Not applicable.
The field of the invention is office spaces and more specifically spaces that automatically adapt to user presence and optimize for specific experiences or activities within spaces.
During the course of a typical work day, employees of a company or other business entity often perform various tasks or activities. For example, during a typical day, a specific employee may work individually, may work with one other employee in a dyadic fashion to share ideas and develop new ideas, may work with two or more other persons to share information or develop concepts in a larger conference setting, may spend a portion of her day on the phone conversing with colleagues or customers, may participate in a video conference with one or more remote colleagues or clients or may spend some time resting by either napping or simply meditating.
In the office space industry it is generally recognized that space affordances can facilitate or hinder activities and that recognition has lead to differently afforded spaces that have been at least somewhat optimized for different activities. For instance, a typical personal office space may include a desk, a task chair and a computer including a display screen on the desk. In contrast, a typical conference space may include a large table, a plurality of chairs arranged about the edges of the table and a projector or large electronic display screen for presenting content from a computer or the like that is being shared within the conference space. Clearly office spaces and conference spaces are differently afforded and each set of affordances enhances the specific use assigned to the space.
In addition to assemblies that provide work surfaces, support chairs for space users and screens for accessing digital information, many spaces have other affordances that, while capable of enhancing specific activities within the spaces, are essentially ignored or are underutilized by space users for one reason or another. For instance, most office spaces include some type of lighting device(s) (e.g., a desk light, a floor lamp, overhead lighting, upward or downward directed shelf lighting, etc.) for illuminating general ambient space, work surfaces, wall surfaces, etc. Here, even where lighting devices are controllable so that light intensity can be adjusted, most lights are either off or turned on to their highest intensity level regardless of whether or not an intermediate intensity level may be optimal for some purpose. For example, in a conference room, lights are often completely on when digital content is not shared and off when digital content is not being shared with no in between. In personal office spaces lights are usually either on with high intensity or off despite the fact that other lighting settings may be optimal depending on the activity performed within the office space. Many spaces include several lighting devices which are often all on or all off regardless of whether those settings are optimized for specific activities.
Other space affordances that are rarely adjusted despite the fact that they can have a great impact on how well activities are performed within a space include temperature control devices (e.g., heaters, cooling devices, etc.), air flow devices (e.g., fans), audio devices (e.g., speakers and audio players that can play sound tracks), electronic display screens that are not being used to present content within a space, etc.
There are several reasons space users do not optimally adjust many affordances within office spaces. First, in many cases, a user simply does not have an understanding that each of the affordances can be adjusted to optimize specific activities. For instance, for many space users high intensity light on a primary work surface with dimmed ambient light optimizes the user's ability to focus on individual work being performed on the primary work surface. Nevertheless, many space users simply rely on a single intensity ambient light to light their work surfaces. As another instance, where a person uses a space to facilitate a resting activity (e.g., take a short nap), in many cases the resting activity would be enhanced where temperature is increased by a few degrees. Nevertheless, space temperature is only rarely adjusted by space users. As yet one other example, it is known that white noise can drown out voices or other noises within a walkway adjacent a space yet even where white noise sound tracks are available to space users, the tracks are rarely played. Many other examples of optimized environmental characteristics that are not understood by space users exist.
Second, even where a space user has a general understanding that certain activities can be enhanced by optimally adjusting affordances, in many cases the user has no understanding of which settings are optimal for which activities. Here, confused, a user often simply uses affordances as set when the user occupies a space without adjusting the affordances to optimize space use for specific activities.
Third, even where a space user recognizes that activities can be enhanced by optimally adjusting affordances and has a good understanding of how those affordances should be optimized for at least some activities, in many cases different affordances are controlled by different control systems or devices and therefore, to adjust several affordances to optimal settings, a user would have to adjust many (e.g., 4-6) different devices. The burden of optimally adjusting many devices each time the activity within a space is changed means that space users simply use space with affordances set “as is” and do not bother with optimizing the affordances to specific activities. This is particularly true in cases where one person may use many different spaces during a day to perform many different tasks. For instance, in a case where an employer has remote employees that “hotel” in spaces in different facilities, most employees will not take the time to optimally set affordance characteristics even if they understand how the setting can affect their activities. In hotelling cases, often-times affordances and controls therefore are different in different spaces and, while a user may understand a control device in one space that is routinely used by the user, the user may not understand another interface for a similar affordances in a different space. The end result is that the user will not take advantage of the capability of setting optimized affordances in differently controlled spaces.
