BACKGROUNDWeb-based social networks, email and other on-line platforms enable users to share and exchange digital content, such as messages, images, video, audio, etc. With the proliferation of mobile computing devices, the volume of such on-line content that is created and shared continues to increase.
To receive updates or other content from friends and others, a user may fetch or otherwise access a computing device and open a corresponding application to view such content. Given the increasing volume of on-line content, a user may sift through numerous notifications, updates, and other unrelated content to find the user's desired content, such as updates from a particular friend. In some cases, finding and activating a device, opening an application, and sorting through numerous items to find desired content may impose undesirable delays in the user receiving the desired content.
Some technologies enable users to experience a fully or partially virtual world. For example, some virtual reality head-mounted display (HMD) devices may display a fully-immersive, entirely virtual environment with no view of the real world. Other, augmented reality HMD devices may include a partially transparent display that blends a user's view of the real world with displayed virtual objects and other content. In some cases, a user may desire to share selected on-line content with another user who is using a virtual reality or augmented reality device. However, managing the availability and presentation of such content can prove challenging.
SUMMARYTo address these issues, a computing device and method are provided for generating a virtual place-located anchor at which holograms may be viewed. The computing device may comprise an anchor program executed by a processor of the computing device, wherein the anchor program is configured to, in a creating phase: receive an instruction to generate a virtual place-located anchor at a virtual location that is world-locked; receive a plurality of data items from a target data source at which a first user has an account; link a subset of the plurality of data items to the virtual place-located anchor; and receive a permission via user input from the first user, the permission specifying a condition under which a second user is authorized to view one or more holograms of the subset of data items.
The anchor program also may be configured to, in a viewing phase: transmit first display data to a first display device comprising an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display, the first display data causing the first display device to display the one or more holograms of the subset of data items to the first user at the virtual place-located anchor at the virtual location; determine if the condition is satisfied; and if the condition is satisfied, transmit second display data to cause a second display device to display the one or more holograms of the subset of data items to the second user at the virtual place-located anchor at the virtual location.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 shows a head-mounted display device according to an example of the present description.
FIG. 2 is a schematic view of a computing device for generating a virtual place-located anchor according to an example of the present disclosure.
FIG. 3 shows users wearing head-mounted display devices ofFIG. 1 in a first room according to an example of the present description.
FIG. 4 shows a user fromFIG. 3 wearing the head-mounted display device ofFIG. 1 in a second room according to an example of the present description.
FIG. 5 shows a user fromFIG. 3 wearing the head-mounted display device ofFIG. 1 in a third room according to an example of the present description.
FIG. 6 shows a smartphone displaying a user interface for the social network according to an example of the present disclosure.
FIGS. 7A, 7B and 7C are a flow chart of a method of generating a virtual place-located anchor according to an example of the present description.
FIG. 8 shows a computing system according to an embodiment of the present description.
DETAILED DESCRIPTIONThe present descriptions relate to generating a virtual place-located anchor at which holograms and other virtual content may be viewed. As described in more detail below, in some examples display data may be transmitted to a display device to cause the device to display one or more holograms of a subset of data items at the virtual place-located anchor. In some examples, the display device may comprise an HMD device, such as an augmented reality display device that includes an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display. In other examples, the HMD device may comprise a fully-immersive virtual reality display device. In other examples, the display device may comprise a tablet computer, smartphone, or other mobile computing device capable of visually augmenting a user's view of a real world three dimensional environment via the display.
FIG. 1 illustrates anHMD device10 according to an example of the present disclosure. In this example, the illustratedHMD device10 takes the form of wearable glasses or goggles, but it will be appreciated that other forms are possible. TheHMD device10 may include an at least partially see-throughstereoscopic display12 that may be configured to visually augment a view of a real world three dimensional environment by the user through the display.
For example, theHMD device10 may include animage production system22 that is configured to display virtual objects such as holograms to the user with the at least partially see-throughdisplay12. The holograms may be visually superimposed onto the physical environment so as to be perceived at various depths and locations. TheHMD device10 may use stereoscopy to visually place a virtual object at a desired depth by displaying separate images of the virtual object to both of the user's eyes.
To achieve the perception of depth, theimage production system22 of theHMD device10 may render the two images of the virtual object at a rendering focal plane of theHMD device10, such that there is a binocular disparity between the relative positions of the virtual object in the two images. For example, such binocular disparity may be a horizontal disparity where the relative positions of the virtual object in the two images are separated by a distance in the x axis direction. In this embodiment, the x axis may be defined as the axis extending horizontally to the left and the right relative to the user, the y axis extending upward and downward vertically relative to the user, and the z axis extending forward and backward relative to the user, and orthogonally to the x and y axes.
The horizontal disparity between the relative positions of the virtual object in the two images will cause the user to perceive that the virtual object is located at a certain depth within the viewed physical environment due to stereopsis. Using this stereoscopy technique, theHMD device10 may control the displayed images of the virtual objects, such that the user may perceive that the virtual objects exist at a desired depth and location in the viewed real world three dimensional environment.
In other examples, the at least partially see-throughdisplay12 andimage production system22 may utilize other image display technologies and configurations. For example, the at least partially see-throughdisplay12 may be configured to enable a wearer of theHMD device10 to view a physical, real-world object in the physical environment through one or more partially transparent pixels that are displaying a virtual object representation. In some examples thedisplay12 may include image-producing elements located within lenses (such as, for example, a see-through Organic Light-Emitting Diode (OLED) display). As another example, thedisplay12 may include a light modulator on an edge of the lenses. In this example, the lenses may serve as a light guide for delivering light from the light modulator to the eyes of a wearer. Such a light guide may enable a wearer to perceive a 3D holographic image located within the physical environment that the wearer is viewing, while also allowing the wearer to view physical objects in the physical environment, thus creating an augmented reality environment.
