Patent Description:
In the last few years the functionality of portable electronic devices has increased exponentially. Further improvements be realized by investigating ways to maximize the utility of unused portions of these devices. Form factor is an interesting area for development given that a large majority of portable electronic devices have settled into a standard form factor; namely a flat planar form factor with a display on one side and an opaque housing which contains the electrical components covering the rear surface of the device. Unfortunately, this popular form factor, leaves the sides and rear surfaces of the device unused or at best configured with buttons and switches with fixed location and functionality. Since many of these buttons and switches have fixed functionality they cannot always be incorporated into third party applications.

<CIT> discloses a housing for a portable electronic device comprising: a first transparent curved portion configured to curve from a front face of the housing to a first side face of the housing; a second transparent curved portion configured to curve from the front face of the housing to a second side face of the housing; a third transparent curved portion configured to curve from a rear face of the housing to the first side face of the housing; and a fourth transparent curved portion configured to curve from the rear face of the housing to the second side face of the housing.

<CIT> discloses an interactive display screen which may be fitted or associated with a container or vessel. In an embodiment, the display screen is wrapped around or configured to surround entirely or partially a host object. In a further embodiment, the display screen is activated by a received signal from a sensor associated with the display screen, a remote activation signal, or a simple press of an activation button by a user. In an embodiment, the display screen is configured to exhibit media such as email(s), text message(s), photo(s) and/or video(s) received from a mobile device and/or other locations.

<CIT> discloses multi-layered imaging device for three-dimensional image display, comprising a plurality of two-dimensional layers superposed in the third dimension, each of said layers having two major surfaces and at least one peripheral edge, said layers being made of a material selected from the group of nonconventional, polarizer-free liquid crystal materials including polymer-dispersed liquid crystals (PDLC) and derivatives and combinations thereof, wherein the exposure of at least one of said layers to illumination allows the transmission of light with minimal losses, facilitating utilization of a maximal number of layers for imaging a three-dimensional display.

<CIT> discloses a mobile terminal including a body and a display module, which is flexible and is capable of receiving a touch input and a method of controlling the mobile terminal are provided. The method includes setting the touch sensitivity of a display module to a first level; if the display module is bent or folded, setting the touch sensitivity of a bent or folded portion of the display module to a second level; and if the display module is unbent or unfolded and thus returns to its original shape, setting the touch sensitivity of the bent or folded portion of the display module back to the first level.

<CIT> discloses a computer dynamic cylindrical display. The display encloses the electronics of the device and contains a simple weighted cam that senses roll (using rotation sensor much like in a mouse). When the cylinder is placed on a flat surface and rolled up and down, the pixel display scrolls in correspondence with the rolling movement, giving the visual feel of rolling a cylindrical magnifying glass across a finely printed document. A "snap-to" scrolling algorithm makes it easier for the user to stop right on the center of a line of text. Parallax algorithms compensate for the cylindrically wrapped text making it appear flatter. Twisting the cap adjusts the angle of presentation for when the user is not looking straight down onto the display. A touch sensitive overlay allows the user to select menu items or hypertext links as the display "rolls over" that line of text. The display also works without a flat surface (although not as naturally) by turning it while holding it in the air.

<CIT> discloses an electronic device including a printed circuit board and a casing. The printed circuit board is for storing an image. The casing secures the printed circuit board and displays the image all through its outer surface. The casing includes a touch panel and a display panel. The touch panel is transparent and is for sensing touch of users and generating control signals. The display panel is under the touch panel and is for displaying the image according to the control signals.

<CIT> discloses a method and a device for presentation of information on a display. The method controls the information to be presented on the display, and comprises obtaining information to be presented on the display, presenting information on the display, and detecting a rotational motion around an axis of rotation of an information presentation device, providing the presented information on the display in dependence of the detected rotational motion. The information may also be presented in dependence on the position of an I/O site at which information may be shifted in and shifted out of the information presentation unit.

