted portions of a display and selecting displayed items. 
     As electronic devices have evolved, they have tended to decrease in size and provide increased features. Their decreasing size can impact the space available for input devices and power sources, such as batteries for example, to support the increased features. Accordingly, the design of input devices for electronic devices can be constrained by efforts to decrease the overall size of the electronic device and conserve a limited supply of power. 
     SUMMARY 
     An input device is disclosed that provides integrated contact switch and touch sensor elements. By integrating a contact switch and touch sensor so that they share a common sensor line, the input device can achieve space and cost savings over those that utilize distinct sensor lines for each of its sensor elements, and increased manufacturing throughput time. 
     For example, contact switch and touch sensor elements can be scanned by a controller to detect whether an input sensed by those elements has occurred. To enable this scanning, a sensor line associated with both the contact switch element and the touch sensor element can be connected to the controller through the controller&#39;s pins. The pins act as an interface through which the controller can scan the sensor elements. 
     By configuring a contact switch and touch sensor to share a common sensor line, a controller can use a single pin to scan both the contact switch and touch sensor elements, rather than using distinct pins to scan distinct sensor lines associated with each sensor element. By using fewer pins to scan the same number of sensor elements, a smaller controller can be used, which can reduce the size and cost of the input device, and increase manufacturing throughput time associated with the input device. 
     The ways in which the controller can be configured to detect input sensed by the integrated contact switch and touch sensor may be widely varied. Since sensor readings associated with the contact switch element can adversely affect sensor readings associated with the touch sensor element due to the use of a common sensor line, the controller can be configured to compensate for these adverse effects. Additionally, the controller&#39;s scan cycle can be optimized to account for the common sensor line configuration. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  illustrates an example of an electronic device. 
         FIG. 2  illustrates an example of an electronic device. 
         FIG. 3  illustrates an example of an integrated contact switch and touch sensor configuration. 
         FIG. 4  illustrates an example of a first conductive layer of an input device. 
         FIG. 5  illustrates an example of a second conductive layer of an input device. 
         FIG. 6  illustrates an example of a third conductive layer of an input device. 
         FIG. 7  illustrates an example of a first conductive layer of an input device. 
         FIG. 8  illustrates an example of a second conductive layer of an input device. 
         FIG. 9  illustrates an example of a third conductive layer of an input device. 
         FIG. 10  illustrates an example of three conductive layers of an input device. 
         FIG. 11  illustrates an example configuration of an integrated contact switch and touch sensor. 
         FIG. 12  illustrates an example operation of an integrated contact switch and touch sensor. 
         FIG. 13  illustrates an example configuration of an integrated contact switch and touch sensor. 
         FIG. 14  illustrates an example operation of an integrated contact switch and touch sensor. 
         FIGS. 15-17  illustrate examples of scanning processes. 
         FIG. 18  illustrates an example of a sensing process. 
         FIGS. 19-21  illustrate examples of sensing circuits. 
         FIG. 22  illustrates an example of a 15-element capacitive sensor element arrangement. 
         FIG. 23  illustrates an example of a 9-element capacitive sensor element arrangement. 
         FIG. 24  illustrates an example of 30-element capacitive sensor element arrangement. 
         FIGS. 25-27  illustrate an example of operations of an input device. 
         FIG. 28  illustrates an example of an input device. 
         FIG. 29  illustrates an example of a computing system. 
         FIGS. 30-33  illustrate examples of applications of input devices. 
     
    
    
     DETAILED DESCRIPTION 
     The present disclosure describes embodiments of an input device with shared contact switch and touch sensor lines. By integrating a contact switch and touch sensor so that they share a common sensor line, the input device can achieve space, cost and manufacturing savings over those that utilize distinct sensor lines for each of its sensor elements. 
       FIG. 1  illustrates an example of an electronic device. The electronic device may be any consumer electronic product. The electronic device may be a computing device and more particularly it may be a media player, PDA, phone, remote control, camera and the like. In the embodiment illustrated in  FIG. 1 , electronic device  100  may correspond to a media player. The term “media player” generally refers to computing devices for processing media, such as audio, video or other images, including, for example, music players, game players, video players, video recorders and the like. These devices can be portable to allow a user to, for example, listen to music, play games or video, record video or take pictures wherever the user travels. In one embodiment, the electronic device can be a handheld device that is sized for placement into a pocket of the user. By being pocket sized, the device may be taken almost anywhere the user travels (e.g., the user is not limited by carrying a large, bulky and often heavy device, as in a portable computer). Furthermore, the device can be operated in the user&#39;s hands, thus no reference surface such as a desktop is required. 
     Electronic devices (e.g., media players) generally have connection capabilities that allow a user to upload and download data to and from a host device, such as a general purpose computer (e.g., desktop computer, portable computer, etc.). For example, in the case of a camera, photo images can be downloaded to the general purpose computer for further processing (e.g., printing). With regard to music players, for example, songs and play lists stored on the general purpose computer can be downloaded into the music player. In the embodiment illustrated in  FIG. 1 , electronic device  100  can be a pocket-sized hand-held media player (e.g., MP3 player) that allows a user to store a collection of music, photos, album art, contacts, calendar entries, and other desirable media assets. It should be appreciated however, that media players are not a limitation as the electronic device may be embodied in other forms as mentioned above. 
     As shown in  FIG. 1 , electronic device  100  may include housing  110  that can enclose various electrical components, such as integrated circuit chips and other circuitry, for example. The integrated circuit chips and other circuitry may include, for example, a microprocessor, memory (e.g., ROM, RAM), a power supply (e.g., battery), a circuit board, a hard drive or Flash (e.g., Nand flash) for storing media for example, one or more orientation detection elements (e.g., accelerometer) and various input/output (I/O) support circuitry. In the case of music players, the electrical components can include components for outputting music such as an amplifier and a digital signal processor (DSP) for example. In the case of video recorders or cameras the electrical components can include components for capturing images such as image sensors (e.g., charge coupled device (CCD) or complimentary oxide semiconductor (CMOS)) or optics (e.g., lenses, splitters, filters) for example. In addition to the above, the housing can also define the shape or form of the electronic device. That is, the contour of housing  102  may embody the outward physical appearance of electronic device  100  in one embodiment. 
     Electronic device  100  may also include display screen  120 . Display screen  120  can be used to display a graphical user interface as well as other information to the user (e.g., text, objects, graphics). For example, display screen  120  may be a liquid crystal display (LCD). In one embodiment, the display screen can correspond to a X-by-Y pixel high-resolution display, with a white LED backlight to give clear visibility in daylight as well as low-light conditions. Display screen  120  can also exhibit a “wide screen” aspect ratio (e.g., similar to a 16:9 aspect ratio) such that it may be relatively easy to perceive portrait and landscape orientations. 