In other examples, the at least partially see-through display may comprise one or more optical redirection elements or techniques, such as a digital single lens reflex camera or other image capture device. In other examples, thedisplay12 may comprise a non-see-through display that provides an immersive, virtual reality experience in which virtual content such as holograms and/or two-dimensional images are displayed to a user.
TheHMD device10 includes anoptical sensor system14 that may include one or more optical sensors. In one example, theoptical sensor system14 may include an outward facingoptical sensor16 that may be configured to detect the real world environment from a similar vantage point (e.g., line of sight) as observed by the user through the see-throughdisplay12. Theoptical sensor system14 may include a variety of additional sensors, such as a depth camera and an RGB camera, which may be a high definition camera or have another resolution.
TheHMD device10 may further include aposition sensor system18 that may include one or more position sensors such as accelerometer(s), gyroscope(s), magnetometer(s), global positioning system(s), multilateration tracker(s), and/or other sensors that output position sensor information useable as a position, orientation, and/or movement of the relevant sensor.
Optical sensor information received from theoptical sensor system14 and/or position sensor information received fromposition sensor system18 may be used to assess a position and orientation of the vantage point of the see-throughdisplay12 relative to other environmental objects. In some embodiments, the position and orientation of the vantage point may be characterized with six degrees of freedom (e.g., world-space X, Y, Z, pitch, roll, yaw). The vantage point may be characterized globally or independent of the real world background. The position and/or orientation may be determined with an on-board computing system (e.g., on-board computing system20) and/or an off-board computing system.
In some examples, theHMD device10 may receive and utilize data from sensors that are not located on the device. For example, theHMD device10 may receive optical sensor information from one or more external cameras that are in the same room as the user. In some examples, theHMD device10 may receive sensor data from another HMD device in the area. In some examples, theHMD device10 may receive position information from a tracking sensor on a movable object.
Furthermore, the optical sensor information and the position sensor information may be used by a computing system to perform analysis of the real world three dimensional environment, such as depth analysis, surface reconstruction, environmental color and lighting analysis, or other suitable operations. In particular, the optical and positional sensor information may be used to create a virtual model of the real world three dimensional environment. In some examples, the virtual model may comprise a three dimensional coordinate space that is overlaid upon the real world three dimensional environment. In some examples, such sensor information may be provided to another computing device, such as a server, that creates the virtual model of the real world three dimensional environment.
In some examples, the position and orientation of the vantage point may be characterized relative to this virtual space. Moreover, the virtual model may be used to determine positions of holograms and other virtual objects in the virtual space, and to add additional virtual objects to be displayed to the user at a desired depth and location within the virtual world.
TheHMD device10 may also include a microphone system that includes one or more microphones, such asmicrophone58, that capture audio data. In other examples, audio may be presented to the wearer via one or more speakers, such asspeaker60 on theHMD device10.
FIG. 2 is a schematic illustration of acomputing device200 interacting with display devices and target data sources according to an embodiment of the present disclosure. As explained in more detail below, thecomputing device200 may be used to generate a virtual place-located anchor at a virtual location that is world-locked.Computing device200 may take the form of a server, networking computer, gaming console, mobile communication device, desktop computer, laptop computer, tablet computer, set-top box (e.g. cable television box, satellite television box), or any other type of suitable computing device. In some examples,computing device200 may comprise an embedded system within a larger electronic or mechanical device or system. Additional details regarding the components and computing aspects of thecomputing device200 are described in more detail below with respect toFIG. 8.
Thecomputing device200 may include ananchor program214 that may be stored inmass storage218 of the computing device. Theanchor program214 may be loaded intomemory220 and executed by aprocessor260 of thecomputing device200 to perform one or more of the methods and processes for generating a virtual place-located anchor, as described in more detail below.
Thecomputing device200 may be communicatively coupled to one or more other devices via a wired connection or a wireless connection to a network. In some examples, the network may take the form of a local area network (LAN), wide area network (WAN), wired network, wireless network, personal area network, or a combination thereof, and may include the Internet. In the example ofFIG. 2,computing device200 is communicatively coupled to afirst display device30, asecond display device34, a firsttarget data source38 and a secondtarget data source42 via one or more networks. In other examples thecomputing device200 may be operatively connected with fewer or additional devices.
With reference also toFIGS. 3-6, example use cases illustrating aspects of the present disclosure will now be presented. As schematically shown inFIG. 3, afirst user302 may be standing in aliving room306 and may wearfirst display device30, which in this example may take the form ofHMD device10 shown inFIG. 1. As noted above, first display device30 (HMD device10) may comprise an at least partially see-through display configured to visually augment the view offirst user302 through the display of the real world three dimensional environment ofliving room306. Thefirst display device30 may generate a virtual model of theliving room306 using a three dimensional coordinate space overlaid upon the real world living room. In the example ofFIG. 3, such three dimensional coordinate space is indicated by the x-y-z axes. As described in more detail below, thefirst display device30 also may include program logic configured to identify physical objects within theliving room306.
With reference also toFIG. 2,first user302 may have an account at the firsttarget data source38. In some examples the firsttarget data source38 may comprise a social network. As used herein, “social network” may include a variety of on-line platforms for building social relations among people who share interests, activities, backgrounds or other connections. Examples of social networks include, but are not limited to, on-line content sharing services, photo and/or video sharing services, recommendation services, instant messaging services, email services, combinations of the foregoing, and any other on-line platform that enables content sharing and/or communication among users. With reference toFIG. 3, in this example the firsttarget data source38 may be a Social Network A316.