Therefore, there exists a need for an improved form factor for portable electronic devices which allows functionality to extend to more than one surface of the device.

This paper describes various embodiments that relate to a portable electronic device with a wraparound display as defined in claim <NUM>.

The described embodiments and the advantages thereof may best be understood by reference to the following description taken in conjunction with the accompanying drawings.

The presently described embodiments relate generally to media devices. More particularly, a media device having a wrap-around display enclosed within a transparent enclosure is described.

In the following description, numerous specific details are set forth to provide a thorough understanding of the presently described embodiments. It will be apparent, however, to one skilled in the art that the presently described embodiments may be practiced without some or all of these specific details. In other instances, well known process steps have not been described in detail in order to avoid unnecessarily obscuring the presently described embodiments.

The majority of portable electronic device manufacturers utilize a common form factor consisting generally of a flat planar form factor with a single surface dedicated mainly for use as a display surface, while the other surfaces remain largely unused, save for the occasional button or switch. The conventional form factor has been used in devices such as smart phones, tablet devices, and electronic book readers. Although this form factor lends itself to electronic devices that are aesthetically pleasing and easy to handle, the requirement for a planar display and associated circuitry inherently limits the amount of surface area to single surface. More specifically, the size of the user interface is generally limited to a portion of the device that takes up less than half of the overall device surface area.

In one embodiment, utilizing a flexible display can provide additional viewing area without increasing either the size or shape of the electronic device. For example, a flexible display can be folded in such a way as to form a continuous loop such that images (still or video) can be presented in a wrap-around manner in which the images appear to be presented in a continuous loop. The flexible display can be folded into a tightly wound configuration and placed within an enclosure at least a portion of which is transparent. In some cases, the enclosure can be formed of glass at least a portion of which is made opaque (at least translucent) by the addition of ink or other masking material. In other cases, however, the entire enclosure can be fully transparent in which case the folded flexible display can unwind when placed within the glass enclosure. Once fully unwound, the flexible display can present images at any portion of the glass enclosure.

These and other embodiments are discussed below with reference to Figs. However, those skilled in the art will readily appreciate that the detailed description given herein with respect to these figures is for explanatory purposes only and should not be construed as limiting.

<FIG> shows housing <NUM> alongside representative flexible display assembly <NUM>. Housing <NUM> can take many forms. For example, housing <NUM> can be multi-part in which a portion is metallic in nature (such as aluminum) whereas another portion can be formed of optically transparent material such as glass. For the remainder of this discussion, however, housing <NUM> is considered to be fully formed of transparent (or at least semi-transparent) material such as glass. In this way and without loss of generality, transparent housing <NUM> may be made of any transparent material such as for example glass, or plastic. The material selected generally depends on many factors including, but not limited to, strength (tensile), density (lightweight), strength to weight ratio, Young's modulus, corrosion resistance, formability, finishing, recyclability, tooling costs, design flexibility, manufacturing costs, manufacturing throughput, reproducibility, and the like. The material selected may also depend on electrical conductivity, thermal conductivity, radio wave and optical transparency, combustibility, toxicity, and the like. The material selected may also depend on aesthetics, including color, surface finish, and weight.

In one particular embodiment, housing <NUM> can be formed from a glass tube. The glass tube may be formed from an extrusion or extrusion-like process. Some of the reasons for using glass over other materials are that glass is strong, stiff, and radio transparent and therefore a suitable material for an enclosure of an electronic device capable of wireless communications and presenting visual content at any surface thereof. The radio transparency is especially important for wireless hand held devices that include antennas internal to the enclosure. Radio transparency allows the wireless signals to pass through the enclosure and, in some cases, even enhances these transmissions. It will be understood that, although a glass enclosure is capable of wireless communications, the embodiments described herein need not be capable of wireless communication.