     Electronic device  100  may also include input device  130 . Input device  130  can be configured to provide one or more control functions for controlling various applications associated with electronic device  100 . For example, a control function can be used to move an object or perform an action on display screen  120  or to make selections or issue commands associated with operating electronic device  100 . Input device  130  may be widely varied. In one embodiment, input device  130  may include a combination of a rigid sensor mechanism and one or more movable sensor mechanisms for detecting input. The rigid sensor mechanism can include, for example, a touch sensitive surface that provides location information for an object, such as a finger for example, in contact with or in proximity to a touch sensor element associated with the touch sensitive surface. The movable sensor mechanism can include, for example, one or more moving members comprising contact switch elements that actuate a switch when a particular area of input device  130  is pressed. The movable sensor mechanism may operate as a mechanical push button and perform a clicking action when actuated. 
       FIG. 2  illustrates an embodiment of an electronic device without a display screen. In the embodiment illustrated in  FIG. 2 , electronic device  200  may include housing  210  that may generally correspond to housing  110 , and input device  230  that may generally correspond to input device  130 . The lack of a display screen allows electronic device  200  to be configured with smaller dimensions than those of electronic device  100 . For example, in one embodiment, electronic device  200  may be less than two inches wide and less than two inches tall. 
       FIG. 3  illustrates an example of an integrated contact switch and touch sensor configuration. Touch sensor element  310  and contact switch element  320  can share common sensor line  330 . Common sensor line  330  can connect to pin  305  of controller  300 , which can be configured to scan the common sensor line to detect an input associated with touch sensor element  310  or contact switch element  320 . 
     The arrangement of touch sensor element  310  and contact switch element  320  may be widely varied. For example,  FIGS. 4 ,  7  and  22 - 24  illustrate examples of some arrangements of capacitive touch sensor elements that can be configured to sense touch events caused by an object, such as a finger, in contact with or in proximity to a touch sensitive surface of an input device corresponding to the embodiments described above.  FIGS. 4 and 7  illustrate examples of 16-element arrangements.  FIG. 22  illustrates an example of a 15-element arrangement.  FIG. 23  illustrates an example of a 9-element arrangement.  FIG. 24  illustrates an example of a 30-element element arrangement. As illustrated in the embodiments of  FIGS. 4 ,  7  and  22 - 24 , the touch sensor elements according to the teachings of the present disclosure may comprise any suitable shape or pattern (e.g., annular, honeycombed, zigzagged, etc.) 
     Touch events detectable by the touch sensor elements of the input device may be widely varied, and may include, for example, rotational motion, linear motion, taps, holds, and other gestures and any combination thereof provided by one (single touch input) or more than one (multi-touch input) of a user&#39;s fingers across the touch sensitive surface. The touch sensor elements can be configured to detect touch input based on self capacitance (as illustrated in  FIGS. 4 ,  7  and  25 - 24 ) or mutual capacitance. In self capacitance, the “self” capacitance of a single electrode is measured as for example relative to ground. In mutual capacitance, the mutual capacitance between at least first and second electrodes is measured. In either case, each of the sensor elements can work independent of the other sensor elements to produce simultaneously occurring signals representative of different points of input on the touch sensitive surface at a particular time. Touch input sensed by the touch sensor elements of the input device may be widely varied, and may include, for example, touches and near-touches (that is, proximate but without actual contact) of a surface of the input device. The input device can include a controller (e.g., controller  300 ) configured to detect touch input by measuring a change in capacitance of the sensor elements. 
       FIGS. 6 ,  9 ,  11  and  13  illustrate examples of contact switch element arrangements. Push button input sensed by the contact switch elements of the input device may be widely varied, and may include, for example, push button presses and push button holds caused by pressure applied and/or released by a user&#39;s finger in a push button area of the input device. The controller described above (e.g., controller  300 ) can also be configured to detect input sensed by the contact switch elements. The ways in which push button input can be detected may be widely varied. For example, in one embodiment the controller can detect push button input by sensing a short circuit caused by a contact of contact switch elements in response to pressure applied to the push button area of the input device beyond a threshold level. In another embodiment, the controller can detect push button input by sensing a level of capacitance beyond a threshold amount. 
     The present disclosure is not limited to the input devices illustrated herein. Rather, an input device of any suitable technology or configuration for enabling detection of input in accordance with the teachings of the present disclosure can be utilized. For the purposes of the following discussion in connection with the embodiments illustrated in  FIGS. 4-21 , the input device can comprise capacitive touch sensor elements and contact switch elements forming mechanical push buttons arranged on different surfaces of a substrate, such as a flexible printed circuit board (“flex”) for example. 
     The flex can comprise three conductive layers—a top, middle and bottom conductive layer for example. The top conductive layer can comprise conducting pad electrodes forming capacitive touch sensor elements, the bottom conductive layer can comprise a conducting surface forming a ground plane around conducting elements forming contact switch elements, and the middle conductive layer can comprise traces connecting the controller to the capacitive touch sensor elements, the contact switch elements and the ground plane. 
     The flex can comprise a multi-layer substrate, and the conductive layers can be arranged on a surface of one or both sides of the substrate layers. In one embodiment, the conductive layer can comprise a copper layer coated on a substrate layer, which can be etched to form the appropriate sensor element and/or ground plane and then glued to another similar substrate layer. 
     Each of the substrate layers can comprise a dielectric material to separate the conductive layers. The dielectric material can be formed of a polyamide or other plastic for example. The traces can comprise sensor lines and connect the controller to the sensor elements through vias formed in the substrate layers and filled with conductive material. An advantage of routing traces and forming contact switch elements in one or more conductive layers different than the conductive layer forming the capacitive touch sensor elements can be to reduce parasitic capacitance, which can reduce the performance of the capacitance touch sensor elements. 
       FIGS. 4-6  illustrate an embodiment of a flex comprising an integrated contact switch and touch sensor configuration in accordance with the teachings of the present disclosure.  FIG. 4  illustrates conductive layer  400  of the flex in which 16 touch sensor elements and a contact switch element of one contact switch can be formed. The 16 touch sensor elements can include touch sensor element  410 , and comprise pad electrodes circumferentially arranged about the center of the flex. The contact switch can be centrally arranged on the flex. The input device can include neck  423  to allow the flex to connect to controller  420 , and tail  427  to allow controller  420  to connect to host interface  430 . Host interface  430  can be configured to connect the input device to a main processor or circuit board of a host electronic device. In one embodiment, traces arranged on neck  423  and tail  427  can be formed in only conductive layer  400  and associated with only one substrate layer to increase the flexibility of the neck and tail portions of the input device, which can be advantageous for assembly of the input device into the host electronic device. In other embodiments, the traces arranged on neck  423  and tail  427  can be formed in other and/or different conductive layers and associated with more than one substrate layer. 
