PATENT DOCUMENT

Publication Number: US-9563239-B2
Application Number: US-201213608839-A
Country: US
Kind Code: B2

Title: Internal computer assembly features and methods

Abstract:
Examples of computing devices and assemblies for mounting computer components to an enclosure or other structure of the computing device are described. In some examples, the mounting assembly may include a compliant member having a plurality of corner portions configured to engage the corners of the component. The mounting assembly may also include a bracket configured to enclose at least a portion of the compliant member. The mounting bracket may be configured to mount the component at an angle relative to the enclosure or other structure, and may include one or more features adapted for improved cooling of the component mounted therein. The compliant member may include a plurality of ribs or other retaining elements for maintaining the component in a spaced apart position relative to the mounting bracket.

Claims:
What is claimed is: 
     
       1. An assembly for mounting a computer component, comprising:
 an elastomeric sleeve having a plurality of corner portions configured to receive corresponding corner portions of the computer component, at least one of the corner portions of the elastomeric sleeve comprising a plurality of retaining elements protruding from a surface of the elastomeric sleeve and configured to contact the corresponding corner portion of the computer component received by the at least one of the corner portions of the elastomeric sleeve, wherein the retaining elements are located between the at least one of the corner portions of the elastomeric sleeve and the computer component; and 
 a bracket that surrounds the elastomeric sleeve, wherein the bracket is configured to mount the elastomeric sleeve and computer component to a computer housing. 
 
     
     
       2. The assembly of  claim 1 , wherein the elastomeric sleeve comprises a plurality of polymeric materials. 
     
     
       3. The assembly of  claim 1 , wherein the retaining elements protrude substantially perpendicularly from the surface of the elastomeric sleeve. 
     
     
       4. The assembly of  claim 1 , wherein at least one of the plurality of retaining elements has a shape which is different than a shape of another one of the plurality of retaining elements. 
     
     
       5. The assembly of  claim 1  wherein each of the corner portions of the elastomeric sleeve includes rounded exterior surfaces, and wherein receiving surfaces of the bracket are shaped to match the rounded exterior surfaces of the corner portions of the elastomeric sleeve. 
     
     
       6. The assembly of  claim 1 , wherein the corner portions of the elastomeric sleeve are wider than other portions of the elastomeric sleeve. 
     
     
       7. The assembly of  claim 1 , wherein the bracket has a deformable portion that overlaps the elastomeric sleeve and bends to receive the elastomeric sleeve in the bracket. 
     
     
       8. The assembly of  claim 1  wherein the bracket is configured to be mounted at an angle to a surface of the computer housing. 
     
     
       9. The assembly of  claim 1  wherein the bracket includes a plurality of mounting portions, at least one of the plurality of mounting portions having a height different than a height of another one of the plurality of mounting portions. 
     
     
       10. The assembly of  claim 1 , wherein the bracket includes a surface connecting a plurality of corners of the bracket, and wherein the surface is offset from a plane defined by the corners of the bracket. 
     
     
       11. The assembly of  claim 10 , wherein at least a portion of the surface is curved. 
     
     
       12. A computing device comprising:
 an enclosure defining an exterior surface and a curved interior surface of the computing device; and 
 a mounting assembly disposed within the enclosure and mounted to the curved interior surface of the enclosure, the mounting assembly comprising:
 a mounting bracket comprising first, second, third, and fourth support members fastened to the curved interior surface of the enclosure, wherein the first and third support members have different lengths, wherein the mounting bracket comprises a base, a first rail that extends from the first support member to the second support member, a second rail that extends from the third support member to the fourth support member, and an opening in the second rail that routes cables through the bracket; 
 a compliant member positioned within the bracket that receives a computer component and that rests on the first and second rails, wherein the first and second rails suspend the compliant member over the base of the mounting bracket to provide an air space between the computer component and the base, wherein the computer component comprises top and bottom surfaces and four sidewall surfaces, and wherein the compliant member comprises a first pair of connector strips that extend parallel to two of the sidewall surfaces and a second pair of connector strips that extend parallel to the top and bottom surfaces while leaving two of the sidewall surfaces uncovered; 
 a first lid attached to the first and second support members such that the computer component is interposed between the first rail and the first lid; and 
 a second lid attached to the third and fourth support members such that the computer component is interposed between the second rail and the second lid, wherein the first and second lids overlap the two uncovered sidewall surfaces of the computer component. 
 
 
     
     
       13. The computing device of  claim 12 , wherein the mounting bracket is mounted at an angle relative to the curved interior surface. 
     
     
       14. The computing device of  claim 12 , wherein the computer component is a hard drive. 
     
     
       15. The computing device of  claim 12 , wherein the compliant member includes a plurality of rib structures that contact the computer component and maintain a gap between the computer component and the first and second pairs of connector strips. 
     
     
       16. The computing device of  claim 12 , wherein the compliant member comprises an elastomeric sleeve. 
     
     
       17. An assembly for mounting a computer component, the assembly comprising:
 a compliant member that wraps around the computer component, wherein the compliant member comprises four corner portions and first and second pairs of opposing side portions that extend between the four corner portions; and 
 a bracket that engages the compliant member to secure the compliant member to the bracket at each of the four corners, wherein the bracket encloses the first pair of opposing side portions while exposing the second pair of opposing side portions, and wherein the bracket comprises a base defining a curved surface that faces the computer component and provides airflow through a gap between the curved surface and the computer component. 
 
     
     
       18. The assembly of  claim 17 , wherein the curved surface increases a velocity of the airflow through the gap. 
     
     
       19. The assembly of  claim 17 , wherein the airflow cools the computer component. 
     
     
       20. The assembly of  claim 17 , wherein the curved surface comprises:
 a first curved portion; 
 a second curved portion; and 
 a substantially flat portion extending between the first and second curved portions. 
 
     
     
       21. The assembly of  claim 20 , wherein at least one of the first and second curved portions is configured to direct airflow from a fan into the gap. 
     
     
       22. The assembly of  claim 17 , wherein the compliant member comprises an encapsulated gel configured to absorb heat generated by the computer component.