Using glass for the fabrication of housing <NUM> can also provide the portable electronic device with a unique, aesthetically pleasing appearance. To further provide an aesthetically pleasing appearance, the glass can also be coated with an oleophobic coating to reduce finger prints and smudging on the glass. The glass can also be coated with an anti-reflective coating to reduce glare. It will be understood that chemically strengthened glass can also be scratch resistant. The glass can also be color tinted in a wide variety of colors and can also have a variety of surface finishes including smooth and rough. For example, the glass can be polished to create a smooth (gloss) finish, or a blasting operation can performed to create a rough or textured (matte) finish. Portions of the glass can also be textured so that the textured surface will disperse light and can be used as light indicator. As discussed in more detail below, the glass material can be formed so that the enclosure can have a seamless or substantially seamless appearance. The seamless enclosure, in addition to being aesthetically pleasing, can provide the added benefit of less contamination and moisture intrusion into the interior of the device.

In some cases, even though housing <NUM> is fully fabricated from a transparent material such as glass, it may be desirable to obscure at least portions of housing <NUM> from the view of an end-user. For example, internal components may be visible through housing <NUM> detracting from the overall look and feel of the electronic product. Therefore, in some cases, portions of housing <NUM> can be optically obscured. The glass enclosure around the display can be made opaque so the operational components of the device are not visible. One method of rendering portions of housing <NUM> opaque is to use an ink printing process in those areas where opacity is desired to create a mask. For example, appropriately placed ink can render a masked region that is optically opaque. For example, an area surrounding a display can be masked to provide an emphasis and accentuate visual content presented by the display. It should be noted that in alternative embodiments, portions of housing <NUM> can be painted or screen printed. Other techniques for achieving opacity in certain areas, such as using a two-layer clad glass.

It should be noted that glass has been used in a wide variety of products, including electronic devices, such as watches, and phones. In these cases, however, the glass materials have not been used as structural components. In most of these cases, the glass materials have been used as cosmetic accoutrements or solely as a screen for a display. It is believed that, up until now, glass materials have never been used as a structural element providing substantially all of the structural frames, walls and main body of a consumer electronic device, and more particularly an enclosure of a portable electronic device, such as a media player or mobile phone.

The glass enclosure also allows a display screen to be positioned underneath and protected by the glass enclosure. The glass material of the enclosure is capable of capacitive sensing so that a touch screen can be used through the glass enclosure. The cross-sectional shape, including both the outer and inner shapes of housing <NUM> may be widely varied. They may be formed from simple or intricate shapes, whether rectilinear and/or curvilinear. For hand held devices, it is typically preferred to use a shape that better fits the hand (e.g., form fits). By way of example, a rectangle with curved edges or an oval or pill shaped cross section having curvature that more easily receives the hand may be used. It should be noted that the inner cross-sectional shape may be the same or different from the external cross sectional shape of the main body. For example, it may be desirable to have a pill shaped external and a rectangular shaped interior, etc. In addition, although not a requirement, the front surface of the housing <NUM> may be substantially planar for placement of a display or a user interface that can be incorporated into housing <NUM> separate from the display.

In this particular embodiment, transparent housing <NUM> can take the form of an elliptical extrusion. The flexible display assembly <NUM> can be an active matrix light emitting diode (AMOLED) display manufactured on a polyimide substrate. In addition to being flexible, AMOLED displays allow pixels to be lit up individually, as opposed to conventional LCD technology in which the entire screen is in either an on or an off state. Consequently, an AMOLED screen can display small amounts of text at extremely conservative power levels. This type of display screen typically has an active display area <NUM> which has supporting circuitry that surrounds at least some of the edges. For example, flexible display assembly <NUM> has active display area <NUM> surrounded on three of four edges with supporting circuitry that generally includes display driver chip <NUM> and sensor flex connector <NUM> on side <NUM>-<NUM> and additional circuitry and associated connectors on sides <NUM>-<NUM> and <NUM>-<NUM>. It should be noted that with suitable design considerations, remaining side <NUM>-<NUM> can be configured in such a way that only a small unused border sufficiently narrow to be effectively unnoticeable can be provided.