Fourth, in many cases, while a space user may understand how affordance settings can be optimized for that user for a specific activity (e.g., user preferences for individual focused work), the user often times will have no understanding of how the affordances can be optimized for other types of activities. Again, a user may understand that bright task lighting on a primary work surface with dimmed lighting in the ambient can optimally support individual focused work but may have no clue that the lighting should be changed for dyadic use of the same space where the user and another space user are sharing ideas in an open conversation and should be changed again for video conferencing and yet again during a resting activity. In these cases, instead of manually adjusting affordances to optimize for specific activities, users typically forego adjustment and simply use less than optimal settings for specific activities.
In addition to there being optimized environment characteristics for different activities performed in a space, it is believed that there are also different optimized characteristic sets for different phases of any given activity. For instance, in the case of a space optimized for facilitating a resting activity (e.g., a short nap), there may be several phases of the activity including an invite phase that invites a user to use the space for a rest activity, a welcome phase that helps a user take control of the space, an activity phase during which a resting activity is performed and an emerge phase that helps a user emerge from the resting activity. Here, there are optimal changes to a space environment that can enhance each of the different phases of the activity. Again, here, most users are unaware of optimized affordance settings for phases and even if they understand that optimized affordance settings for each phase exist, the burden of adjusting the affordance settings is too great to be performed for each activity within the space.
Thus, there is a need for a system where affordance settings within a space can be optimized for the space and for specific activities within the space in a simplified manner. There is also a need for a system where affordance settings can be optimized easily for specific users of spaces.
It has been recognized that the environment within a space substantially affects how well specific activities can be accomplished within the space. It has also been recognized that many affordances within spaces that can be adjusted to control space environment are poorly utilized and therefore that many space environments are not optimized for specific activities. Moreover it has been recognized that many of the poorly utilized affordances can be automatically controlled by a system server that, based on trigger events that occur within or proximate a space, adjust affordances either automatically or substantially independent of input from space users so that space environment can be optimized for specific activities or so that at least particularly advantageous environments for specific activities can be provided. In at least some cases actions that a space user would perform during normal use of a space such as closing a door to the space, presenting an identification (e.g., RF) device to take control of the space, sitting down within the space, standing up within the space, etc., may be used as triggers for adjusting space affordances to change environmental characteristics. Thus, space characteristics may be optimized or adjusted substantially automatically without requiring a user to understand how to operate a control interface associated with a specific space.
It has also been recognized that many space experiences have different generally repeatable phases and that the environment within a space can facilitate each of the phases when adjusted appropriately. Thus, where a space is to be used for individual focused work for instance, while light may be high intensity on a primary work surface with dim ambient light there around (e.g., a focused light pattern) while a space user is focusing on work, there may be a phase in or welcome period when the user first takes control of the space, taking materials out of a book bag, setting up the space with materials on the primary work surface, etc. as well as an emerge or phase out period when the user is preparing to leave the space by packing up materials, making sure no materials are left behind, cleaning up the primary and other work spaces, etc., during which the focused lighting pattern is not optimal or even advantageous. Here, lighting and other space affordances (e.g., temperature, sound effects, air circulation, etc.) may all be adjusted differently during each of the different phases in ways designed to enhance activities performed during each phase. Again, actions by a user within the space during normal use of the space may be selected as triggers for commencing next sequential phases in a space experience so that changes to space affordance settings occur generally automatically without requiring any dedicated action, gesture or input from the user for controlling the settings. Thus, for instance, in one embodiment, a system server may control lighting devices within a first space to generate pulsing green light during an invite phase when the space is available for use (e.g., is not scheduled for use during a current or temporally immanent period of time). When a user enters the space and closes a door to a space egress, the door closing may trigger a welcome phase where lighting changes, a first sound track is played, etc. When the user presents an identification device to a reader in the space to schedule use of the space during the current period, upon reading the device, the system may again change to lighting as well as the sound track, temperature in the space, air circulation, notice capability of personal devices within the space (e.g., block delivery of e-mails, texts, etc., to devices in the space), etc. Near the end of the scheduled period of use, the system may, based on time, automatically trigger an emerge phase, again changing the lighting and sound effects, changing space temperature and air circulation, change the notice capability of personal devices within the space, etc. When the user opens the door to exist the space, settings may revert back to the invite settings to invite use of the space by another user.