Description:
TECHNICAL FIELD 
     The present disclosure relates generally to internal computer assembly features and methods. Examples of systems and methods for mounting vibration sensitive computer components to a computer enclosure are described, as well as examples for simplified and efficient locating of internal components during assembly. 
     BACKGROUND 
     Computing devices generally include numerous internal components such as memory, storage devices (e.g. disk or solid state drives), processors, thermal management devices, and various input/output (I/O) circuitry and interfaces. The components of a typical computing device are generally enclosed within a housing or enclosure, which may be made of plastic, metal, glass, and/or any other material suitable for protecting the internal components of the computer and for achieving a desired aesthetic appearance. 
     Interaction between a user and a computer is typically effectuated through I/O devices such as keyboards, trackpads, mice, trackballs, various other pointer devices, monitors, printers, and still other peripheral devices. Frequently, I/O devices are external to the housing and the computing device may be adapted for connecting with peripheral devices using standardized I/O interfaces and/or connectors. I/O connectors for plugging in peripheral devices and their respective circuitry may be provided on the main logic board of the computing device or on auxiliary circuit boards plugged into the main logic board. In some instances, such as certain laptop and handheld computers, certain I/O devices may be at least partially integrated with the computer and accessible through the enclosure. An example of I/O device integration in laptop computers is the incorporation of a keyboard and a touchpad partially within the laptop&#39;s housing. 
     In some instances, desktop computers may also have components integrated within the same enclosure which houses the display device, for example. While such integration generally enhances the user experience, new challenges may be introduced through the implementation of such integration. For example, the compact nature of integrated devices generally results in a smaller design space within which the computer components must be accommodated. The compact design space not only may necessitate smaller sized components but may bring components closer together and likely may necessitate tighter tolerances. The proximity of certain components to others may have undesirable consequences, and last but not least, aesthetic considerations may also dictate design choices. Accordingly, improved devices for locating internal computer components and improved methods for assembling internal components of a computing device within the same enclosure may be needed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The foregoing and other features of the present disclosure will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only several examples in accordance with the disclosure and are, therefore, not to be considered limiting of its scope, the disclosure will be described with additional specificity and detail through use of the accompanying drawings, in which: 
         FIG. 1  is a perspective view of an integrated computing device. 
         FIG. 2  is an isometric view of a computer component mounting assembly and hard drive according to the present disclosure. 
         FIG. 3A  is an isometric view of a compliant member for mounting a computer component according to one embodiment of the present disclosure and an example computer component therein. 
         FIG. 3B  is an isometric view of the compliant member of  FIG. 3A . 
         FIG. 4  is an isometric view of a mounting bracket according to one embodiment of the present disclosure. 
         FIG. 5A  is a perspective view of an example of a compliant member for mounting a computer component, an example of which is also shown in the figure, according to the present disclosure. 
         FIG. 5B  is a perspective view of another example of a compliant member for mounting a computer component with an example component according to the present disclosure. 
         FIG. 6  is a perspective view of a mounting bracket for use with the compliant member in  FIG. 5B . 
         FIG. 7A  is a back view of the integrated computing device of  FIG. 1 . 
         FIG. 7B  is a detail of  FIG. 7A . 
         FIG. 8A  is a partial perspective view of a circuit board showing a plurality of I/O connectors with a locating device for locating the circuit board relative to the enclosure of the computing device according to one example of the present disclosure. 
         FIG. 8B  is a detail of one portion of the locating device shown in the partial perspective view of  FIG. 8A . 
         FIG. 8C  is a detail of another portion of the locating device shown in the partial perspective view of  FIG. 8A . 
         FIG. 9A  is a partial view of the back of the enclosure depicted in  FIGS. 7A-B  looking outwardly from the interior and showing the plurality of I/O openings depicted in  FIGS. 7A-B . 
         FIG. 9B  is a partial cross-section taken at line  9 B- 9 B of  FIG. 7B . 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description, reference is made to the accompanying drawings, which form a part hereof. In the drawings, similar symbols typically identify similar components, unless context dictates otherwise. The illustrative examples described in the detailed description, drawings, and claims are not meant to be limiting. Other examples may be utilized, and other changes may be made, without departing from the spirit or scope of the subject matter presented herein. It will be readily understood that the aspects of the present disclosure, as generally described herein and illustrated in the Figures, can be arranged, substituted, combined, separated, and designed in a wide variety of different configurations, all of which are implicitly contemplated herein. 
     The present disclosure relates generally to internal computer assembly features and methods. As briefly discussed above, certain desktop computers may be integrated to include the internal computer components and display device within the same enclosure (see  FIG. 1 ). While advantageous and desirable for a variety of reasons, such integration may pose numerous design challenges. The present disclosure may offer solutions to some of these challenges as will be described and appreciated by those skilled in the art. 
       FIG. 1  shows a perspective view of a computing device  100  in which certain computer components are provided within or through the same enclosure  105  which houses the display  115 . The computing device  100  depicted in  FIG. 1  may include various computer components (not shown), such as memory, one or more processors, storage devices, I/O interface devices and other circuitry as may be known in the art. Some of the computer components, for example the hard disk drive, may be mounted directly to the enclosure  105  or a support structure attached to the enclosure  105 . Other internal components, for example the processor, system memory, I/O circuitry and connectors, may be provided on a main logic board (a partial view of an example of such logic board is shown in  FIG. 8 ), which may then be mounted to the enclosure  105  in a desired location as will be further described. The computer component, which may be a disk drive or a solid state drive, may be sized and shaped according to any of a variety of standardized form factors (as shown in the examples in  FIG. 5A ). Using a standardized component may be advantageous in terms of integration and operability, but the present disclosure is not limited in that sense. Computer components having substantially any form factor, can be accommodated using various embodiments of the present disclosure. 