One of the advantages of using a polyimide substrate is that the AMOLED display screen can be heated that allows the AMOLED display screen to be configured into any number of shapes. Moreover, once the heat is removed, the AMOLED display will then "remember" the original shape even if temporarily rolled up or flattened out. In this way, by heating AMOLED display assembly <NUM> while configured in a shape in accordance with transparent housing <NUM> AMOLED display assembly <NUM> easily conforms to the shape of transparent housing <NUM>. For example, <FIG> shows a preheated AMOLED display assembly <NUM> temporarily rolled up as it is placed into lumen <NUM> of transparent housing <NUM>. Once inside transparent housing <NUM>, AMOLED display assembly <NUM> can be released resulting in AMOLED display assembly <NUM> "unwinding" to assume the shape of lumen <NUM> of transparent housing <NUM> in such a way that AMOLED display assembly <NUM> is arrayed against interior surface <NUM> of transparent housing <NUM>. In order to secure unwound display assembly <NUM> to transparent housing <NUM>, a laminating process can be performed subsequent to the unwinding of AMOLED display assembly <NUM> to interior surface <NUM> of transparent housing <NUM>. For example, an adhesive can be placed between the interior surface <NUM> and AMOLED display assembly <NUM> at locations not viewable by an end-user. It should be noted that edges <NUM>-<NUM> and <NUM>-<NUM> of AMOLED display assembly <NUM> are now positioned at the top and bottom of transparent housing <NUM>, leaving only edge <NUM>-<NUM> with the connector <NUM> and display driver chip <NUM> to be hidden from view. Once AMOLED display assembly <NUM> is securely attached to the inside surface of transparent housing <NUM>, the other electrical components can be inserted.

<FIG> shows a perspective view of portable electronic device <NUM> as internal components of portable electronic device <NUM> are being inserted into transparent housing <NUM>. An internal frame for portable electronic device <NUM>, which supports the electrical components, can include two support columns <NUM>, which are secured by end cap <NUM> and end cap <NUM> by way of end cap receivers <NUM>. End cap <NUM> and end cap <NUM> can be made of any suitable rigid material, such as plastic, aluminum, or even steel. Printed circuit board (PCB) <NUM> can be supported by a rigid framework (not shown) connecting support columns <NUM>. PCB <NUM> allows the other supporting electrical components such as battery <NUM> and processor <NUM> to drive the operations of portable electronic device <NUM>. End cap <NUM> and end cap <NUM> also include electrical connectors <NUM> so that components housed within them, such as data connector <NUM>, and RF antennae (not shown) can cooperate and interact with electrical components disposed on PCB <NUM>. Once end caps <NUM> and <NUM> are secured on either end of transparent housing <NUM> all the electrical components are enclosed within transparent housing <NUM>. Support columns <NUM> can be mechanically fastened to end caps <NUM> and <NUM> so that the end caps stay firmly in place. In one embodiment, fasteners such as small screws (not shown) can be embedded in at least one of the end caps, allowing for the end cap to be released from support columns <NUM> when the screws are loosened. This configuration would allow the end caps to be easily removed for maintenance purposes. In another embodiment the removable end cap could also allow users to add end caps with additional functionality. For example, an end cap could be installed that would allow two devices to be connected together and act as one system. This could be as simple as having an end cap with a male data connector designed to attach to data connector <NUM> of another similar portable electronic device <NUM>. In yet another embodiment an alternate end cap could have an improved camera or a different set of wireless antennae.