       FIG. 6  illustrates conductive layer  600  of the flex in which ground plane  620  and a contact switch element associated with each of 4 contact switches, including contact switch element  610 , can be formed. In the illustrated embodiment, each contact switch can constitute a dome switch comprising 2 contact switch elements configured to make contact to actuate the switch. At least one contact switch element of each of the four dome switches can be formed in conductive layer  600 , and can be arranged in proximity to the touch sensor element with which it is integrated, such as on opposite sides of the flex from its corresponding touch sensor element for example.  FIG. 5  illustrates conductive layer  500  of the flex comprising a trace layer in which sensor lines connecting the touch sensor elements and the contact switch elements through via holes can be routed to controller  420 . 
       FIG. 5  also illustrates the integration of the contact switch elements and touch sensor elements formed near one another on the flex. Common sensor line  510  illustrates an exemplary integration of contact switch element  610  and touch sensor element  410 . By connecting contact switch element  610  and touch sensor element  410  in this manner, controller  420  can utilize one pin to detect a touch input via touch sensor element  410  and a push button input via contact switch element  610 . This configuration can achieve space, cost and manufacturing savings, since controller  420  can be configured smaller to utilize only 16 pins, for detecting touch and push button input via the 16 touch sensor elements and 4 contact switch elements, rather than having 20 dedicated pins for each sensor element (e.g., 16 for each touch sensor element and 4 for each contact switch element). 
       FIGS. 7-10  illustrate another embodiment of a flex comprising an integrated contact switch and touch sensor configuration in accordance with the teachings of the present disclosure. Similar to  FIG. 4 ,  FIG. 7  illustrates conductive layer  700  of the flex in which 16 touch sensor elements including touch sensor element  710  can be formed, and controller  720 , host interface  730 , neck  723  and tail  727 . Similar to  FIG. 6 ,  FIG. 9  illustrates conductive layer  900  of the flex in which a contact switch element associated with each of 4 contact switches, including contact switch element  900 , can be formed in proximity to the touch sensor element with which it is integrated. Unlike the embodiment of the flex illustrated in  FIGS. 4-7 , which illustrate a centrally arranged contact switch in the same layer as the touch sensor elements, the embodiment of the flex illustrated in  FIGS. 7-10  illustrates a centrally arranged contact switch in the same layer as ground plane  920 . 
     In the embodiment illustrated in  FIGS. 7-10 , at least one contact switch element of each of four dome switches can be formed in conductive layer  900 , and can be arranged in proximity to the touch sensor element with which it is integrated, such as on opposite sides of the flex from its corresponding touch sensor element for example. Similar to  FIG. 5 ,  FIG. 8  illustrates conductive layer  800  of the flex comprising a trace layer in which sensor lines connecting the touch sensor elements and the contact switch elements through via holes can be routed to controller  720 . Similar to  FIG. 5 ,  FIG. 8  illustrates the integration of contact switch elements with touch sensor elements formed near one another on the flex. Common sensor line  810  illustrates the integration of contact switch element  910  and touch sensor element  710 .  FIG. 10  illustrates conductive layers  1000 , which comprise a composite view of conductive layers  700 ,  800  and  900  of the flex. 
     The configuration of the flex according to the teachings of the present disclosure can vary widely. For example, to normalize capacitance readings among the touch sensor elements, the size, shape and thickness of the touch sensor elements or the flex itself can be increased or decreased appropriately. For instance, the second flex embodiment illustrates a rotation of the touch sensor element arrangement relative to the touch sensor element arrangement of the first embodiment. By rotating the touch sensor element arrangement in this manner, a more uniform touch sensing element area can be achieved. In another embodiment, dummy sets of contact switch elements can be mounted to the flex near touch sensor elements that are not integrated with contact switch elements in the manner indicated above, in order to normalize any effect that the working contact switch elements may have on the capacitance between their corresponding touch sensor elements and ground. This effect may also be compensated for by the controller via calibration to normalize capacitance readings across the touch sensor elements. In a further embodiment, to reduce the thickness of the flex, the trace layer of the flex can be combined with the ground plane layer to form a two conductive layer, rather than a three conductive layer, flex. In this embodiment, the sensor lines can be formed to snake through the ground plane without contacting the conductive material forming the ground plane. 
       FIGS. 11 and 13  illustrate an example of a configuration and operation of an integrated contact switch and touch sensor in input device  1100 .  FIG. 11  illustrates a configuration of the integrated contact switch and touch sensor in a non-pressed state. In the illustrated embodiment, the flex comprises a multi-layer substrate including substrate layer  1140  and substrate layer  1145 . Touch sensor element  1110  and neighboring touch sensor elements  1130  can be arranged on a top surface of substrate layer  1140 . Ground plane  1160  and contact switch element  1120  can be arranged on a bottom surface of substrate layer  1145 . Contact switch element  1125  can be connected to ground plane  1160 . A routing layer including common sense line  1155  can be arranged either on a bottom surface of substrate layer  1140 , a top surface of substrate layer  1145 , or on both surfaces. 
     Contact switch element  1120  and touch sensor element  1110  can be connected to common sense line  1155  via interconnect  1150  formed though via holes in the flex. In particular, in the non-pressed state, touch sensor element  1110  can operate as if it were separately and distinctly connected to the controller. For example,  FIG. 12  illustrates graph  1200  of capacitive reading measurements associated with touch sensor element  1110  and those of neighboring touch sensor elements  1130  during a scan cycle. The controller can detect that a touch input has occurred when the capacitance reading exceeds the finger threshold. This can be caused by finger  1170  contacting or hovering near touch sensor element  1110 , for example. 
       FIG. 13  illustrates a configuration of the integrated contact switch and touch sensor in a pressed state in input device  1100 . In the pressed state of the illustrated embodiment, button press  1300  can cause contact switch element  1125  to connect to contact switch element  1120 . Since contact switch element  1125  is connected to ground plane  1160 , the connecting of contact switch element  1125  to contact switch element  1120  can cause touch sensor element  1110 , which is connected to contact switch element  1120  via interconnect  1150  and common sense line  1155 , to be shorted to ground. The shorting to ground can cause a capacitive reading of zero or other appreciable drop in capacitance to be measured on the common sensor line. This situation is depicted in graph  1400  of  FIG. 14 , in which the absence of the center bar reflects a grounding of the common sensor line. In one embodiment, the controller can detect that a push button input has occurred when the capacitance reading is zero. This can be caused, for example, by a finger pressing the input device at a push button area such that the corresponding contact switch elements contact each other to cause the short. The dotted outline of the center bar can reflect a heightened capacitive reading on the common sensor line, prior to its grounding, reflecting a close proximity, but not connection, between contact switch element  1125  and contact switch element  1120  during button press  1300 . This heightened capacitive reading reflects an increase in capacitance, beyond a button press threshold level, between ground plane  1160  and touch sensor element  1110  due to contact switch element  1125  being moved closer to ground plane  1160  during button press  1300 . 