       FIG. 2  shows a mounting assembly  200  for mounting one computer component  150 , for example a hard drive, to another computer component (not shown in  FIG. 2 ), for example an enclosure of the computing device. Components, other than hard drives may be mounted according to the present disclosure. While specific examples of mounting hard drives to an enclosure are described and depicted herein, the present disclosure is not limited in this manner For example, a display may be mounted to a housing for the display using a frame lined with a gasket configured to reduce vibrations. Other components, such as optical drives, or various vibration generating components such as microphone and/or fans, may be mounted to the enclosure or other support structure according to the examples herein. In another example, a cushioning or a vibration-reducing layer may be provided between a base and other components of a computer attached to the stand, so as to minimize the transfer of vibrations to the components attached to the base. Such an arrangement may be useful if the computing device is placed on a vibrating surface, for example if placed in an automobile or attached to a dashboard of the automobile. External vibrations which may otherwise be transmitted through the base and to other components of the computing device may effectively be minimized according to the present examples. 
     Referring again to  FIG. 2 , the mounting assembly  200  may be configured to accommodate a computer component  150 , which may be a hard drive as in the present example. The mounting assembly  200  may include a compliant member  300  configured to enclose at least a portion of the computer component  150  (e.g. hard drive), and the assembly  200  may further include a cradle or bracket  400  for mounting the computer component  150  (e.g. hard drive) and compliant member  300  to the enclosure  105  (described previously with reference to  FIG. 1 ). As will be further described, the bracket  400  may be used to orient the component  150  in any desired position within the enclosure, and to mount the component  150 , directly or indirectly, to the enclosure  105 . For example, the component  150  may be positioned behind and generally parallel to the display  120  within the enclosure  105 . As will be further described below, certain features of the bracket, for example variable length fastener posts and/or a base with a varying profile, may be used to accommodate mounting the bracket in such position. 
     The bracket  400  may include one or more lids  250 , as in the present example. In other examples, the computer component  150  enclosed within the compliant member  300  may be retained within the bracket  400  by a snap fit. That is, the bracket  400  may include a top portion which may be configured to extend slightly over the compliant member  300  and component  150  when the two are seated in the bracket  400 . The bracket may be adapted such that a top portion of the bracket  400  temporarily deforms to allow the compliant member  300  and component  150  to be inserted in the bracket, subsequently engaging with a surface of the compliant member  300  or component  150 . In yet other examples, a combination of these features may be used. That is, the bracket  400  may include a top portion which extends over the compliant member  300  and component  150  (an example of this configuration is depicted in  FIG. 6 ). This top portion may, but need not, deform. Once the component  150  and compliant member  300  are placed in the bracket  400 , a lid may additionally be used to secure the component  150  and compliant member  300  within the bracket  400 . Other variations and combinations for maintaining the component  150  and compliant member  300  may also be used without departing from the scope of this disclosure. 
     In some embodiments, the compliant member  300  and bracket  400  may be generally rectangular in shape, however other form factors may be implemented if desired. The compliant member  300  and bracket  400  may be shaped and sized to fit substantially any desired form factor so as to accommodate any of a variety of standardized or uniquely shaped computer components. For example, various vibration or shock sensitive components, such as optical drives, may also be mounted according to the examples herein. In other examples, components tending to generate vibrations, such as microphones, speakers, or fans, may be mounted as described herein so as to prevent vibrations generated by such components from being transmitted to the enclosure and/or other components attached thereto. 
     Compliant members according to the present disclosure may be configured to reduce or damp out vibrations or other dynamic loading from being transmitted from an external source to the computer component mounted within the bracket, or from the component mounted within the bracket to other components of the computer. For example, in the case of a hard drive, shock or vibrations transmitted to the hard drive while in operation may lead to read/write errors or defective sectors, and some hard drives may be particularly sensitive to vibrations. Shock or vibrations may be generated by a variety of sources external to the hard drive, such as the microphone or fan, or from sources external to the computer (e.g. the user). Conversely, the component  150  (e.g. a microphone or a fan) may generate vibrations which may be transmitted to other components of the computing device  100 . To minimize or eliminate undesired motion experienced by the component  150  (e.g. hard drive, optical drive, or the like), a compliant member  300 , as will be described, may be placed between the rigid enclosure  105  and the component  150 . The component  150  thus insulated may then be provided in a bracket or cradle  400 , which may be rigidly mounted to the enclosure  105 . The cradle may maintain the component  150  in the desired position relative to the remaining internal components while the compliant member may function to reduce transmission of vibrations to or from the component  150 . 
       FIG. 3A  shows an example of a compliant member  300  according to the present disclosure. The compliant member may be implemented as a sleeve, which may be configured to enclose the component  150  or portions thereof. The compliant member  300 , which may be a sleeve, may have a shape which resembles the shape of the component  150  and may be sized to fit snugly over the component  150 . In some embodiments, the compliant member  300  may fully enclose the component  150 , and openings may be formed in the compliant member  300  for cable runs, for example. In some examples, the interior contact surface of the compliant member  300  may be textured or ribbed to provide a less rigid contact area between the sleeve and component  150 . In other embodiments, only portions of the component  150 , for example the corners or certain edges, may be enclosed within the compliant member  300 . 
     In some examples, the component may have a generally circular or oval shape, and the compliant member  300  may be shaped generally cylindrical in shape so as to complement the rounded shape of the component. In such examples, the compliant member  300  may be configured to engage with one or more sides and/or edges of the rounded component, for example by receiving the outer perimeter portion of the component  150  within similarly shaped side portion of the sleeve. Other configurations and/or form factors may be used if desired or dictated by the particular application. 
     The compliant member  300  may be formed using substantially any compliant polymer material, such as rubber or other elastomeric materials. In some examples,  30 A durometer rubber or silicon may be used. Other polymers or combinations of polymers may be used and tailored to achieve the desired rigidity or flexibility of the various parts of the compliant member  300  (e.g. sleeve) as described. Foam material and/or gels may also be used in some examples. The compliant member  300  may be sized and shaped such that at least some portions of the sleeve  300  form a snug fit with the component  150 . For example, the compliant member  300  or portions thereof may need be stretched to receive the component  150 . In some examples the compliant sleeve may define a cavity having substantially the same shape as the component  150  such that the component  150  may be received within the cavity. Certain portions of the compliant member  300  may be configured to elongate or deform more than other portions of the sleeve as will be further described. 