<FIG> shows a bottom view of portable electronic device <NUM> in accordance with the described embodiments. In this view structural support elements <NUM> are shown attached to support columns <NUM>. Support elements <NUM> can help provide structural support to transparent housing <NUM>. Structural support elements <NUM> can be deployed after the support columns and electrical components are all connected and in place, thereby providing further support for all the components housed within portable electronic device <NUM>. In cases where transparent housing <NUM> is made of a material which requires reinforcement additional supports may be attached to the inner framework so that portable electronic device is truly robust. Also shown in this drawing is the connection between AMOLED display assembly <NUM> and PCB <NUM>. The two components are attached by sensor flex <NUM>, which allows data to pass between the two components. This diagram also shows how the two ends of AMOLED display assembly <NUM> join together at lap joint <NUM>. The portion of AMOLED display assembly <NUM> that extends past the lap joint is the final portion of the border of AMOLED display assembly <NUM> that is hidden to provide one continuous display that extends around the entire device. If lap joint <NUM> cannot be made to look seamless it may be desirable to cover lap joint <NUM> with a thin line of dark paint on the interior of transparent housing <NUM>. In this the lap joint can be positioned on one edge of the device to further conceal any apparent discontinuity. In situations where a dark paint concealer is used a butt joint could also be used as the cosmetic appearance of the device is less crucial. It should also be noted that although the lap joint is shown on a bottom portion of portable electronic device <NUM> it can be positioned anywhere along the inside of the device.

<FIG> shows a perspective view of portable electronic device <NUM> in operation. Notice how the wrap around display substantially increases the available display area that can be used for display of icons, data, images, video and such. For example, as shown in <FIG>, up to five application icons can be presented that span the width of display <NUM>. Microphones <NUM> and speaker <NUM> allow portable electronic device <NUM> to act as a portable personal communication device, such as a smart phone. Furthermore, virtualization of the physical buttons allows for expanded functionality. For example, volume control <NUM> can be located at roughly the same position it would be if it were configured as a physical button; however, in this configuration the actual volume setting can be seen at any time (indicated by the circle between the + and - indicators). Additionally, by holding a finger over the volume indicator an action could be triggered expanding the volume control over the entire left side of the device. This would allow a user to make fine adjustments to the volume of portable electronic device <NUM>. Once the adjustment control is released the control can return to its original size. A hold switch is another popular function that is often assigned to a physical button. Instead of the hold button a multi touch gesture along one of the sides could instead act as a method of locking and unlocking the hold function. Additional features that can be well suited for portable electronic device <NUM> include various image capture devices along the lines of cameras <NUM>. It should be noted that since portable electronic device <NUM> can present visual content in any direction it is important for the portable electronic device <NUM> to be able to determine a current location of the end-user. In this way, any of cameras <NUM> can periodically capture an image and using basic facial recognition software, one or more of cameras <NUM> can be used to track the movement the end user's face in the space around it and as such be able to determine a general direction of the end-user and the field of vision of the end user and adjust the presentation of visual content by display <NUM> accordingly.

<FIG> illustrate a variety of additional representative form factors in which the described embodiments can be manufactured. For example, <FIG> shows embodiment <NUM> that includes rectangular shaped housing <NUM>. It should be noted that the rounded corners of <FIG> permit an end-user's finger to move objects around the corners of the device. In yet another embodiment, transparent housing <NUM> can be strengthened by the addition of external frame <NUM>. External frame <NUM> can provide support for corners <NUM> and provide additional support for portable electronic device <NUM>. <FIG> shows embodiment <NUM> that includes a cylindrically shaped housing <NUM>. In this case orientation sensors such as an accelerometer and facial tracking can be used in maintaining user interface correctly oriented in the visual field of the end user. In <FIG> housing <NUM> can have a tapered shape with a variably sized cross section. In this embodiment, AMOLED display assembly <NUM> can be manufactured in a non-rectangular shape, allowing the display to conform to the internal surface of housing <NUM>.