In the example ofFIG. 3,first user302 may use thefirst display device30 to capture an image of theart piece312. Thefirst user302 may desire to share the image with others viasocial network A316. Accordingly, thefirst user302 may send the image to thesocial network A316 in a posting320 to the network.
Other users of the social network A may post comments to the posting320 fromfirst user302 on the network. In one example and with reference again toFIG. 2, one or more users may use one or morethird party devices46 to postcomments50 to theposting320. For example, Friend A offirst user302 may use a third party device to post acomment50 to the first user'sposting320. In some examples a comment may comprise text, an image, a video, a hashtag, and/or any combinations of the foregoing.
Thefirst user302 may desire to view thecomment50 and any other comments posted tosocial network A316 regarding the first user'sposting320. Accordingly, and in one potential advantage of the present disclosure,first user302 may instruct theFirst display device30 to generate a virtual place-located anchor at a world-locked virtual location. In different examples, such instruction may comprise hand, head or other bodily gesture input, voice input, eye-tracking input, or other suitable user input. For example,first user302 may speak an instruction to “Put an anchor at the art piece for comments to the picture I just posted to Social Network A.” As described in more detail below, one or more holograms of thecomment50 and other comments to the first user'sposting320 may be displayed byFirst display device30 at theart piece312.
With reference also toFIG. 2, in some examples and in response to the instruction from thefirst user302, thefirst display device30 may transmit tocomputing device200 aninstruction54 to generate a virtual place-locatedanchor56 at a virtual location that is world-locked.Computing device200 may be communicatively coupled to the firsttarget data source38, and may receive a plurality ofdata items62 from the target data source. In examples where the firsttarget data source38 comprisessocial network A316, thedata items62 may comprise postings, updates, and other items provided to the social network A by users, and may include items and other content generated by the social network.
In response to theinstruction54 fromfirst user302 viafirst display device30, theanchor program214 may link asubset64 of the plurality ofdata items62 from the firsttarget data source38 to the virtual place-locatedanchor56. In the present example, theanchor program214 may filter thedata items62 to identify and select comments to the first user's posting320 of the image of theart piece312. Theanchor program214 may then transmitfirst display data66 to thefirst display device30 that causes the device to display one or more holograms of this subset of data items to thefirst user302.
In the example ofFIG. 3, thefirst display device30 may display to thefirst user302 holograms of comments to the first user's posting320 of the image of theart piece312. For example, ahologram330A of the comment “Nice!” from Friend A to the first user'sposting320 may be displayed at the world-locked virtual place-located anchor at the virtual location. One or more other holograms of comments to the first user's posting320 from other friends and/or users of social network A, such asholograms330B and330C, may also be displayed.
These holograms may be displayed by thefirst display device30 at the world-locked virtual place-locatedanchor56. In some examples, the virtual location of the virtual place-locatedanchor56 may be world-locked to a position that is fixed in the three dimensional coordinate space overlaid upon the real world three dimensional environment. In the example ofFIG. 3, such a fixed position may be established as an area or a volume of space indicated at334 that is adjacent to theart piece312 which is the subject of the first user'sposting320.
As noted above, thefirst user302 may designate the virtual location of the virtual place-located anchor via user input. In some examples, thefirst display device30 may programmatically generate an instruction for a virtual place-located anchor at a world-locked virtual location. For example, in response to the first user's posting320 of the image of theart piece312, thefirst display device30 may use sensor data to programmatically identify theart piece312 inliving room306 as a subject of the posting. In response to identifying theart piece312, thefirst display device30 may programmatically transmit an instruction tocomputing device200 to generate a virtual place-located anchor at a world-locked virtual location corresponding to theart piece312.
In other examples, a fixed position may be defined as another location in theliving room306. For example, thefirst user302 may provide user input that establishes a world-locked fixed position for the virtual place-locatedanchor56 as the space above thebookcase340. In other examples, such a fixed position may be defined as a room, building, inside a vehicle, at an outdoor space or location, or any location that may be mapped to a three dimensional coordinate space.
In some examples, the virtual location of the virtual place-locatedanchor56 may be world-locked to a position relative to an object in the real world three dimensional environment. With reference toFIG. 3, in one example the virtual place-located anchor may be world-locked to a position relative to theart piece312 that is the subject of the first user'sposting320.
In some examples, where the virtual location of the virtual place-locatedanchor56 is world-locked to a position relative to an object, the virtual place-located anchor may travel with the object. For example and with reference toFIG. 4, theart piece312 may be moved from theliving room306 to thekitchen400. In this example, when theart piece312 is at an initial real world location in theliving room306, thefirst display device30 may capture one or more images of the art piece as well as other aspects of the real world location.
After theart piece312 has been moved to the table404 inkitchen400, thefirst user302 may enter the kitchen. Usingsensor data68 collected from sensors of thefirst display device30, theanchor program214 may identify theart piece312 and may identify thekitchen400 as a subsequent real world location that is different from the initial real world location of theliving room306. In response to identifying theart piece312 in thekitchen400, thecomputing device200 may transmit display data to thefirst display device30 that causes the device to display theholograms330A,330B and330C to thefirst user302 at the virtual place-located anchor at the virtual location world-locked to the position relative to theart piece312 in thekitchen400.
In other examples, a virtual place-located anchor may be world-locked to a position relative to an object that is not the subject of a user's posting. For example and with reference toFIG. 3, the virtual place-locatedanchor56 the first user'sposting320 may be world-locked to a position relative to thecoat rack350. In this example, thefirst user302 may provide via user input an instruction to “Put an anchor at the coat rack for comments to the picture I just posted to Social Network A.” One or more holograms of thecomment50 and other comments to the first user'sposting320 may be displayed byfirst display device30 at thecoat rack350.