     The compliant member  300  (e.g. sleeve) may have a plurality of contact portions spaced apart from one another and configured to engage one or more surfaces of the computer component  150 . The contact portions may be implemented as corner portions, as will be described further below, or they may be implemented as edge rails, flexible wall spacers, or other similar structures configured to maintain the component  150  in a spaced apart configuration relative to the bracket  400 . Referring to the example in  FIG. 3B , the compliant member  300  may have four contact portions, which in the present example are the corner portions  301 - 304 . The corner portions  301 - 304  may be generally rectangular structures, shaped to grip each corner by engaging with one or more surfaces at each corner of the component  150 . In the present example, the corner portions are configured such that all four surfaces at each corner contact a corresponding interior surface of the corner portion. In other examples, fewer surfaces may be contacted, for example by providing sufficient tension between two opposing contact surfaces of the corner portions such that the component  150  is maintained in position by friction. 
     In some embodiments, the number of corner portions may vary, for example when the component  150  has a complex geometry. In other examples, a compliant member  300  which may be configured to enclose a generally rectangular component  150 , may have fewer than four corner portions. For example, the sleeve may have two corner portions and may be configured to grip two opposing corners of the component  150  with a void remaining between the component  150  and bracket  400  at the remaining corners not otherwise enclosed in the sleeve. Other combinations for engaging with the component  150  may also be used without departing from the scope of this disclosure. 
     In some examples, the contact portions (e.g. corner portions  301 - 304 ) may reduce vibrations that may otherwise be transmitted to the component  150  during various dynamic loading conditions (e.g when component  150  is subjected to sudden movements). Each of the corner portions  301 - 304  may include a plurality of structures adapted to act as a spring and thereby essentially “float” or “suspend” the component  150  relative to the rest of the structure (e.g. enclosure  105 ). The spring structures may be implemented as a plurality of protrusions or fingers  315 - 318 , which project perpendicularly from one or more surfaces  319  of the contact portions. In the present example, the corner portions  301 - 304  are configured to enclose and contact all four surface of the component  150  at each respective corner. Accordingly, spring structures (e.g. fingers  315 - 318 ) are provided perpendicular to each of the surfaces of the contact portions opposite respective surfaces of the component  150 . That is, each interior surface of each corner portion may have one or more fingers extending therefrom. In some examples, three or more fingers may protrude from each surface. In other examples fewer than three fingers may be used and tailored to provide a desired stiffness of the joint at each corner. The plurality of fingers  315 - 318  may be parallel to one another, or they may be angled relative to one another. In some examples, the fingers  315 - 318  may be regularly or irregularly spaced apart. Some or all of the fingers may have cross-sectional profiles different from the cross-sectional profiles of other ones of the fingers  315 - 318 . For example, some of the fingers may have a generally rectangular transverse cross-section, while other fingers may be shaped as a trapezoid. 
     The fingers  315 - 318  may also vary in thickness and composition (e.g. different fingers being made from different materials). As described, different materials, including various elastomeric materials, foams or gels may be used to form the contact portions of the compliant member  300 . Combinations of or composite materials may be use to tailor the stiffness of the contact portions. For example, foam and/or gel may be added between the fingers  315 - 318  or used in place of the fingers  315 - 318 . As will be appreciated, many other form factors may be used. For example, additional ribs may be provided between some or all of the individual fingers  320  to stiffen the joint, if desired. In examples, the cross sectional profile of the fingers may change, for example widen, as a particular finger  320  approaches and attaches to the surface  319 . By varying the length, thickness, material and other design parameters, the compressive and bending stiffness of each finger the compliant joint  321  as a whole may be tailored as may be appropriate as desired. 
     As described, the cross-section of the corner portions may be generally rectangular, and in some examples, the corners of the outer surfaces or some or all of the corner portions may be rounded. That is, in some embodiments, the corner portions  301 - 304  may have rounded and/or flattened portions. Surfaces  326 ,  327 ,  328 , as examples, may be generally flat and may provide a stable contact area with corresponding surfaces the bracket  400 . Some or all of the corners,  331 ,  332 ,  334 , and  336 , as examples, may be rounded for ease of placement of the sleeve  300  within the bracket  400  and/or lid  250 . Thus, the combination of flattened surfaces and rounded corners may allow for the sleeve assembly  350  to be easily inserted in the bracket  400  while providing a stable contact surface between the two. The rounded and flattened portions of the sleeve  300  and corresponding matching surfaces of the bracket  400  may also serve a locating function (e.g. to dictate a placement of the sleeve in a particular position within the bracket). Other locating features on the mating surfaces of the sleeve  300  and bracket  400  may also be included without departing from the scope of this disclosure. 
     In further examples, some or all of the corner portions  301 - 304  may be connected using connector strips  305 - 310 , which may be fabricated from the same or a different elastomeric material. The connector strips  305 - 310  may be solid along their length or they may have one or more cutouts for added flexibility or for access the component  150 , for example for plugging in a cable. The connector strips  305 - 310  may or may not come in contact with the component  150 . In some examples, the thickness of the strips may vary along their length, or certain surface features such as ribs, may be added if desired. That is, in some examples, the strips (e.g.  305 - 310 ) may lay against the surface of the component along all or a portion of the distance which they span. Alternatively, the strips (e.g.  305 - 310 ) may be offset from the surface of the component  150 . As will be understood, any combinations of number and/or placement of the connector strips may be used. For example, one or more connector strips may be used to connect the corner portions along a top  160  and/or bottom  162  surfaces of the component  150  (see  FIG. 3A ), or the may span the sides  164 ,  166  of the component. The sleeve may include some of the strips  305 - 310  or additional strips may be added. 
     In some examples, the compliant member  300  (e.g. sleeve) may be formed as a single unitary structure, for example by conventional injection molding or other conventional polymer fabrication techniques. In other examples, portions of the compliant member  300 , for example the corner portions, may be fabricated separately from other portions and assemble to form the sleeve  300 . Different polymeric materials may be used for different portions of the compliant member as desired and/or to obtain effective damping of motion which may otherwise be transmitted to the component  150 . For example, overmolding may be used to lay-up a compliant member  300  (e.g. sleeve) having a softer interior and a stiffer outer layer, for example. Conventional injection molding techniques may be used and different materials may be injected at different location along the mold to obtain a desired stiffness of the various portions of the compliant member  300 . 
     In some examples, the compliant member  300  may include only the contact portions (e.g. corner portions  301 - 304 ), which in this example may not be connected together but may instead separately engage with each edge or corner of the component  150  before placing the component  150  into the bracket  400 . Alternatively, the contact portions may be fixedly secured to the bracket  400  and the component  150  may be positioned into the cradle without removing the contact portion. Other variations of providing the compliant member  300  between the component  150  and the bracket or cradle  400  may be used without departing from the scope of this disclosure. For example, a pliable material, such as an encapsulated gel, or a shape-memory material, such as a viscoelastic memory foam, may be layered within the bracket  400  or over other stiffer layers disposed in the bracket. The pliable or shape-memory material may be allowed to deform to the shape of the component  150  when the component  150  is provided therein. In the case of using a gel, alone or in combination with other polymeric materials, the gel may aid with cooling the component  150  by absorbing some of the excess heat generated by the component  150 . Cutouts or other features may also be included through the thickness of these materials to allow for cooling of the component  150 . 