<FIG> shows a flowchart detailing process <NUM> in accordance with the described embodiments. Process <NUM> can be used to assemble a portable communication device having a wrap-around flexible display enclosed within a transparent housing. The portable communication device can further include wireless communication functionality provide an end-user with the option of configuring the portable communication device as a personal communication device along the lines of a smart phone. In any case, process <NUM> begins at <NUM> by receiving an enclosure at least a portion of which is transparent. In one embodiment, the enclosure can be fully formed of a transparent material such as glass that can also be used as structural support for the portable communication device. In another embodiment, the enclosure can be a multi-part housing where one portion is formed of structural material such as metal such as aluminum whereas another portion can be formed of transparent material such as glass integrally formed with the metallic housing.

At <NUM>, a flexible display is shaped in such a way as to be inserted into a lumen of the enclosure. For example, when the lumen of the enclosure is circular or circular-like in nature, the flexible display can be wound, or rolled, up into a shape consistent with the shape of the lumen. By rolling up the flexible display into, for example, a cylinder, the rolled up flexible display can be easily inserted into the lumen of the enclosure. Once the rolled up flexible display is within the lumen of the enclosure, the flexible display unwinds, or unrolls, at <NUM> and conforms to the shape of the lumen and thereby provides a display surface at an interior surface. Next at <NUM>, the enclosure is sealed at either or both ends. For example, end caps can be attached to the enclosure to complete the assembly of the portable communication device.

In one embodiment as shown in <FIG>, a second flexible display can be inserted subsequent (or concurrent with) the insertion of the first flexible display. More particularly, <FIG> shows multiple display portable communication device <NUM> in accordance with the described embodiments. Multiple display portable communication device <NUM> can include first flexible display <NUM> and second flexible display <NUM>. In one embodiment, first flexible display <NUM> and second flexible display <NUM> can present visual content independent of each other. In alternative embodiments, first flexible display <NUM> and second flexible display <NUM> can cooperatively present visual content. For example, visual content can be presented by first flexible display <NUM> out of temporal phase with the visual content presented by second flexible display <NUM>. In this way, an illusion of depth perception can be presented mimicking a 3D experience. In one embodiment, first flexible display <NUM> can be partially transparent such that visual content from second flexible display <NUM> can be viewed concurrent with visual content presented by first flexible display <NUM>.

<FIG> shows a bottom view of multi-display portable electronic device <NUM> in accordance with the described embodiments.

<FIG> is a block diagram of an electronic device <NUM> suitable for use with the described embodiments. The electronic device <NUM> illustrates circuitry of a representative computing device. The electronic device <NUM> includes a processor <NUM> that pertains to a microprocessor or controller for controlling the overall operation of the electronic device <NUM>. The electronic device <NUM> stores media data pertaining to media items in a file system <NUM> and a cache <NUM>. The file system <NUM> is, typically, a storage disk or a plurality of disks. The file system <NUM> typically provides high capacity storage capability for the electronic device <NUM>. However, since the access time to the file system <NUM> is relatively slow, the electronic device <NUM> can also include a cache <NUM>. The cache <NUM> is, for example, Random-Access Memory (RAM) provided by semiconductor memory. The relative access time to the cache <NUM> is substantially shorter than for the file system <NUM>. However, the cache <NUM> does not have the large storage capacity of the file system <NUM>. Further, the file system <NUM>, when active, consumes more power than does the cache <NUM>. The power consumption is often a concern when the electronic device <NUM> is a portable media device that is powered by a battery <NUM>. The electronic device <NUM> can also include a RAM <NUM> and a Read-Only Memory (ROM) <NUM>. The ROM <NUM> can store programs, utilities or processes to be executed in a non-volatile manner. The RAM <NUM> provides volatile data storage, such as for the cache <NUM>.