Interruptions inevitably occur during space use. To deal with interruptions during an ongoing space experience, the system may be programmed to automatically recognize when conditions within a space have changed and to adjust space affordances accordingly. For instance, where a user is performing individual focused work activity in a space and the lighting is high intensity on a work surface and dim generally within the ambient and a second person opens a door to the space, the system may sense the door opening (e.g., the trigger) and immediately change the lighting setting to have an intermediate level of light intensity within the entire space and to dim the intensity on the primary work surface. Thereafter, when the second person leaves the space and closes the door, the lighting setting may revert back to the individual focused work setting automatically. Other affordance adjustments based on sensed interruptions are contemplated.
It has also been recognized that more than one space experience may be provided by affordances associated with a space even if the space is optimized for one type of space experience and that a system server or controller (e.g., a computer of some type either remote or local) may control affordances based on the set of affordances available within a space. For instance, where a space experience specification specifies seven optimal affordance settings for a space and a specific space only includes five of the seven affordances, the server will nevertheless control the five affordances according to the specification in at least some embodiments of the present disclosure to present as much of an optimized environment for a specific experience as possible.
In at least some embodiments separate spaces are optimally afforded for different space experiences. For instance, in at least some cases a first subset of spaces may be optimally fitted out to support resting activities, a second subset of spaces may be optimally fitted out to support dyadic activities, a third subset of spaces may be optimally fitted out to support individual focused work, etc. In these cases, in at least some embodiments, when a user takes control of a space, the space experience associated with the optimal activity may be commenced automatically. In some cases a user may be able to select a different space experience causing the system server to control the space according to a specification for the different experience that was selected.
In some embodiments lighting devices used within the spaces are color controllable so that the lighting devices can generate illumination of virtually any color. For instance, in at least some cases RGB LEDs may be provided on lighting devices and may be controlled to generate any desired light color. The different color illumination may be used to enhance space experiences. For instance, during a rest (e.g., nap) activity, space lighting may be dark blue, during a welcome phase of a space experience the lighting may be a warm yellow/orange, where focused work is performed lighting may be bright white, etc. Light intensity and special effects may also be controlled to enhance specific activities and phases of different experiences. For instance, light intensity may be pulsed in a sinusoidal pattern or to follow a sound track in some cases. As another instance, lighting color and effect may be controlled to simulate different effects like a rising sun, lightening in a dark sky, etc. Other effects are contemplated.
In at least some cases a space or room control interface device may be provided adjacent or within a space for manually adjusting affordances via an intuitive interface. For instance, lighting, sound, temperature, circulation, etc., may be controlled via a touch screen interface.
In at least some embodiments a space user can adjust affordance settings for specific types of space experiences (e.g., rest, individual focused work, dyadic space use, etc.) and can store those personalized settings. Thereafter, the system may, when the specific user is identified in a space and a specific space experience is to be performed, use the personalized settings to present the experience to the space user.
In at least some embodiments where a space user has a personal portable device (e.g., a smart phone, a tablet type computing device, a laptop, etc.) in a space, the system may use one or more capabilities of the personal device to present at least some space experience effects. For instance, where a portable device includes speakers or an earphone jack, experience sound tracks may be played on the user device to be presented to the user.
Many personal devices include some type of data collector or sensor. For instance, many personal devices include an accelerometer, a gyroscope, an elevation detector, etc. As another instance, many personal devices include a camera that can obtain images. As yet another instance, some personal devices can now sense gestures proximate the devices (e.g., adjacent a display screen). In at least some embodiments it is contemplated that one or more of the sensors or data collectors on a personal device may be used to obtain information that can operate as a trigger for controlling space affordances. For instance, where a personal device is within a user's pocket and the user stands up during individual focused work, the accelerometer or some other sensor may sense the change in posture and send a wireless signal to a system server which may then change the lighting effect within the space according to an experience specification. As another instance, a portable device camera may be positioned within the space to obtain images transmitted to the system server for examination to identify other trigger activities.