In some examples the virtual place-locatedanchor56 may not be displayed to a user. In other examples, an anchor hologram representing the virtual place-locatedanchor56 at the world-locked virtual location may be displayed to a user. In the example ofFIG. 3, an anchor hologram in the form of aholographic star356 may be displayed at the world-locked virtual location corresponding to the virtual place-locatedanchor56. In some examples, theholograms330A,330B and330C may be displayed within a predetermined distance of the anchor hologram. For example, theholograms330A,330B and330C may be displayed within 0.5 m, 1.0 m, 2.0 m, or any suitable predetermined distance from theholographic star356.
In some examples, the appearance of the anchor hologram may be changed in response to one or more comments that are associated with the posting320 of thefirst user302. For example, when a new comment is posted, the appearance of theholographic star356 may change to signal the receipt of a new comment. Examples of such a change in appearance of the anchor hologram may include blinking, changing color, changing size, etc. In some examples, thefirst user302 may provide user input that triggers the display of a new hologram of the new comment.
In some examples, thefirst user302 may desire to allow one or more others to view the holograms of the comments associated with the first user'sposting320. With continued reference toFIG. 3, thefirst user302 may transmit via user input tofirst display device30 one ormore permissions70 specifying one ormore conditions72 under which one or more others are authorized to view theholograms330A,330B and330C.
In one example, a connection permission may specify acondition72 that limits viewing of the holograms to other users who are connected with thefirst user302 via one or more social networks, such as social network A. For example, thefirst user302 may have a friend with whom the first user is connected via social network A. With reference again toFIG. 2, this friend may be associated withsecond display device34. In the example ofFIG. 3, this friend is illustrated assecond user364 who is wearingsecond display device34 that may take the form ofHMD device10. Thesecond display device34 may be communicatively coupled to thecomputing device200.
Thefirst user302 may create aconnection permission70 that specifies that other users who are connected with thefirst user302 via social network A may view any holograms of comments associated with any postings of the first user to the social network A. In the example ofFIG. 3, when thesecond user364 enters theliving room306, and usingsensor data68 from thesecond display device34, theanchor program214 may identify theart piece312 and discover the virtual place-locatedanchor56 associated with the art piece.Anchor program214 may determine that thecondition72 specified by theconnection permission70 is satisfied (e.g.,second user364 is connected with thefirst user302 via a social network A). In response,computing device200 may transmit second display data74 to thesecond display device34 that causes the device to display the holograms300A,300B and300C to thesecond user364 at the virtual place-locatedanchor56 at the world-locked virtual location adjacent to theart piece312.
In some examples, thefirst user302 may create a place-basedpermission70 that specifies acondition72 that limits viewing of the holograms to other users who are located within a predetermined viewing range of the virtual place-located anchor. For example and with reference toFIG. 3, thefirst user302 may create a place-basedpermission70 that specifies that any other users who are present in theliving room306 may view holograms of comments associated with postings of the first user to the social network A. In this example, the predetermined viewing range is defined as being located in theliving room306.
In the example ofFIG. 3, awork colleague370 is visiting thefirst user302 and standing in theliving room306. The work colleague may be wearing adisplay device372 that may take the form ofHMD device10. Thedisplay device372 may be communicatively coupled to thecomputing device200. In the example ofFIG. 3, when thework colleague370 enters theliving room306, and using sensor data from thedisplay device372, theanchor program214 may identify theart piece312 and discover the virtual place-locatedanchor56 associated with the art piece.Anchor program214 may determine that thecondition72 specified by the place-basedpermission70 is satisfied (e.g.,work colleague370 is located in the living room306). Accordingly,computing device200 may transmit display data to thedisplay device372 that causes the device to display the holograms300A,300B and300C to thework colleague370 at the virtual place-locatedanchor56 at the world-locked virtual location.
In some examples, the place-based permission may specify acondition72 that limits viewing of the holograms to other users who are located within a predetermined viewing range in the form of a threshold distance from the virtual place-locatedanchor56. For example and with reference toFIG. 3, a threshold distance D from the virtual place-located anchor may be specified. If another user is within the threshold distance D, then such user may view the holograms, whether or not such user is connected tofirst user302 via a social network.
In some examples, the virtual place-located anchor may be located outdoors in a public or private space. Also, it will be appreciated that many other example use cases and types of permissions are possible. For example, thefirst user302 may specify a condition that allows one or more other defined groups of people to view holograms of comments associated with postings of the first user to the social network A. Examples of such groups may include, but are not limited to, those people with whom thefirst user302 is connected via two or more social networks, those people within a specified social distance of the first user (such as friends of friends), an enumerated list of specific people, and any other suitable defined group.
In some examples, thefirst user302 may desire to view holograms associated with postings of the first user to two or more social networks at the same virtual place-located anchor. With reference toFIG. 2, thefirst user302 may have an account at the secondtarget data source42, which may comprise another social network. Thecomputing device200 may receive another plurality ofdata items62 from the secondtarget data source42. As described above with respect to data items from the firsttarget data source38, thecomputing device200 may link a subset of the plurality of data items from the secondtarget data source42, such as postings from thefirst user302, to the virtual place-locatedanchor56.
With reference also to the example ofFIG. 3, thecomputing device200 may transmit second target data source display data to thefirst display device30 worn byfirst user302 that causes the first display device to display one or more world-locked holograms of the subset of the plurality of data items from the secondtarget data source42 to the first user at the virtual place-located anchor. In the example ofFIG. 3, thefirst display device30 may display to thefirst user302holograms380A and380B of comments that reference or are otherwise associated with a posting made by the first user of the image of theart piece312 to the secondtarget data source42. For example, ahologram380A of the comment “Cool!” from User F may be displayed at the virtual place-located anchor at the world-locked virtual location. One or more other holograms of comments to the first user's posting from other friends and/or users of the other social network, such ashologram380B, may also be displayed.