     Due to the nature of the common sensor line, the sensor readings associated with contact switch element  1120  in a pressed state can adversely affect sensor readings associated with touch sensor element  1110 . For example, a capacitive reading of zero can falsely indicate that touch sensor element  1110  is inactive. A capacitive reading of zero can also falsely indicate, based on a centroid analysis of graph  1400 , that two fingers are in contact with or near neighboring touch sensor elements  1130 , rather than one finger being in contact with or near touch sensor element  1110 . Further, a heightened capacitive reading as described above, which can occur during a push button input, can skew a centroid analysis performed to locate the position at which the touch input is applied to the input device. In particular, this skewing can occur due to the centroid analysis unnecessarily weighing the location of touch sensor element  1110 , caused by the heightened capacitive reading that is not reflective of the proximity of a finger. 
     Accordingly, the controller can be configured to compensate for these adverse effects.  FIGS. 15-17  illustrate examples of scanning processes that can compensate for these adverse effects 
       FIG. 15  illustrates a scanning process by which the controller can scan the common sensor line to detect an input associated with the touch sensor element or the contact switch element associated with an integrated contact switch and touch sensor. During each scan cycle (block  1500 ), the controller can scan (block  1510 ) all of the sensor elements of the input device. For push button input, the controller can detect (block  1520 ) push button input based on the scan data. For touch input, the controller can compensate (block  1520 ) for a pressed state of any integrated contact switch and touch sensor in the input device, and subsequently detect (block  1500 ) touch input based on compensated scan data. 
     For example, the controller can compensate for the pressed state of an integrated contact switch and touch sensor by estimating scan data for the associated touch sensor element. The ways in which the controller can estimate the scan data can be widely varied. In one embodiment, for example, the controller can estimate scan data based on scan data associated with the particular touch sensor element from one or more previous scan cycles. In another embodiment, the controller can estimate scan data based on captured scan data associated with neighboring touch sensor elements, such as an average of the captured scan data associated with the neighboring touch sensor elements for example. By replacing the null scan data (due to the grounding of the common sensor line) with estimated scan data, the controller can utilize more reliable data to detect the occurrence and location, for example, of a touch input associated with the integrated contact switch and touch sensor. 
     It should be appreciated that the process described above is not limited to the particular order illustrated in  FIG. 15 . For example, push button inputs can be detected as each contact switch element is scanned, rather than after all contact switch elements are scanned. 
     The ways in which the controller can scan (block  1510 ) the sensor elements of an input device may be widely varied. For example, in one embodiment, the controller can scan, within each scan cycle, the sensor elements for push button input first, and the sensor elements for touch input second. In order to debounce the contact switch elements, the controller can subsequently scan the sensor elements for push button input a second time in the same scan cycle (e.g., near the end of the scan cycle). 
     Further, the controller can be configured to optimize the scan cycle to account for the common sensor line configuration of integrated contact switch and touch sensors. In one embodiment, the controller can skip scanning, within a scan cycle, all touch sensor lines when a push button input has been detected. In this embodiment, the controller can scan the contact switch sensor lines for push button input. If the controller determines that any contact switch element has been activated, the controller can skip scanning any further touch sensor lines for touch input during the remainder of the scan cycle. Otherwise, the controller can scan the touch sensor lines for touch input during the remainder of the scan cycle. 
     In another embodiment, as illustrated in  FIG. 16 , the controller can skip scanning, within a scan cycle, only the touch sensor lines shared with a contact switch element that has sensed a push button input. In this illustrated embodiment, the controller can scan (block  1600 ) the contact switch sensor lines for push button input. If the next touch sensor line is shared (block  1610 ) with a contact switch element, then the controller can determine (block  1640 ) whether the shared contact switch element has been activated. If the shared contact switch element has been pressed, the controller can skip scanning the touch sensor line for touch input. If the shared contact switch element has not been pressed, the controller can scan (block  1620 ) the touch sensor line for touch input. This can be repeated (block  1630 ) for each remaining touch sensor line in the scan cycle. 
     The embodiments described above in connection with optimizing the scan cycle can reduce the scanning time, and thus, power, associated with each scan cycle, since they involve selectively skipping certain scans. 
     In another embodiment of a scanning process, rather than scanning for push button inputs independently of scanning for touch inputs as described in an embodiment above (i.e., scanning for push button input first, and scanning for touch input second), the controller can determine whether to consecutively scan for push button input and touch input based on the particular sensor line that is next in line to be scanned. For example, in this embodiment during each scan cycle, the controller can determine whether the next sensor line to be scanned is connected to both a contact switch and touch sensor element. If the next sensor line is connected to both a contact switch and touch sensor element, the controller can scan for a push button input and for a touch input on that sensor line. If the next sensor line is not connected to both a contact switch and touch sensor element, the controller can scan only for a touch input on that sensor line. 
     In connection with the noise and button press thresholds described in  FIGS. 12 and 14 , the embodiment of a scanning process illustrated in  FIG. 17  enables undesirable scan data to be disregarded. For example, during each scan cycle the controller can scan (block  1700 ) touch sensor lines for touch input. If the controller determines that the scan data resulting from the scan of the touch sensor line falls below (block  1710 ) a noise threshold or exceeds (block  1720 ) a button press threshold, the controller can disregard (block  1740 ) the scan data (e.g., not retain it for further processing). However, if the controller determines that the scan data does not fall below (block  1710 ) the noise threshold and does not exceed (block  1720 ) the button press threshold, the controller can capture (block  1730 ) the scan data for further process (e.g., centroid analysis, etc.). By disregarding undesirable scan data such as that which falls below the noise threshold, the controller can save processing time and power by not wasting time on noise. By disregarding undesirable scan data such as that which exceeds the button press threshold, the controller can enhance reliability by not allowing skewed scan data adversely effect touch sensor detection. Rather, the controller can rely on the compensation techniques described above in connection with  FIG. 15 . 
       FIGS. 18-21  describe various embodiments through which the above-described scanning process could be implemented. For example,  FIG. 18  illustrates an example of a sensing process associated with touch sensor elements of input device  1800  in accordance with one embodiment. During a scan cycle, the controller can perform a sensing operation for each of the sensor elements in consecutive fashion. When a sensing operation is being performed in association with one of the sensor elements, the other sensor elements can be grounded. In one embodiment, the sensor elements can be disposed on a three conductive layer flex as described above. 
       FIG. 19  illustrates an example of a sensing circuit that can implement the sensing process of  FIG. 18 . A parasitic capacitance Cp can represent the sum of all capacitance from a sensor element associated with a sensing operation to surrounding conductive material (e.g., sensor element to ground plane and sensor element to grounded sensor elements). The capacitance Cf associated with an object such as a finger over the sensor element can increase the total capacitance C(C=Cp+Cf) associated with the sensor element above a threshold sense level. Timer and controller  1910  (which can correspond to the controllers described above) of sensing circuit  1900  can measure a capacitance associated with a sensor element by using relatively small capacitance Cp+Cf to charge relatively large capacitance Cint (associated with an integration capacitor) to voltage threshold Vref. Sensing circuit  1900  can produce a measurement value reflecting how long it takes (e.g., how may switching cycles as described below) to charge Cint to Vref. For example, a measurement value reflecting an input (e.g., the above input sense level values) can result from the time it takes for Cp+Cf to charge Cint to Vref minus the time it takes for Cp to charge Cint to Vref. Expressed formulaically, input=time(Cp+Cf)−time(Cp). 