     Referring now to  FIG. 4 , a mounting bracket  400  according to the present disclosure may include support members  401 - 404 , one or more receiving portions  406 - 409 , and a bottom portion and/or side portions  410  connecting the receiving portions  406 - 409  together. The bracket  400  may be sized and shaped to accommodate the component  150  and compliant member  300  therein. The mounting bracket  400  may be sized and shaped to form a snug fit with the sleeve assembly  350 . In this manner free play between the bracket and sleeve assembly  350  may be reduced and/or undesirable movement of the component  150  may be minimized. In some examples, additional structures (e.g. top brackets or lids  250 ) may be included to further secure the sleeve assembly  350  within the mounting bracket  400 . 
     The bracket  400  may be rigidly mounted, directly or indirectly, to the computer enclosure (e.g., by mounting it to other internal structure of the enclosure  105 , such as ribs, posts, or other similar structures). The bracket  400  may be affixed to the enclosure using any conventional means, for example by fastening, welding, bonding, adhering or the like. The bracket  400  may be bolted to the enclosure  105  using the support members  401 - 404 , which may be implemented as posts and which may have a threaded portion  405  for securing the bracket using a standard fastener. The support members  401 - 404  may be generally identical in shape and/or size. 
     In some examples, the bracket  400  may need to be mounted to a surface which is not flat, for example the interior back surface of the enclosure  105  (shown in  FIG. 1 ), which may be curved or angled relative to the bracket  400 . When mounted, the base  410  of the bracket  400 , and specifically the under surface  419  of the base is adjacent the interior surface of the enclosure  105 . In order to accommodate the curved profile  110  of the enclosure  105 , the bracket  400  may be shaped to complement such a curved profile  110 , and the support members  401 - 404  may be configured to be mounted to a curved surface or a surface disposed at an angle relative to the longitudinal axis of the bracket  400 . To achieve this, the length of one or more of the support members  401 - 404  (e.g. posts) may be different from the length of other support members. That is one or more of the posts  401 - 404  may be longer or extend further in a given direction than other posts. One or more of the lengths  411 - 413  may be different than the lengths of the other posts. In other examples, bosses on the interior surface of the enclosure having different lengths may be used in order to compensate for the variable distance between the bracket  400  and the mounting surface. 
     The mounting bracket  400  may further include one or more receiving portions  406 - 409  for accommodating the sleeve assembly  350  which includes the compliant member (e.g. sleeve)  300  and component  150  therewithin. The receiving portions  406 - 409  may be shaped substantially identically to the exterior portions of the compliant member  300  which will be provided within the receiving portions  406 - 409  thereby working in conjunction to stabilize the sleeve assembly  350  within the bracket. For example, the receiving portion  408  may have an inner surface  414  (e.g. inner mold line) which may be substantially the same as the outer surface  321  (e.g. outer mold line) of the corner portions  301 - 304 . The receiving portions  406 - 409  may be connected using one or more rails  420 ,  421 , which may be substantially flat or otherwise shaped to match the bottom profile of the sleeve. The rails need not be identically shaped or sized, and one or more of the rails may include additional features, for example cutouts  422  for routing cables through the bracket and to the component  150  to be mounted therein. In some examples, the cutout  422  may additionally serve to secure the cable runs in place and/or prevent the cables from interfering with other components. In some examples, one or more of the rails (e.g. rail  420 ) may extend substantially to the edge of the respective receiving portions (e.g.  408  and  409 ) so as to provide a more stable base for the sleeve assembly  350 . 
     As mentioned above, the mounting bracket  400  may also include a base  410  which extends between the rails  420  and  421 . The base  410  may include a generally flat portion  423  and curved portions  415  and  416 , the curvature of which need not be the same. The base  410  may be configured to form a cooling channel between the lower surface of the component  150  (not shown in  FIG. 4 ) and the upper most portion of the base. For example, the generally flat portion  423 , which is be the upper most portion of the base  410 , may be spaced apart from a plane defined by the rails  420 ,  421 . The rails  420 ,  421 , working in cooperation with the receiving portions  406 - 409 , as previously described, may be configured to support the sleeve assembly  350  within the bracket  400  thereby controlling the placement of the assembly  350  relative to the base  410 . Accordingly, an air space may be formed which may assist with cooling of the component  150 . The combination of the surface profiles of the curved portions  415 ,  416 , and base  410  may in cooperation define an airfoil-like surface  417 , which may speed up air passing under the component  150  thereby improving the cooling characteristics of the mounting assembly  200  (see  FIG. 2 ). As will be understood, any other airfoil profiles or combinations of curved and/or flat surfaces may be used to tailor the flow of air below the components. In some examples, the rails  420 ,  421  may instead be placed between support member  401  and  404  and between support member  402  and  403 , and the airfoil-like surface  417  may instead span a direction orthogonal to the direction depicted in  FIG. 4 . In other examples, the bracket  400  may not include rails and two airfoil-like profiles may be defined along the two orthogonal directions between the support members  401 - 404 . As can be appreciated, numerous variations are possible to take advantage of the location of various active cooling components (e.g. fans or other sources of airflow) relative to the mounting assembly  200  (as shown in  FIG. 2 ). 
       FIGS. 5A and 5B  show examples of computer components  150  and compliant members  300  for mounting the computer components  150  according to the present disclosure.  FIG. 5A , shows the compliant member (e.g. sleeve)  300  discussed previously with reference to  FIGS. 2-4 , which may include any of the combinations of features described herein.  FIG. 5A  shows another example of a compliant member  500  for mounting a component  550 , which may be of a different size than the component  150 . As with the sleeve  300 , generally any computer component, such as a hard disk drive, an optical disk drive, sold state drive, audio components, various cooling components, or others, may be mounted to the enclosure or other structures of a computing device. As previously described, the components  150 ,  550  may vary in shape and/or size and accordingly sleeves  300  and  500  having complementary shapes and sizes may be manufactured for accommodating such components. It will also be understood that any of the compliant sleeves  300  and/or  500  may be implemented to incorporate any of the features of compliant sleeves described and appreciated in light of this disclosure. 