The electronic device <NUM> also includes a user input device <NUM> that allows a user of the electronic device <NUM> to interact with the electronic device <NUM>. For example, the user input device <NUM> can take a variety of forms, such as a button, keypad, dial, touch screen, audio input interface, visual/image capture input interface, input in the form of sensor data, etc. Still further, the electronic device <NUM> includes a display <NUM> (screen display) that can be controlled by the processor <NUM> to display information to the user. A data bus <NUM> can facilitate data transfer between at least the file system <NUM>, the cache <NUM>, the processor <NUM>, and the CODEC <NUM>.

In one embodiment, the electronic device <NUM> serves to store a plurality of media items (e.g., songs, podcasts, etc.) in the file system <NUM>. When a user desires to have the electronic device play a particular media item, a list of available media items is displayed on the display <NUM>. Then, using the user input device <NUM>, a user can select one of the available media items. The processor <NUM>, upon receiving a selection of a particular media item, supplies the media data (e.g., audio file) for the particular media item to a coder/decoder (CODEC) <NUM>. The CODEC <NUM> then produces analog output signals for a speaker <NUM>. The speaker <NUM> can be a speaker internal to the electronic device <NUM> or external to the electronic device <NUM>. For example, headphones or earphones that connect to the electronic device <NUM> would be considered an external speaker.

The electronic device <NUM> also includes a network/bus interface <NUM> that couples to a data link <NUM>. The data link <NUM> allows the electronic device <NUM> to couple to a host computer or to accessory devices. The data link <NUM> can be provided over a wired connection or a wireless connection. In the case of a wireless connection, the network/bus interface <NUM> can include a wireless transceiver. The media items (media assets) can pertain to one or more different types of media content. In one embodiment, the media items are audio tracks (e.g., songs, audio books, and podcasts). In another embodiment, the media items are images (e.g., photos). However, in other embodiments, the media items can be any combination of audio, graphical or visual content. Sensor <NUM> can take the form of circuitry for detecting any number of stimuli. For example, sensor <NUM> can include a Hall Effect sensor responsive to external magnetic field, an audio sensor, a light sensor such as a photometer, and so on.

The foregoing description, for purposes of explanation, used specific nomenclature to provide a thorough understanding of the described embodiments. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the described embodiments. Thus, the foregoing descriptions of the specific embodiments described herein are presented for purposes of illustration and description. They are not target to be exhaustive or to limit the embodiments to the precise forms disclosed. It will be apparent to one of ordinary skill in the art that many modifications and variations are possible in view of the above teachings.

The various aspects, embodiments, implementations or features of the described embodiments can be used separately or in any combination. Various aspects of the described embodiments can be implemented by software, hardware or a combination of hardware and software. The described embodiments can also be embodied as computer readable code on a computer readable medium for controlling manufacturing operations or as computer readable code on a computer readable medium for controlling a manufacturing line. The computer readable medium is any data storage device that can store data that can thereafter be read by a computer system. Examples of the computer readable medium include read-only memory, random-access memory, CD-ROMs, DVDs, magnetic tape, and optical data storage devices. The computer readable medium can also be distributed over network-coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

Claim 1:
A portable electronic device (<NUM>) having front and rear surfaces, comprising:
a transparent enclosure (<NUM>) that forms at least part of the front and rear surfaces;
a circuit board (<NUM>);
a display assembly (<NUM>) configured to provide visual content, wherein the display assembly (<NUM>) is positioned in the transparent enclosure (<NUM>) and extends around the circuit board (<NUM>), wherein the display assembly (<NUM>) has first and second ends and a border at the second end, wherein the second end is joined to the first end at a joint (<NUM>), and wherein at least part of the first end overlaps the second end and hides a final portion of the border of the display assembly (<NUM>) from view such that images are presented in a continuous loop that wraps around the device (<NUM>); and
a camera configured to capture an image of a user, wherein the image is processed using facial recognition software to determine an orientation of a user relative to a portion of the display assembly (<NUM>), and wherein the presentation of visual content is adjusted based on the orientation of the user relative to the portion of the display assembly (<NUM>).