It will be appreciated that the firsttarget data source38 and secondtarget data source42 may comprise any of a variety of types of social networks, such as photo and/or video sharing services, recommendation services, instant messaging services, email services, etc.
In some examples, thefirst user302 may desire to view in two or more different locations the holograms of comments to a posting. With reference now toFIGS. 2, 3 and 5, thefirst user302 may have an account at another social network SN2. A base virtual place-locatedanchor230 may be world-locked to avirtual location382 on or adjacent to thewall384 in theliving room306. In this example, an anchor hologram in the form of a logo SN2 corresponding to the other social network may be displayed at thevirtual location382 corresponding to the base virtual place-locatedanchor230.
Thecomputing device200 may transmit display data to thefirst display device30 that causes the device to display holograms to thefirst user302 at the base virtual place-locatedanchor230 at the world-lockedvirtual location382 adjacent to thewall384. In this example, the holograms represent comments made to a posting of thefirst user302 to the social network SN2 regarding the first user's favorite soccer team. For example,hologram386A of the comment “Great match!” from User K may be displayed at the base virtual place-located anchor at the world-lockedvirtual location382. One or more other holograms of comments to the first user's posting from other friends and/or users of the other social network SN2, such asholograms386B and386C, may also be displayed.
With reference now toFIG. 5, thefirst user302 may provide user input to thefirst display device30 to generate a mirrored virtual place-located anchor240 at another world-locked virtual location in amedia room500. In this example, the world-locked virtual location is defined as the volume of space adjacent to the upper left corner oftelevision504 indicated at510. Another anchor hologram in the form of logo SN2 may be displayed to thefirst user302 at the world-lockedvirtual location510 corresponding to the mirrored virtual place-located anchor240.
When thefirst user302 is present in themedia room500, thecomputing device200 may transmit mirror display data to thefirst display device30 that causes the first display device to displayholograms386A′,386B′ and386C′ at the mirrored virtual place-located anchor at the world-lockedvirtual location510. As illustrated inFIGS. 3 and 5,holograms386A′,386B′ and386C′ displayed to thefirst user302 inmedia room500 are copies of theholograms386A,386B and386C displayed to thefirst user302 in theliving room306. In this manner, thefirst user302 may use the base virtual place-locatedanchor230 and mirrored virtual place-located anchor240 to convenienly view the same holograms in two different locations. In other examples, two, three or more mirrored virtual place-located anchors may be generated and located in corresponding different locations.
In some examples, thefirst user302 may interact with a social network on one or more other display devices, such as a smartphone, tablet computer, etc. In some examples the social network may indicate that a posting from thefirst user302 is associated with a virtual place located anchor. With reference now toFIG. 6, in one example the first user302 (Alley) may interact with social network SN2 via asmartphone600 that displays amobile user interface604 for the social network SN2. Alley may submit to the social network SN2 a posting in the form of a status update reading “Mighty Team Z wins!! What a performance!” In other examples, the posting may comprise an image such as a photograph, a video, and/or a text comment.
As described above, thefirst user302 may causefirst display device30 viacomputing device200 to display holograms of comments to her posting to social network SN2 at a virtual place-located anchor at a world-locked virtual location. In some examples, thecomputing device200 also may instruct the social network SN2 to indicate that the first user's posting is associated with a virtual place-located anchor. In response and in the example ofFIG. 6, themobile user interface604 of the social network SN2 may display anasterisk610 with the first user's posting to signal to thefirst user302 that this posting is associated with a virtual place-located anchor. In this manner, thefirst user302 is conveniently alerted that holograms of comments to her posting are available at a corresponding virtual place-located anchor at a world-locked virtual location.
In other examples, a variety of other indicators and methods for indicating that a posting is associated with the virtual place-located anchor may be used. Such other examples may include, but are not limited to, highlighting, flashing, coloring, or otherwise altering the appearance of the posting. Also and as described in more detail below, in some examples the display of thesmartphone600 may visually augment a user's view of a real world environment by displaying virtual content such as two-dimensional images at a virtual place-located anchor.
In some examples, a user may interact with a virtual place-located anchor to reply to a comment displayed as a hologram. With reference again toFIG. 5, in one example thefirst user302 may direct user input to the anchor hologram SN2 to reply to one of the displayed holographic comments. In some examples such user input may take the form of voice input, eye-tracking/gaze input, gesture input, or any other suitable form of user input. For example, thefirst user302 may speak an instruction to thefirst display device30 to “Reply to User J, quote I'm going to the Team X game. Want to carpool? end quote.” In some examples, a hologram of the reply offirst user302 may be displayed to thefirst user302 viafirst display device30.
FIGS. 7A, 7B and 7C illustrate a flow chart of amethod700 for generating a virtual place-located anchor at which holograms may be viewed according to an example of the present disclosure. The following description ofmethod700 is provided with reference to the software and hardware components described above and shown inFIGS. 1-6. It will be appreciated thatmethod700 also may be performed in other contexts using other suitable hardware and software components.
With reference toFIG. 7A, at704 themethod700 may include in a creating phase, receiving an instruction to generate a virtual place-located anchor at a virtual location that is world-locked. At708 the virtual location may be world-locked to a position that is fixed in a three dimensional coordinate space overlaid upon the real world three dimensional environment. At712 the virtual location may be world-locked to a position relative to an object in the real world three dimensional environment.