     The compliant member  500  may include many of the same features as the compliant member  300 . For example, the compliant member  500  may include one or more corner portions  501 - 504 , which may include similar features as the corner portions  301 - 304  previously described (see  FIG. 3B ). For example, one or more damping features (e.g. spring structures) similar or identical to the fingers  315 - 318  of sleeve  300  may be included on inner surfaces of the corner portions  501 - 504 . One or more of the corner portions  502 ,  503  may have surface  511 ,  512  with variable profiles. This feature may be used, in conjunction with the examples of spring structures (not shown in this figure for clarity of illustration), to adjust the stiffness at different locations within the corner portions  501 - 504 . For example, the lower portion  513  of the surface  511  may accommodate longer length fingers, while the upper portion  514  of the surface  511  may have shorter fingers. The shorter fingers may be stiffer than the longer fingers, and accordingly the stiffness provided by the corner portion  502  may vary along the length of surface  511 . 
     The corner portions  501 - 504  may have flattened and rounded surfaces, as previously described. In some examples, the corner portions  501 - 504  may be nearly fully rounded to form a generally circular or oval structure. Air spaces may remain between the sleeve and certain parts of the bracket  400  in such examples, or the receiving portions of the bracket  400  may have a complementary shape to the corner portions, as previously described. In other examples, the corner portions  501 - 504  may be generally angular  515 - 517  with the corners transitioning one surface  518  at a nearly right angle to the adjacent surface  519 . The corners of a corresponding bracket, as will be described below with reference to  FIG. 6 , may have a similar angular arrangement rather than having rounded receiving portions as previously described. 
     The compliant sleeve  500  may also include connecting strips  505 ,  507 ,  509 , and  510  which may be implemented similarly to the connecting strips  305 - 310  previously described. Any number of connector strips may be used, for example the four connecting strips  505 ,  507 ,  509 , and  510 , as shown, or other number or placement of strips may selected as previously discussed. The connecting strips  505 ,  507 ,  509 , and  510  may serve the function of connecting the corner portions and/or tensioning the corner portions against the surfaces of the component  550 . The strips may also be used to reduce vibrations, for example by being provided with certain surface features which may contact the surfaces of the component  550  and further cushion the component  550  therewithin. 
       FIG. 6  shows another example of a bracket or cradle  600  for use with the compliant member  500  of  FIG. 5B . The bracket  600  may include many of the features of the bracket  400  previously described and accordingly, and for brevity their description will not be repeated. For example, the bracket  600  may include receiving portions  606 - 609  for seating the corner portions  501 - 504  of the sleeve  500 , and the bracket  600  may further have mounting portion  601 ,  604 , as examples, which may be used to fasten the bracket to the enclosure (not shown) using any conventional means. Analogous to the bracket  400 , the mounting portions may be configured to accommodate a slanted mounting surface. In some examples, the mounting portions  601 ,  604 , may be located at different distances from the bottom plane  619  of the bracket, thus allowing the bracket  600  to be provided at an angle to the slanted surface. That is the mounting portion  601  may be used to mount one end of the bracket  600  in a more elevated position as compared to the end mounted using the mounting portion  604 . In other examples, in place of or in combination with the above feature, bosses of different heights may be used to further tailor the relative angle between the mounting surface and the plane  619  of the bracket  600 . 
     In certain examples, the bracket  600  may be mounted with the top portions of the receiving portions  607 ,  606  closest to the mounting surface. In such examples, the component  550  (e.g. the hard drive shown in  FIG. 5B ) is first inserted in the bracket  600 , for example by sliding the component  550  and sleeve  500  in the receiving portions  607 ,  608  such that the top portions of the receiving portions  607 ,  606  engage the component and sleeve. The bracket  600  is attached to the mounting surface in an upside-down position relative to the mounting surface such that the compliant member  500  and component  550  are sandwiched between the mounting surface (not shown) and portions of the bracket  600 . One or more surfaces of the compliant member  500  may be in contact with the mounting surface in this configuration. In this manner, the compliant member  500  and component  550  enclosed therewithin may be held in place by a combination of the bracket  600  and the mounting surface, for example the interior surface of the enclosure, to which the bracket  600  may be attached. In this manner, the bracket  600  may be used without a top bracket (e.g. lid  250  of the example in  FIG. 2 ). The mounting surface (e.g. interior surface of the enclosure) may function as the top bracket or lid, when the bracket  600  is mounted in this configuration. 
     In the example in  FIG. 6 , the bracket  600  may not have a bottom plane  619  but may instead include a plurality of side members  620 - 623  which connect the receiving portions  606 - 609  of the bracket  600 . The brackets  400  and/or  600  may be formed using substantially any rigid material, such as plastic, metallic materials and others. The brackets  400  and  600  may be formed as single-piece (e.g. monolithic) structures or their respective components may be fabricated and assembled to form the brackets described. As will be appreciated, many variations of the brackets  400  and  600  described herein are possible without departing from the scope of this disclosure, and the examples provided are for illustration only and not to be viewed in a limiting sense. 
     Referring now to  FIG. 7-9 , examples of devices and methods for mechanically locating and aligning internal computer components will be described. As will be understood, degrees of freedom (DOF) of a rigid body are determined base on the number of axes along or about which the body may be allowed to move. Generally, in a Cartesian coordinate system, an unconstrained body may be able to translate along the three axes, X, Y, and Z and may also be able to rotate about all three axes. A body is said to be fully constrained (e.g. all six DOF have been removed) when the body is fixed in all six DOF (e.g. movement along and about all axes is prevented). In the context of the present disclosure, in addition to positioning the component in a desired location, the term “locating” may also be used to mean constraining the component in some or all of the DOF. 
     In the case of conventional computers the enclosure may be generally rectangular with each of the flat surfaces of the enclosure arranged at right angles to each other. Locating and/or aligning components relative to such rectangular enclosure may be fairly easy as the flat surfaces may themselves be used to drive alignment. For example, a logic board may have a generally flat surface and may have two or more edges that are orthogonal to each other. Certain components on the logic board, for example I/O ports, may protrude from the board, typically at right angles to the board. As such, top surfaces of the I/O ports may define a plane which is parallel to the logic board. The top surface of the I/O port, in cooperation with one or more of the edges of the board, may be used to locate and align the board relative to certain features in the enclosure (e.g. cutouts through the enclosure, which may be used to access the ports). Furthermore, as the top surface of the I/O ports and the inner surface of the enclosure are typically parallel to each other, it may be easier to maintain the two parts in alignment during use because the surfaces may typically be resting against one another. 