     In operation, sensing circuit  1900  can operate as follows:
         step 0: reset and start timer (assume Cint has no charge)   step 1: open transfer switch SW 2 , close charge switch SW 1  (these can switch alternately very fast, e.g., MHz)
           Cp+Cf are charged to Vcc (e.g., 3.0 V)   
           step 2: open charge switch SW 1 , close transfer switch SW 2 
           Cp+Cf charge flows to Cint   repeat step 1 and step 2 until Cint reaches Vref (e.g., 1.1 V)   
           step 3: stop timer   step 4: open charge switch SW 1 , open transfer switch SW 2 , close discharge switch SW 3 : discharges Cint to no charge state
           open discharge switch SW 3  when done   repeat for all sensor elements   
               

       FIGS. 20 and 21  illustrate examples of sensing circuits associated with independent touch sensor elements and integrated contact switch and touch sensor elements in accordance with one embodiment. The controller can configure its GPIO pins in many ways using a multiplexer or switch network. 
     For example, in the configuration of  FIG. 20 , chip  2000  includes multiplexer  2020  that connects the sensor pad pins to capacitor sensing block  2010 . Since there is only one capacitor sensing block, the controller of chip  2000  can perform the sensing for each sensor element one by one. While a generic multiplexer normally connects only one input to its output, multiplexer  2020  acts more like a switch network; it can connect multiple sensor elements together into its output. The output of capacitor sensing block  2010  can be a raw count indicating the capacitance of the sensor pad (e.g., the number of clock cycles it took to charge the integration capacitor to Vref). 
     In the configuration of  FIG. 21 , chip  2000  can configure the pin as a GPIO. The SPDT switch can be assumed to be part of multiplexer  2020  in  FIG. 20 , although simplified for clarity. In this configuration, the illustrated internal pull-up can be enabled and the pin configured as input. If the contact switch element is not pressed, the pin can be read as “high” due to the internal pull-up. If the button is pressed, the pin can be read as “low”. 
     Chip  2000  can have a massive switching block between its pins and the internal blocks. The controller can perform the following steps:
         step 1: if initial power-on, perform some initialization   step 2: check if the device host is active by looking at signal driven by the host; a high signal can indicate that the host is active, and a low signal can indicate that the host is sleeping
           if the host is active, stay in ACTIVE mode   if the host is sleeping, go to SLEEP   
               

     ACTIVE steps:
         Step 2.5: set timer (e.g., 16 ms) to wake us up Oust set the alarm, keep continue executing)   Step 3: configure button pins as GPI (general purpose input)
           read button states all together; take note of if any were not pressed but are now pressed (i.e. low)   
           Step 4: If MODE=ACTIVE:
           connect each sensor pin to capacitor sensing block  2010  and record raw count; after all sensor elements are read, an array of #sensor raw counts (#sensor=16 according to embodiment of  FIGS. 4-10 ) is recorded   If MODE=IDLE:   connect multiple sensor elements (e.g., 3) to capacitor sensing block  2010  and record raw count; after all sensor elements are read, an array of (#sensor/3) raw counts (#sensor/3=6) is recorded   
           Step 5: was this the initial sensing?
           if YES=&gt;store raw counts as baseline   
           Step 6: calculate the difference between raw count and baseline for each sensor element; store in signal array   Step 7: are all sensor element signals less than noise threshold?
           if YES, perform “baseline update”   
           Step 8: is any sensor element above finger threshold?
           if YES, look for finger presence.   If mode=IDLE and finger detected, change mode to ACTIVE.   
           Step 9: was any button pressed from step #3?
           if so, configure the button pins as GPI again and read the button states   if the button(s) pressed in step 3 are still pressed (=debouncing), then report it to the host   
           Step 10: if finger was down or up and/or button was pressed/depressed (step 9), send a packet to host   Step 11: any finger presence after 3 scans?
           if YES, set mode to IDLE mode   
           Step 12: go to sleep (16 ms timer set earlier in step 2.5 will wake controller up)
           after waking up, go to step 2   
               

     SLEEP mode:
         set button pins and host signal as GPI&#39;s.   enable interrupt on change   enable wake-up on interrupt   go to sleep (any status change on buttons or host pins will wake controller up)   after waking up, go to step 2       

     FINGER PRESENCE DETECTION:
         are any sensor elements above finger threshold?   are there at least two neighboring sensor elements that are above finger threshold?=&gt;Valid centroid   count the number of valid centroids that are separated by at least one sensor element less than finger threshold   for device supporting multi-touch: (X number of fingers can be detected): report if only X or less valid centroids exist   for device supporting single touch: report if only one valid centroid exists       

     BASELINE UPDATE:
         if raw count of sensor element is above its baseline count, slowly update baseline count towards the raw count value (this may take several scans and baseline update procedure calls)   if raw count of sensor element is below its baseline count (=negative finger), set baseline to raw count immediately       

       FIGS. 25-27  illustrate operations of an input device according to some embodiments of the present disclosure. For example, the input device may generally correspond to any of the input devices mentioned above. In the example shown in  FIG. 25 , input device  2530  can be configured to send information or data to an electronic device in order to perform an action on a display screen (e.g., via a graphical user interface). Examples of actions that may be performed include, moving an input pointer, making a selection, providing instructions, etc. The input device can interact with the electronic device through a wired connection (e.g., cable/connector) or a wireless connection (e.g., IR, Bluetooth, etc.). Input device  2530  may be a stand alone unit or it may be integrated into the electronic device. As a stand alone unit, the input device can have its own enclosure. When integrated into an electronic device, the input device can typically use the enclosure of the electronic device. In either case, the input device can be structurally coupled to the enclosure, as for example, through screws, snaps, retainers, adhesives and the like. In some cases, the input device may be removably coupled to the electronic device, as for example, through a docking station. The electronic device to which the input device may be coupled can correspond to any consumer related electronic product. For example, the electronic device can correspond to a computer such as a desktop computer, laptop computer or PDA, a media player such as a music player, a communication device such as a cellular phone, another input device such as a keyboard, and the like. 
     As shown in  FIG. 25 , in this embodiment input device  2530  may include frame  2532  (or support structure) and touch pad  2534 . Frame  2532  can provide a structure for supporting the components of the input device. Frame  2532  in the form of a housing can also enclose or contain the components of the input device. The components, which may include touch pad  2534 , can correspond to electrical, optical and/or mechanical components for operating input device  2530 . Frame  2532  may be a separate component or it may be an integral component of the housing of the electronic device. 