At716 in the creating phase themethod700 may include receiving a plurality of data items from a target data source at which a first user has an account. At720 the target data source may comprise a social network, and the subset of the plurality of data items may comprise third party comments to a posting from the first user on the social network. At724 in the creating phase themethod700 may include linking a subset of the plurality of data items to the virtual place-located anchor.
At728 in the creating phase themethod700 may include receiving a permission via user input from the first user, the permission specifying a condition under which a second user is authorized to view one or more holograms of the subset of data items. At732 in the creating phase themethod700 may include transmitting an instruction to the social network to indicate that the posting is associated with the virtual place-located anchor.
With reference now toFIG. 7B, in a viewing phase at736 themethod700 may include transmitting first display data to a first display device comprising an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display, the first display data causing the first display device to display the one or more holograms of the subset of data items to the first user at the virtual place-located anchor at the virtual location. At740 the first display data may cause the first display device to display at the virtual location an anchor hologram representing the virtual place-located anchor; and to display the one or more holograms within a predetermined distance of the anchor hologram.
At744 in the viewing phase themethod700 may include determining if the condition is satisfied. At748 in the viewing phase themethod700 may include, if the condition is satisfied, transmitting second display data to cause a second display device to display the one or more holograms of the subset of data items to the second user at the virtual place-located anchor at the virtual location. At752 in the viewing phase themethod700 may include, where the target data source is a social network and the permission is a connection permission, if the second user is connected with the first user via the social network, then the condition is satisfied. At756 in the viewing phase themethod700 may include, where the permission is a place-based permission, if the second user device is located within a predetermined viewing range of the virtual place-located anchor, then the condition is satisfied.
With reference now toFIG. 7C, where the virtual location is world-locked to a position relative to an object in the real world three dimensional environment, and where the object is at an initial real world location, at760 in the creating phase themethod700 may include receiving sensor data from the first user device, and using the sensor data, identifying the object at a subsequent real world location different from the initial real world location. At764 in the viewing phase themethod700 may include transmitting subsequent display data to the first display device that causes the first display device to display the one or more holograms to the first user at the virtual place-located anchor at the virtual location world-locked to the position relative to the object at the subsequent real world location.
Where the virtual place-located anchor is a base virtual place-located anchor, at768 in the creating phase themethod700 may include receiving an instruction to generate a mirrored virtual place-located anchor at another virtual location that is world-locked. At772 in the viewing phase themethod700 may include transmitting mirror display data to the first display device that causes the first display device to display the one or more holograms to the first user at the mirrored virtual place-located anchor at the other virtual location.
Where the plurality of data items are a first plurality of data items and the target data source is a first target data source, at776 in the creating phase themethod700 may include receiving a second plurality of data items from a second target data source at which the first user has an account; and linking a subset of the second plurality of data items to the virtual place-located anchor. At780 in the viewing phase themethod700 may include transmitting second target data source display data to the first display device that causes the first display device to display one or more world-locked holograms of the subset of the second plurality of data items to the first user at the virtual place-located anchor.
It will be appreciated thatmethod700 is provided by way of example and is not meant to be limiting. Therefore, it is to be understood thatmethod700 may include additional and/or alternative steps relative to those illustrated inFIGS. 7A, 7B and 7C. Further, it is to be understood thatmethod700 may be performed in any suitable order. Further still, it is to be understood that one or more steps may be omitted frommethod700 without departing from the scope of this disclosure.
In some embodiments, the methods and processes described herein may be tied to a computing system of one or more computing devices. In particular, such methods and processes may be implemented as a computer-application program or service, an application-programming interface (API), a library, and/or other computer-program product.
While the above examples are described in the context of displaying holograms, it will be appreciated that the present disclosure may be utilized with other virtual content, such as two-dimensional images, and with non-holographic displays. For example, tablet computers, smartphones, and other mobile computing devices may receive a digital video feed that visually augments a user's view of a real world environment via a display according to the principles of the present disclosure.
FIG. 8 schematically shows a non-limiting embodiment of acomputing system800 that can enact one or more of the methods and processes described above.Computing system800 is shown in simplified form.Computing system800 may take the form of one or more head-mounted display devices as shown inFIG. 1, or one or more devices cooperating with a head-mounted display device (e.g., personal computers, server computers, tablet computers, home-entertainment computers, network computing devices, gaming devices, mobile computing devices, mobile communication devices (e.g., smart phone), and/or other computing devices).
Computing system800 includes alogic processor804,volatile memory808, and anon-volatile storage device812.Computing system800 may optionally include adisplay subsystem816,input subsystem820,communication subsystem824, and/or other components not shown inFIG. 8.
Logic processor804 includes one or more physical devices configured to execute instructions. For example, the logic processor may be configured to execute instructions that are part of one or more applications, programs, routines, libraries, objects, components, data structures, or other logical constructs. Such instructions may be implemented to perform a task, implement a data type, transform the state of one or more components, achieve a technical effect, or otherwise arrive at a desired result.
The logic processor may include one or more physical processors (hardware) configured to execute software instructions. Additionally or alternatively, the logic processor may include one or more hardware logic circuits or firmware devices configured to execute hardware-implemented logic or firmware instructions. Processors of thelogic processor804 may be single-core or multi-core, and the instructions executed thereon may be configured for sequential, parallel, and/or distributed processing. Individual components of the logic processor optionally may be distributed among two or more separate devices, which may be remotely located and/or configured for coordinated processing. Aspects of the logic processor may be virtualized and executed by remotely accessible, networked computing devices configured in a cloud-computing configuration. In such a case, these virtualized aspects may be run on different physical logic processors of various different machines.