     In some instances, it may be desirable to locate and thereby maintain a generally rectangular component in alignment relative to an angled surface. For example, in the case of the computing device in  FIG. 1 , some of the surfaces of the enclosure  105  may be curved. The back of the enclosure  105  is shown in  FIG. 7A , and in further detail in  FIG. 7B . The enclosure  105  of the device  100  may have one or more cutouts  125 ,  126  for accessing one or more of the I/O ports, which may include a variety of standard I/O ports (USB, HDMI, Ethernet, audio ports, or the like). Each cutout  126  may be shaped and sized to accommodate access to the port and allow the user insert a corresponding standard plug therethrough. The number and relative arrangement of the ports and cutouts may be varied and the particular example depicted and described herein is for illustration purposes only. The circuit board (shown in phantom lines in  FIG. 7B ), to which the I/O ports are connected, may need to be aligned relative to the enclosure such that each of the I/O ports is accessible through the corresponding cutout. Misalignment of one or more of the I/O ports may at the very least be displeasing to the user from a cosmetic standpoint. From a functional standpoint, misalignment may render the I/O port useless (e.g. inaccessible) or may cause damage to the port and/or plug due to interferences when the user attempts to plug into the port. As can be appreciated, good alignment may be desirable for both functional and aesthetic reasons. When mounting components with complex surfaces, optical equipment, such as charge-coupled device (CCD) cameras or laser alignment tools, may frequently be required to locate and align the components. However, the use of such equipment is expensive and time consuming. The exemplary devices and methods for locating internal components described herein may address these and other problems in the art. 
       FIG. 8  shows a partial view of an example logic board  800  with a plurality of I/O ports  810  attached thereto. As described, the ports  810  are typically attached to the board so that they project generally orthogonally from the board. The ports  810  may be provided adjacent a bottom edge of the logic board  800  and may be generally aligned for cosmetic reasons, for example along a centerline of each port  810 . References to locations (e.g. “top,” “bottom,” etc.) are used herein for purposes of facilitating a description of the examples, and are not to be taken in a limiting sense. The logic board  800  may be attached to the enclosure  105  (see FIG.  1 ) during assembly such that the plurality of I/O ports  810  are visible and/or accessible through the cutouts  125 ,  126 . Accordingly, mechanical locating devices, which may allow for precise alignment of the logic board  800  relative to the enclosure without the use of optical equipment, is described in further detail below. 
     The mechanical locating devices according to the present disclosure may include a plurality of locator pins which are configured to engage within respective locator divots formed on a surface of the enclosure. Each pin may be sized to fit within the respective divot and the combination of pins and divots described may effectively restraint movement of the logic board  800 . In some embodiments, and as depicted in  FIG. 8 , two locator pins  821 ,  822  may be used to drive alignment. The pins  821 ,  822  may be sufficiently spaced apart so as to achieve the desired angular control. Various form factors and number of pins may be used to suit the particular application. That is, a variety of combinations of shapes and number of pins may be used, some of which will be further described below and other appreciated in light of this disclosure. 
     In the example in  FIG. 8 , a first pin  821 , which may be have a circular cross-section, may be provided proximate a first I/O port  811 . A second pin  822 , which may have a generally rectangular cross-section, may be provided proximate a second I/O port  813 . The first or circular pin  821  may be used to establish a first datum point during assembly, which may generally restrain all but one axis of freedom. In this example, the first pin restrains translation along all axes and rotation about all but one of the axes. The logic board  800 , once located using the first pin, may still be free to rotate about the third axis (e.g. the center axis of the pin  821 ). The second pin  822  may then be used to restrain the last (e.g. rotational) degree of freedom. That is, rotation about the axis of pin  821  is restrained upon engaging the second locator pin within the second slot (e.g. “locking” the board  800  in place). A different sequence may be instead be used. That is, the rectangular pin  822  may be placed in engagement with its corresponding divot. Depending on tolerances and other design considerations, the pin  822  may still be able to translate along one axis (e.g. the longitudinal axis of the pin&#39;s cross-section). Engaging pin  821  with its respective circular divot may then constrain the last degree of freedom. 
     In some examples, the locator pins  821 ,  822  may be located a certain distance apart to minimize or remove relative movement of the parts without over constraining the alignment. If the pins are very close together, for example adjacent one another, motion may be fully constrained as between the two pins but perimeter portions of the component (e.g. logic board  800 ) may be free to move relative to certain other portions of the enclosure. Alignment and/or locating of features or devices on the logic board  800 , which are farther away from the pins, may be poor when the pins are so close to one another. On the other hand, if the pins are placed at the farthest ends of the board, engagement with the divots may be difficult due to imperfections and imprecision of the manufacturing process. Therefore, the locator features may be spaced apart by some intermediate distance between the two extreme examples described. The spacing between the pins may, in some instances, be from about 3 inches to about 10 inches apart. In other examples, the pins may be from about 4 inches to about 6 inches apart. In some examples, the pins may be about 5 inches apart. Other distances may be used as desired or depending on certain design considerations. 
     The placement of the locator features on the board may be selected based on which components it may be most critical to locate precisely. That is, while the locator features described in reference to the logic board  800  may have been placed anywhere on the board, for example along top portions of the board (not shown in the figure), in the particular case it may be desirable to place the locator pins near the ports because the ports may require more precise alignment than other portions of the board. However, the depicted location is provided as an example to illustrate the inventive concepts herein, and the locations of the pins in other examples may vary. 
     Furthermore, in some embodiments, and as shown in the example in  FIG. 8 , a circular pin  821  and a rectangular pin  822  may be used in combination to achieve precise alignment without over constraining the system when manufacturing tolerances are taken into account. Other shapes and combinations may be used, for example two circular pins, which may have relaxed tolerances to prevent over constraining the assembly. Two rectangular pins, disposed at an angle to one another (e.g. orthogonally to each other) may be used in other examples. According to yet other examples, pins having different tolerances may be used. For example, one pin may be designed to have a clearance fit and/or with a large manufacturing tolerance. The clearance fit and/or larger tolerance may allow for certain amount of movement between the two parts when only the first pin is engaged. A second pin may be used, which has a tighter tolerance or which is design for a transition/location fit with its mating divot. When mated within the corresponding divot, the second fit may prevent any movement, locking the two parts into place. 
       FIG. 9A  shows a portion of the interior surface of the enclosure  910 , through which the plurality of cutouts  125 ,  126  may be provided for accessing a plurality of I/O connectors previously described. The enclosure  910  may be identical or similar to the enclosure  110  of  FIG. 7 . For example, and as previously described, the enclosure  910  may have first  911  and second  912  cutouts adjacent one another. The cutouts  911 ,  912  may configured to allow the user to plug into a corresponding I/O port and may accordingly be sized and shaped to allow for a plug of the kind to be inserted therethrough. In some examples, a first locator feature  921  may be provided adjacent the first  911  and/or second  912  cutouts. A second locator feature  922  may be spaced apart from the first locator feature  921  and provided adjacent another one or plurality of cutouts  913 . The locator features  921  and  922  are surface features (e.g. detents, or protrusions) and are not apertures extending through the thickness of the enclosure. As such, the locator features are not visible through or on any of the cosmetic (e.g. exterior) surfaces of the computing device. In some examples, the first  921  and second  922  locator features may be aligned along one or more axes relative to each other, however such alignment is not necessary for proper functioning of the locating devices. Generally, any spacing and or relative positioning of the locator features  921  and  922  may be used provided the features  921  and  922  are positioned to correspond to the placement of the pins on the logic board  800  or other component. In the present example, two locating pins (e.g.  821 ,  822 ) are used to drive alignment in cooperation with the two locator features  921 ,  922  depicted in  FIG. 9A . 