     Touch pad  2534  can provide location information for an object, such as a finger for example, in contact with or in proximity to the touch pad. This information can be used in combination with information provided by a movement indicator to generate a single command associated with the movement of the touch pad. The touch pad may be used as an input device by itself; for example, the touch pad may be used to scroll through a list of items on the device. 
     The shape, size and configuration of touch pad  2534  may be widely varied. In addition to the touchpad configurations disclosed above, a conventional touch pad based on the Cartesian coordinate system, or based on a Polar coordinate system can be configured to provide scrolling using rotational movements and can be configured to accept the multi-touch and gestures, for example those described herein. Furthermore, touch pad  2534  can be used in at least two different modes, which may be referred to as a relative mode and an absolute mode. In absolute mode, touch pad  2534  can, for example, report the absolute coordinates of the location at which it may be touched. For example, these would be “x” and “y” coordinates in the case of a standard Cartesian coordinate system or (r,θ) in the case of a Polar coordinate system. In relative mode, touch pad  2534  can report the direction and/or distance of change, for example, left/right, up/down, and the like. In most cases, the signals produced by touch pad  2534  can direct movement on the display screen in a direction similar to the direction of the finger as it may be moved across the surface of touch pad  2534 . 
     The shape of touch pad  2534  may be widely varied. For example, it may be circular, oval, square, rectangular, triangular, and the like. In general, the outer perimeter can define the working boundary of touch pad  2534 . In the embodiment illustrated in  FIG. 25 , the touch pad may be circular. Circular touch pads can allow a user to continuously swirl a finger in a free manner, i.e., the finger may be rotated through  360  degrees of rotation without stopping. This form of motion can produce incremental or accelerated scrolling through a list of songs being displayed on a display screen, for example. Furthermore, the user may rotate his or her finger tangentially from all sides, thus providing more finger position range. Both of these features may help when performing a scrolling function. Furthermore, the size of touch pad  2534  can accommodate manipulation by a user (e.g., the size of a finger tip or larger). 
     Touch pad  2534 , which can generally take the form of a rigid platform. The rigid platform may be planar, convex or concave, and may include touchable outer surface  2536 , which may be textured, for receiving a finger or other object for manipulation of the touch pad. Although not shown in  FIG. 25 , beneath touchable outer surface  2536  can be a sensor arrangement that may be sensitive to such things as the pressure and movement of a finger thereon. The sensor arrangement may typically include a plurality of sensors that can be configured to activate as the finger sits on, taps on or passes over them. In the simplest case, an electrical signal can be produced each time the finger is positioned over a sensor. The number of signals in a given time frame may indicate location, direction, speed and acceleration of the finger on touch pad  2534 , i.e., the more signals, the more the user moved his or her finger. In most cases, the signals can be monitored by an electronic interface that converts the number, combination and frequency of the signals into location, direction, speed and acceleration information. This information can then be used by the electronic device to perform the desired control function on the display screen. The sensor arrangement may be widely varied. For example, the sensors can be based on resistive sensing, surface acoustic wave sensing, pressure sensing (e.g., strain gauge), optical sensing, capacitive sensing and the like. 
     In the embodiment illustrated in  FIG. 25 , touch pad  2534  may be based on capacitive sensing. In most cases, the capacitive touch pad may include a protective shield, one or more electrode layers, a circuit board and associated electronics including an application specific integrated circuit (ASIC). The protective shield can be placed over the electrodes, the electrodes can be mounted on the top surface of the circuit board, and the ASIC can be mounted on the bottom surface of the circuit board. The protective shield may serve to protect the underlayers and to provide a surface for allowing a finger to slide thereon. The surface may generally be smooth so that the finger does not stick to it when moved. The protective shield also may provide an insulating layer between the finger and the electrode layers. The electrode layer may include a plurality of spatially distinct electrodes. Any suitable number of electrodes can be used. As the number of electrodes increases, the resolution of the touch pad also increases. 
     In accordance with one embodiment, touch pad  2534  can be movable relative to the frame  2532 . This movement can be detected by a movement detector that generates another control signal. For example, touch pad  2534  in the form of the rigid planar platform can rotate, pivot, slide, translate, flex and/or the like relative to frame  2532 . Touch pad  2534  can be coupled to frame  2532  and/or it can be movably restrained by frame  2532 . For example, touch pad  2534  can be coupled to frame  2532  through axels, pin joints, slider joints, ball and socket joints, flexure joints, magnets, cushions and/or the like. Touch pad  2534  can also float within a space of the frame (e.g., gimbal). It should be noted that input device  2530  may additionally include a combination of joints such as a pivot/translating joint, pivot/flexure joint, pivot/ball and socket joint, translating/flexure joint, and the like to increase the range of movement (e.g., increase the degree of freedom). 
     When moved, touch pad  2534  can be configured to actuate a movement detector circuit that generates one or more signals. The circuit may generally include one or more movement detectors such as switches, sensors, encoders, and the like. 
     In the embodiment illustrated in  FIG. 25 , touch pad  2534  can be part of a depressible platform. The touch pad can operate as a button and perform one or more mechanical clicking actions. Multiple functions or the same function of the device may be accessed by depressing the touch pad  2534  in different locations. A movement detector signals that touch pad  2534  has been depressed, and touch pad  2534  signals a location on the platform that has been touched. By combining both the movement detector signals and touch pad signals, touch pad  2534  acts like multiple buttons such that depressing the touch pad at different locations corresponds to different buttons. As shown in  FIGS. 26 and 27 , according to one embodiment touch pad  2534  can be capable of moving between an upright position ( FIG. 26 ) and a depressed position ( FIG. 27 ) when a requisite amount of force from finger  2538 , palm, hand or other object is applied to touch pad  2534 . Touch pad  2534  can be spring biased in the upright position, as for example through a spring member. Touch pad  2534  moves to the depressed position when the spring bias is overcome by an object pressing on touch pad  2534 . 
     As shown in  FIG. 26 , touch pad  2534  generates tracking signals when an object such as a user&#39;s finger is moved over the top surface of the touch pad in the x,y plane. As shown in  FIG. 27 , in the depressed position (z direction), touch pad  2534  generates positional information and a movement indicator generates a signal indicating that touch pad  2534  has moved. The positional information and the movement indication can be combined to form a button command. Different button commands or the same button command can correspond to depressing touch pad  2534  in different locations. The button commands may be used for various functionalities including, but not limited to, making selections or issuing commands associated with operating an electronic device. For example, in the case of a music player, the button commands may be associated with opening a menu, playing a song, fast forwarding a song, seeking through a menu and the like. 