Volatile memory808 may include physical devices that include random access memory.Volatile memory808 is typically utilized bylogic processor804 to temporarily store information during processing of software instructions. It will be appreciated thatvolatile memory808 typically does not continue to store instructions when power is cut to thevolatile memory808.
Non-volatile storage device812 includes one or more physical devices configured to hold instructions executable by the logic processors to implement the methods and processes described herein. When such methods and processes are implemented, the state ofnon-volatile storage device812 may be transformed—e.g., to hold different data.
Non-volatile storage device812 may include physical devices that are removable and/or built-in.Non-volatile storage device812 may include optical memory (e.g., CD, DVD, HD-DVD, Blu-Ray Disc, etc.), semiconductor memory (e.g., ROM, EPROM, EEPROM, FLASH memory, etc.), and/or magnetic memory (e.g., hard-disk drive, floppy-disk drive, tape drive, MRAM, etc.), or other mass storage device technology.Non-volatile storage device812 may include nonvolatile, dynamic, static, read/write, read-only, sequential-access, location-addressable, file-addressable, and/or content-addressable devices. It will be appreciated thatnon-volatile storage device812 is configured to hold instructions even when power is cut to thenon-volatile storage device812.
Aspects oflogic processor804,volatile memory808, andnon-volatile storage device812 may be integrated together into one or more hardware-logic components. Such hardware-logic components may include field-programmable gate arrays (FPGAs), program-and application-specific integrated circuits (PASIC/ASICs), program-and application-specific standard products (PSSP/ASSPs), system-on-a-chip (SOC), and complex programmable logic devices (CPLDs), for example.
The term “program” may be used to describe an aspect ofcomputing system800 implemented to perform a particular function. In some cases, a program may be instantiated vialogic processor804 executing instructions held bynon-volatile storage device812, using portions ofvolatile memory808. It will be understood that different programs may be instantiated from the same application, service, code block, object, library, routine, API, function, etc. Likewise, the same program may be instantiated by different applications, services, code blocks, objects, routines, APIs, functions, etc. The term “program” encompasses individual or groups of executable files, data files, libraries, drivers, scripts, database records, etc.
When included,display subsystem816 may be used to present a visual representation of data held bynon-volatile storage device812. As the herein described methods and processes change the data held by the non-volatile storage device, and thus transform the state of the non-volatile storage device, the state ofdisplay subsystem816 may likewise be transformed to visually represent changes in the underlying data.Display subsystem816 may include one or more display devices utilizing virtually any type of technology. Such display devices may be combined withlogic processor804,volatile memory808, and/ornon-volatile storage device812 in a shared enclosure, or such display devices may be peripheral display devices. Theimage production system22 configured to display virtual objects such as holograms via the at least partially see-throughdisplay12 ofHMD device10 described above is one example of adisplay subsystem816.
When included,input subsystem820 may comprise or interface with one or more user-input devices such as a keyboard, mouse, touch screen, or game controller. In some embodiments, the input subsystem may comprise or interface with selected natural user input (NUI) componentry. Such componentry may be integrated or peripheral, and the transduction and/or processing of input actions may be handled on- or off-board. Example NUI componentry may include a microphone for speech and/or voice recognition; an infrared, color, stereoscopic, and/or depth camera for machine vision and/or gesture recognition; a head tracker, eye tracker, accelerometer, and/or gyroscope for motion detection, gaze detection, and/or intent recognition; as well as electric-field sensing componentry for assessing brain activity; any of the sensors described above with respect toposition sensor system18 ofFIG. 1; and/or any other suitable sensor.
When included,communication subsystem824 may be configured to communicatively couplecomputing system800 with one or more other computing devices.Communication subsystem824 may include wired and/or wireless communication devices compatible with one or more different communication protocols. As non-limiting examples, the communication subsystem may be configured for communication via a wireless telephone network, or a wired or wireless local- or wide-area network. In some embodiments, the communication subsystem may allowcomputing system800 to send and/or receive messages to and/or from other devices via a network such as the Internet.
It will be understood that the configurations and/or approaches described herein are exemplary in nature, and that these specific embodiments or examples are not to be considered in a limiting sense, because numerous variations are possible. The specific routines or methods described herein may represent one or more of any number of processing strategies. As such, various acts illustrated and/or described may be performed in the sequence illustrated and/or described, in other sequences, in parallel, or omitted. Likewise, the order of the above-described processes may be changed.
The subject matter of the present disclosure includes all novel and nonobvious combinations and subcombinations of the various processes, systems and configurations, and other features, functions, acts, and/or properties disclosed herein, as well as any and all equivalents thereof.