     In some example, the locator features (e.g. features  921 ,  922 ) may be shaped to complement the cross section of each pin. That is, in the present example, a circular divot (e.g. feature  921 ) and an elongated slot or divot (e.g. feature  922 ) may be used. As will be appreciated, the combination of circular and elongated locating features may be advantageous as they may allow for good alignment to be obtained without over constraining the alignment. For example, if two circular pins and divots are used it may be difficult to engage with their corresponding locator features as manufacturing tolerances may cause the two pins to be spaced apart slightly differently than their corresponding locator features. By using a circular pin, the logic board  800  may be located and constrained in all but one axis (e.g. rotation about the centerline of pin  821 ). Subsequently, the logic board  800  may be rotated until it snaps within slot  922 , with the longitudinal configuration of the slot  922  compensating for slight differences in manufacturing tolerances. However, and as previously described, other implementations may also be used which may allow for sufficient movement of the parts (e.g. logic board  800  and enclosure  910 ) relative to one another such that the pins may engage with the divots. 
     In some examples, the locating features (e.g. pins  821 ,  822  and corresponding surface features  921 ,  922 ) may be e configured to accommodate a curved enclosure. As depicted in  FIG. 9 , the enclosure  105  may have a curved profile. Accordingly, so that the connector  812  is precisely located relative to the enclosure and the cutout  912 , the pin  821  may have a first length selected to provide pin  821  in engagement with the feature  921 . A second pin (e.g. pin  822 ) may have a second length also selected to provide pin  822  in engagement with the feature  922 . That is, in examples, the length of the respective pins  821 ,  822  may be selected to correspond to the depth of the enclosure in a particular location, thus accommodating for the curved surface  110  of the enclosure  105 . As will be appreciated, while particular examples of subtractive features (e.g. divots/slots  921 ,  922 ) have been depicted and described, the surface features may be additive (e.g., protruding features provided on the inner surface of the enclosure  105 ). 
     Any combination and number of pins may be used to achieve a desired level of control and precision of the alignment. For example, three locating pins may be used in some cases. Two of the pins may be elongated pins configured to be provided within elongated divots. A third pin, which may be circular in cross-section, may be used to restrain remaining freedoms of motion. For example, the elongated pins may be parallel to each other. Once the elongated pins are provided in engagement with the divots, the part may be substantially restrained from movement in all but one translational axis. A circular pin may be used to lock the part into place preventing any further translation or sliding of the part relative to the surface to which it is being located. Additional features such as dents or protrusions may be used to snap the pins into place. In some examples, the pins and/or divots may be made from or lined using a polymer material which may be allowed to compress slightly to allow for an interfering fit between the pin and divot. 
     While the specific examples described relate to aligning I/O ports to their corresponding openings, the locating devices according to this disclosure may be used to align a wide variety of other components. For example, in addition to locating circuit boards relative to another structure of the computing device, locating devices of this type may be used with for aligning the mounting brackets  400 ,  500  as may be desired. Locating devices may also be incorporated in display modules, internal power source devices, storage devices, and others. According to the examples described, and as will be appreciated, precise placement of various internal components may be achieved without the use of an optical device. 
     Examples of devices for mechanically aligning an internal computer component relative to an enclosure have been described. An exemplary device for mechanical alignment may include a first pin rigidly mounted to the internal computer component at a first location and configured to engage with a first locating feature provided on a surface of the enclosure, the first locating feature shaped so as to mechanically engage the first pin. The device may further include a second pin rigidly mounted to the internal computer component at a second location spaced apart from the first location, the second pin configured to engage with a second locating feature provided on a surface of the enclosure. In some examples, the first pin may have a circular cross-sectional profile, and the second pin may have a an elongated cross-sectional profile. In examples, the first locating feature may have a shape substantially similar to the cross-sectional profile of the first pin, and the second locating feature may have a shape substantially similar to the cross-sectional profile of the second pin. In examples, one or more of the first pin and second pin may be attached proximate one or more I/O connectors. In preferred examples, the circular pin may be mounted adjacent critical I/O connectors from the standpoint of requiring precise alignment. In some examples, the first pin may have a first height and the second pin may have a second height, the second height being different from the first height. 
     An exemplary method of aligning an internal computer component relative to an enclosure may include the steps of engaging a first pin attached to the computer component with a first feature provided on a surface of the enclosure, and moving the computer component to engage a second pin attached to the computer component with a second feature provided on the surface of the enclosure. According to some examples, the step of engaging the first pin may include inserting the first pin within a divot on the surface of the enclosure. According to some examples, the step of engaging the first pin may include providing a circular pin within a circular surface feature on the surface of the enclosure, and the step of moving the computer component may include rotating the computer component about the center axis of the first pin. In light of the examples described, various other implementation of devices for locating and alignment of components without the use of optical equipment may be appreciated and practiced without departing from the scope of the present disclosure. 
     While various aspects and examples have been disclosed herein, other aspects and examples will be apparent to those skilled in the art. The various aspects and examples disclosed herein are for purposes of illustration and are not intended to be limiting, with the true scope and spirit being indicated by the following claims.

Metadata:
Filing Date: 20120910
Publication Date: 20170207
Grant Date: 20170207
Priority Date: 20120910
Inventors: NGUYEN ANTHONY PHAM
DEFOREST LAURA M.
GOLDBERG MICHELLE
JAYANATHAN STEPHEN VINCENT
FETTERMAN KEVIN SCOTT
CUSEO JAMES M.
FUNAMARA JOSHUA RYAN
Assignee: APPLE INC
CPC Classifications: [{"code": "G06F1/183", "inventive": true, "first": false, "tree": "[]"}, {"code": "G06F1/187", "inventive": true, "first": true, "tree": "[]"}, {"code": "G06F1/183", "inventive": true, "first": false, "tree": "[]"}, {"code": "G06F1/187", "inventive": true, "first": true, "tree": "[]"}]
Family ID: 50233085