     To elaborate, touch pad  2534  can be configured to actuate a movement detector, which together with the touch pad positional information, can form a button command when touch pad  2534  is moved to the depressed position. The movement detector can be located within frame  2532  and coupled to touch pad  2534  and/or frame  2532 . The movement detector may be any combination of switches and sensors. Switches can be generally configured to provide pulsed or binary data such as activate (on) or deactivate (off). For example, an underside portion of touch pad  2534  can be configured to contact or engage (and thus activate) a switch when the user presses on touch pad  2534 . The sensors, on the other hand, can be generally configured to provide continuous or analog data. For example, the sensor can be configured to measure the position or the amount of tilt of touch pad  2534  relative to the frame when a user presses on the touch pad  2534 . Any suitable mechanical, electrical and/or optical switch or sensor may be used. For example, tact switches, force sensitive resistors, pressure sensors, proximity sensors, and the like may be used. In some case, the spring bias for placing touch pad  2534  in the upright position may be provided by a movement detector that includes a spring action. In other embodiments, input device  2530  can include one or more movement detectors in various locations positioned under and/or above touch pad  2534  to form button commands associated with the particular locations in which the movement detector is actuated. Touch pad  2534  may can also be configured to provide a force feedback response. 
       FIG. 28  illustrates a simplified perspective diagram of input device  2570 . Like the input device shown in the embodiment of  FIGS. 25-27 , this input device  2570  incorporates the functionality of one or more buttons directly into touch pad  2572 , i.e., the touch pad acts like a button. In this embodiment, however, touch pad  2572  can be divided into a plurality of independent and spatially distinct button zones  2574 . Button zones  2574  may represent regions of the touch pad  2572  that can be moved by a user to implement distinct button functions or the same button function. The dotted lines may represent areas of touch pad  2572  that make up an individual button zone. Any number of button zones may be used, for example, two or more, four, eight, etc. In the embodiment illustrated in  FIG. 28 , touch pad  2572  may include four button zones  2574  (i.e., zones A-D). 
     As should be appreciated, the button functions generated by pressing on each button zone may include selecting an item on the screen, opening a file or document, executing instructions, starting a program, viewing a menu, and/or the like. The button functions may also include functions that make it easier to navigate through the electronic system, as for example, zoom, scroll, open different menus, home the input pointer, perform keyboard related actions such as enter, delete, insert, page up/down, and the like. In the case of a music player, one of the button zones may be used to access a menu on the display screen, a second button zone may be used to seek forward through a list of songs or fast forward through a currently playing song, a third button zone may be used to seek backwards through a list of songs or fast rearward through a currently playing song, and a fourth button zone may be used to pause or stop a song that may be in the process of being played. 
     To elaborate, touch pad  2572  can be capable of moving relative to frame  2576  so as to create a clicking action. Frame  2576  can be formed from a single component or a combination of assembled components. The clicking action can actuate a movement detector contained inside frame  2576 . The movement detector can be configured to sense movements of the button zones during the clicking action and to send a signal corresponding to the movement to the electronic device. For example, the movement detectors may be switches, sensors and/or the like. 
     In addition, touch pad  2572  can be configured to send positional information on what button zone may be acted on when the clicking action occurs. The positional information can allow the device to determine which button zone to activate when the touch pad is moved relative to the frame. 
     The movements of each of button zones  2574  may be provided by various rotations, pivots, translations, flexes and the like. In one embodiment, touch pad  2572  can be configured to gimbal relative to frame  2576 . By gimbal, it is generally meant that the touch pad  2572  can float in space relative to frame  2576  while still being constrained thereto. The gimbal can allow the touch pad  2572  to move in single or multiple degrees of freedom (DOF) relative to the housing, for example, movements in the x,y and/or z directions and/or rotations about the x,y, and/or z axes (θxθyθz). 
       FIG. 29  illustrates an example of a simplified block diagram of a computing system  2539 . The computing system may generally include input device  2540  operatively connected to computing device  2542 . For example, input device  2540  can generally correspond to input device  2530  shown in  FIGS. 25-27 , and the computing device  2542  can correspond to a computer, PDA, media player or the like. As shown, input device  2540  may include depressible touch pad  2544  and one or more movement detectors  2546 . Touch pad  2544  can be configured to generate tracking signals and movement detector  2546  can be configured to generate a movement signal when the touch pad is depressed. Although touch pad  2544  may be widely varied, in this embodiment, touch pad  2544  can include capacitance sensors  2548  and control system  2550  (which can generally correspond to the controllers described above) for acquiring position signals from sensors  2548  and supplying the signals to computing device  2542 . Control system  2550  can include an application specific integrated circuit (ASIC) that can be configured to monitor the signals from sensors  2548 , to compute the absolute location, angular location, direction, speed and/or acceleration of the monitored signals and to report this information to a processor of computing device  2542 . Movement detector  2546  may also be widely varied. In this embodiment, however, movement detector  2546  can take the form of a switch that generates a movement signal when touch pad  2544  is depressed. Movement detector  2546  can correspond to a mechanical, electrical or optical style switch. In one particular implementation, movement detector  2546  can be a mechanical style switch that includes protruding actuator  2552  that may be pushed by touch pad  2544  to generate the movement signal. For example, the switch may be a tact or dome switch. 
     Both touch pad  2544  and movement detector  2546  can be operatively coupled to computing device  2542  through communication interface  2554 . The communication interface provides a connection point for direct or indirect connection between the input device and the electronic device. Communication interface  2554  may be wired (wires, cables, connectors) or wireless (e.g., transmitter/receiver). 
     Referring to computing device  2542 , it may include processor  2557  (e.g., CPU or microprocessor) configured to execute instructions and to carry out operations associated with computing device  2542 . For example, using instructions retrieved from memory, the processor can control the reception and manipulation of input and output data between components of computing device  2542 . Processor  2557  can be configured to receive input from both movement detector  2546  and touch pad  2544  and can form a signal/command that may be dependent upon both of these inputs. In most cases, processor  2557  can execute instruction under the control of an operating system or other software. Processor  2557  may be a single-chip processor or may be implemented with multiple components. 
     Computing device  2542  may also include input/output (I/O) controller  2556  that can be operatively coupled to processor  2557 . (I/O) controller  2556  can be integrated with processor  2557  or it may be a separate component as shown. I/O controller  2556  can generally be configured to control interactions with one or more I/O devices that may be coupled to the computing device  2542 , as for example input device  2540  and orientation detector  2555 , such as an accelerometer. I/O controller  2556  can generally operate by exchanging data between computing device  2542  and I/O devices that desire to communicate with computing device  2542 . 
     Computing device  2542  may also include display controller  2558  that can be operatively coupled to processor  2557 . Display controller  2558  can be integrated with processor  2557  or it may be a separate component as shown. Display controller  2558  can be configured to process display commands to produce text and graphics on display screen  2560 . For example, display screen  2560  may be a monochrome display, color graphics adapter (CGA) display, enhanced graphics adapter (EGA) display, variable-graphics-array (VGA) display, super VGA display, liquid crystal display (e.g., active matrix, passive matrix and the like), cathode ray tube (CRT), plasma displays and the like. In the embodiment illustrated in  FIG. 29 , the display device corresponds to a liquid crystal display (LCD). 