The following paragraphs provide additional support for the claims of the subject application. One aspect provides a method, comprising: in a creating phase: receiving an instruction to generate a virtual place-located anchor at a virtual location that is world-locked; receiving a plurality of data items from a target data source at which a first user has an account; linking a subset of the plurality of data items to the virtual place-located anchor; receiving a permission via user input from the first user, the permission specifying a condition under which a second user is authorized to view one or more holograms of the subset of data items; in a viewing phase: transmitting first display data to a first display device comprising an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display, the first display data causing the first display device to display the one or more holograms of the subset of data items to the first user at the virtual place-located anchor at the virtual location; determining if the condition is satisfied; and if the condition is satisfied, transmitting second display data to cause a second display device to display the one or more holograms of the subset of data items to the second user at the virtual place-located anchor at the virtual location. The method may additionally or optionally include wherein the target data source comprises a social network, and the subset of the plurality of data items comprises third party comments to a posting from the first user on the social network. The method may additionally or optionally include, in the creating phase, transmitting an instruction to the social network to indicate that the posting is associated with the virtual place-located anchor. The method may additionally or optionally include, wherein the first display data causes the first display device to: display at the virtual location an anchor hologram representing the virtual place-located anchor; and display the one or more holograms within a predetermined distance of the anchor hologram. The method may additionally or optionally include, wherein the virtual location is world-locked to a position that is fixed in a three dimensional coordinate space overlaid upon the real world three dimensional environment. The method may additionally or optionally include, wherein the virtual location is world-locked to a position relative to an object in the real world three dimensional environment. The method may additionally or optionally include, wherein the object is at an initial real world location: in the creating phase: receiving sensor data from the first user device; using the sensor data, identifying the object at a subsequent real world location different from the initial real world location; and in the viewing phase: transmitting subsequent display data to the first display device that causes the first display device to display the one or more holograms to the first user at the virtual place-located anchor at the virtual location world-locked to the position relative to the object at the subsequent real world location. The method may additionally or optionally include, wherein the virtual place-located anchor is a base virtual place-located anchor: in the creating phase: receiving an instruction to generate a mirrored virtual place-located anchor at another virtual location that is world-locked; and in the viewing phase: transmitting mirror display data to the first display device that causes the first display device to display the one or more holograms to the first user at the mirrored virtual place-located anchor at the other virtual location. The method may additionally or optionally include, wherein the plurality of data items are a first plurality of data items, the target data source is a first target data source, the method further comprising: in the creating phase: receiving a second plurality of data items from a second target data source at which the first user has an account; linking a subset of the second plurality of data items to the virtual place-located anchor; and in the viewing phase:
transmitting second target data source display data to the first display device that causes the first display device to display one or more world-locked holograms of the subset of the second plurality of data items to the first user at the virtual place-located anchor. The method may additionally or optionally include, wherein the target data source is a social network and the permission is a connection permission, and if the second user is connected with the first user via the social network, then the condition is satisfied. The method may additionally or optionally include, wherein the permission is a place-based permission, and if the second user device is located within a predetermined viewing range of the virtual place-located anchor, then the condition is satisfied.
Another aspect provides a computing device, comprising: an anchor program executed by a processor of the computing device, the anchor program configured to: in a creating phase: receive an instruction to generate a virtual place-located anchor at a virtual location that is world-locked; receive a plurality of data items from a target data source at which a first user has an account; link a subset of the plurality of data items to the virtual place-located anchor; receive a permission via user input from the first user, the permission specifying a condition under which a second user is authorized to view one or more holograms of the subset of data items; in a viewing phase: transmit first display data to a first display device comprising an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display, the first display data causing the first display device to display the one or more holograms of the subset of data items to the first user at the virtual place-located anchor at the virtual location; determine if the condition is satisfied; and if the condition is satisfied, transmit second display data to cause a second display device to display the one or more holograms of the subset of data items to the second user at the virtual place-located anchor at the virtual location. The computing device may additionally or optionally include, wherein the virtual location is world-locked to a position that is fixed in a three dimensional coordinate space overlaid upon the real world three dimensional environment. The computing device may additionally or optionally include, wherein the virtual location is world-locked to a position relative to an object in the real world three dimensional environment. The computing device may additionally or optionally include, wherein the object is at an initial real world location, and the anchor program is configured to: in the creating phase: receive sensor data from the first user device; using the sensor data, identify the object at a subsequent real world location different from the initial real world location; and in the viewing phase: transmit subsequent display data to the first display device that causes the first display device to display the one or more holograms to the first user at the virtual place-located anchor at the virtual location world-locked to the position relative to the object at the subsequent real world location. The computing device may additionally or optionally include, wherein the subset of the plurality of data items comprises third party comments related to an image, a video, a comment, or an update that is posted by the first user to the target data source. The computing device may additionally or optionally include, wherein the anchor program is configured to: in the creating phase: receive from the first display device an image of an object in the real world three dimensional environment at the virtual location, wherein the image is posted to the target data source; and filter the plurality of data items by selecting third party comments associated with the image as the subset of the plurality of data items. The computing device may additionally or optionally include, wherein the virtual place-located anchor is a base virtual place-located anchor, and the anchor program is configured to: in the creating phase: receive an instruction to generate a mirrored virtual place-located anchor at another virtual location that is world-locked; and in the viewing phase: transmit mirror display data to the first display device that causes the first display device to display the one or more holograms to the first user at the mirrored virtual place-located anchor at the other virtual location. The computing device may additionally or optionally include, wherein the plurality of data items are a first plurality of data items, the target data source is a first target data source, and the anchor program is configured to: in the creating phase: receive a second plurality of data items from a second target data source at which the first user has an account; link a subset of the second plurality of data items to the virtual place-located anchor; and in the viewing phase: transmit second target data source display data to the first display device that causes the first display device to display one or more world-locked holograms of the subset of the second plurality of data items to the first user at the virtual place-located anchor.
Another aspect provides a method, comprising: in a creating phase: receiving an instruction to generate a virtual place-located anchor at a virtual location that is world-locked to a position relative to an object in the real world three dimensional environment; receiving a plurality of data items from a social network at which a first user has an account; linking a subset of the plurality of data items to the virtual place-located anchor, the subset of data items comprising third party comments to a posting from the first user on the social network; receiving a permission via user input from the first user, the permission specifying a condition under which a second user is authorized to view one or more holograms of the subset of data items; in a viewing phase: transmitting first display data to a first display device comprising an at least partially see-through display configured to visually augment a view of a real world three dimensional environment through the display, the first display data causing the first display device to display the one or more holograms of the subset of data items to the first user at the virtual place-located anchor at the virtual location; determining if the condition is satisfied; and if the condition is satisfied, transmitting second display data to cause a second display device to display the one or more holograms of the subset of data items to the second user at the virtual place-located anchor at the virtual location.