     In some cases, processor  2557  together with an operating system operates to execute computer code and produce and use data. The computer code and data can reside within program storage area  2562  that may be operatively coupled to processor  2557 . Program storage area  2562  can generally provide a place to hold data that may be used by computing device  2542 . For example, the program storage area may include Read-Only Memory (ROM), Random-Access Memory (RAM), hard disk drive and/or the like. The computer code and data could also reside on a removable program medium and loaded or installed onto the computing device when needed. In one embodiment, program storage area  2562  can be configured to store information for controlling how the tracking and movement signals generated by the input device may be used, either alone or in combination for example, by computing device  2542  to generate an input event command, such as a single button press for example. 
       FIGS. 30-33  illustrate applications of an input device according to some embodiments of the present disclosure. As previously mentioned, the input devices described herein can be integrated into an electronic device or they can be separate stand alone devices.  FIGS. 30-33  show some implementations of input device  2520  integrated into an electronic device.  FIG. 30  shows input device  2520  incorporated into media player  2512 .  FIG. 31  shows input device  2520  incorporated into laptop computer  2514 .  FIGS. 32 and 33 , on the other hand, show some implementations of input device  2520  as a stand alone unit.  FIG. 32  shows input device  2520  as a peripheral device that can be connected to desktop computer  2516 .  FIG. 33  shows input device  2520  as a remote control that wirelessly connects to docking station  2518  with media player  2512  docked therein. It should be noted, however, that in some embodiments the remote control can also be configured to interact with the media player (or other electronic device) directly, thereby eliminating the need for a docking station. It should be noted that these particular embodiments do not limit the present disclosure and that many other devices and configurations may be used. 
     Referring back to  FIG. 30 , media player  2512 , housing  2522  and display screen  2524  may generally correspond to those described above. As illustrated in the embodiment of  FIG. 30 , display screen  2524  can be visible to a user of media player  2512  through opening  2525  in housing  2522  and through transparent wall  2526  disposed in front of opening  2525 . Although transparent, transparent wall  2526  can be considered part of housing  2522  since it helps to define the shape or form of media player  2512 . 
     Media player  2512  may also include touch pad  2520  such as any of those previously described. Touch pad  2520  can generally consist of touchable outer surface  2531  for receiving a finger for manipulation on touch pad  2520 . Although not illustrated in the embodiment of  FIG. 30 , beneath touchable outer surface  2531  a sensor arrangement can be configured in a manner as previously described. Information provided by the sensor arrangement can be used by media player  2512  to perform the desired control function on display screen  2524 . For example, a user may easily scroll through a list of songs by swirling the finger around touch pad  2520 . 
     In addition to above, the touch pad may also include one or more movable buttons zones A-D as well as a center button E for example. The button zones can be configured to provide one or more dedicated control functions for making selections or issuing commands associated with operating media player  2512 . For example, in the case of an MP3 music player, the button functions can be associated with opening a menu, playing a song, fast forwarding a song, seeking through a menu, making selections and the like. In some embodiments, the button functions can be implemented via a mechanical clicking action. 
     The position of touch pad  2520  relative to housing  2522  may be widely varied. For example, touch pad  2520  can be placed at any surface (e.g., top, side, front, or back) of housing  2522  accessible to a user during manipulation of media player  2512 . In some embodiments, touch sensitive surface  2531  of touch pad  2520  can be completely exposed to the user. In the embodiment illustrated in  FIG. 30 , touch pad  2520  can be located in a lower front area of housing  2522 . Furthermore, touch pad  2520  can be recessed below, level with, or extend above the surface of housing  2522 . In the embodiment illustrated in  FIG. 30 , touch sensitive surface  2531  of touch pad  2520  can be substantially flush with an external surface of housing  2522 . 
     The shape of touch pad  2520  may also be widely varied. Although illustrated as circular in the embodiment of  FIG. 30 , the touch pad can also be square, rectangular, triangular, and the like for example. More particularly, the touch pad can be annular, i.e., shaped like or forming a ring. As such, the inner and outer perimeter of the touch pad can define the working boundary of the touch pad. 
     It will be appreciated that the above description for clarity has described embodiments of the disclosure with reference to different functional units and processors. However, it will be apparent that any suitable distribution of functionality between different functional units or processors may be used without detracting from the disclosure. For example, functionality illustrated to be performed by separate processors or controllers may be performed by the same processors or controllers. Hence, references to specific functional units may be seen as references to suitable means for providing the described functionality rather than indicative of a strict logical or physical structure or organization. 
     The disclosure may be implemented in any suitable form, including hardware, software, firmware, or any combination of these. The disclosure may optionally be implemented partly as computer software running on one or more data processors and/or digital signal processors. The elements and components of an embodiment of the disclosure may be physically, functionally, and logically implemented in any suitable way. Indeed, the functionality may be implemented in a single unit, in a plurality of units, or as part of other functional units. As such, the disclosure may be implemented in a single unit or may be physically and functionally distributed between different units and processors. 
     One skilled in the relevant art will recognize that many possible modifications and combinations of the disclosed embodiments can be used, while still employing the same basic underlying mechanisms and methodologies. The foregoing description, for purposes of explanation, has been written with references to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the disclosure to the precise forms disclosed. Many modifications and variations can be possible in view of the above teachings. The embodiments were chosen and described to explain the principles of the disclosure and their practical applications, and to enable others skilled in the art to best utilize the disclosure and various embodiments with various modifications as suited to the particular use contemplated. 
     Further, while this specification contains many specifics, these should not be construed as limitations on the scope of what is being claimed or of what may be claimed, but rather as descriptions of features specific to particular embodiments. Certain features that are described in this specification in the context of separate embodiments can also be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment can also be implemented in multiple embodiments separately or in any suitable subcombination. Moreover, although features may be described above as acting in certain combinations and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a subcombination or variation of a subcombination.

Metadata:
Filing Date: 20090601
Publication Date: 20130312
Grant Date: 20130312
Priority Date: 20081217
Inventors: FISHER JOSEPH
KOCALAR ERTURK
RATHNAM LAKSHMAN
Assignee: APPLE INC
CPC Classifications: [{"code": "G06F3/0362", "inventive": true, "first": false, "tree": "[]"}, {"code": "G06F3/0362", "inventive": true, "first": false, "tree": "[]"}, {"code": "G06F3/0412", "inventive": true, "first": false, "tree": "[]"}, {"code": "G06F3/0445", "inventive": true, "first": true, "tree": "[]"}, {"code": "G06F3/0445", "inventive": true, "first": true, "tree": "[]"}]
Family ID: 42239911