These and other objects, advantages and aspects of the invention will become apparent from the following description. In the description, reference is made to the accompanying drawings which form a part hereof, and in which there is shown a preferred embodiment of the invention. Such embodiment does not necessarily represent the full scope of the invention and reference is made therefore, to the claims herein for interpreting the scope of the invention.
The various aspects of the subject disclosure are now described with reference to the drawings, wherein like reference numerals correspond to similar elements throughout the several views. It should be understood, however, that the drawings and detailed description hereafter relating thereto are not intended to limit the claimed subject matter to the particular form disclosed. Rather, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the claimed subject matter.
As used herein, the terms “component,” “system” and the like are intended to refer to a computer-related entity, either hardware, a combination of hardware and software, software, or software in execution. For example, a component may be, but is not limited to being, a process running on a processor, a processor, an object, an executable, a thread of execution, a program, and/or a computer. By way of illustration, both an application running on a computer and the computer can be a component. One or more components may reside within a process and/or thread of execution and a component may be localized on one computer and/or distributed between two or more computers or processors.
The word “exemplary” is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other aspects or designs.
Furthermore, the disclosed subject matter may be implemented as a system, method, apparatus, or article of manufacture using standard programming and/or engineering techniques to produce software, firmware, hardware, or any combination thereof to control a computer or processor based device to implement aspects detailed herein. The term “article of manufacture” (or alternatively, “computer program product”) as used herein is intended to encompass a computer program accessible from any computer-readable device, carrier, or media. For example, computer readable media can include but are not limited to magnetic storage devices (e.g., hard disk, floppy disk, magnetic strips . . . ), optical disks (e.g., compact disk (CD), digital versatile disk (DVD) . . . ), smart cards, and flash memory devices (e.g., card, stick). Additionally it should be appreciated that a carrier wave can be employed to carry computer-readable electronic data such as those used in transmitting and receiving electronic mail or in accessing a network such as the Internet or a local area network (LAN). Of course, those skilled in the art will recognize many modifications may be made to this configuration without departing from the scope or spirit of the claimed subject matter.
Referring now to the drawings wherein like reference numerals correspond to similar elements throughout the several views and, more specifically, referring to
Referring again to
Server 102 may include any type of computing device having the capability to run space control software to take inputs from the interface devices and the sensors and to provide output control signals to the controller 150 for controlling various aspects of any given space. The server 102 may, for instance, include a remote or local stationary computer dedicated to controlling the devices in one or several different spaces within one or several facilities. As another instance, the server 102 may include a portable computer in some cases that runs software to perform various functions. The server 102 may be hard wired to the control system 150 or may be wirelessly connected in some cases.
Server 102 is linked to database 130. Database 130 stores programs run by server 102 to perform various processes as described hereafter as well as specifications for how the affordances within specific spaces are controlled as a function of various sensed parameters. Hereinafter, unless indicated otherwise, any specific sequence of affordance control will be referred to as a “space experience”. The space experience specifications can be changed by a system administrator using a workstation 140 or other interface device in at least some cases. Also, in some cases, any or at least a subset of system users may be able to change a subset or all of the space experience specifications or may be able to customize one or more space experience specifications for their own use using an interface 140 or using a room controller device (e.g., 104). Any changes to a space experience specification may be stored in database 130 for subsequent use.
Referring again to
RFID sensor 108 is a radio frequency sensor device that can be used to sense an RF identification card, badge, fob, etc. (e.g., an RFIF device), to obtain information therefrom. For instance, an RFID card may include information for determining the identity of a system user that is associated with the card so that one system user can be distinguished from others. As another instance, an RFID card may simply indicate characteristics of personalized space experiences for a system user associated with the card as opposed to indicating the identity of the user. RFID sensor devices are well known and therefore will not be described here in detail. It should suffice to say that when an RF identification device is placed within a sensing range or area associated with the sensor 108, the sensor 108 obtains the information stored on the identification device and provides that information to server 102. Here, the RF sensor may be any type of RF sensor including an NFC sensor or some type of conventional wireless communication (e.g., RF should be considered broadly to include any type of wireless communication unless indicated otherwise).
It is also contemplated that this information could be provided via traditional wireless connections to the user's devices or via an IR connection. It would also be possible to utilize a wired connection, although it is believed the wireless connection is particularly advantageous.
Portable device sensor 106 is a sensor for sensing that an electronic portable device associated with a specific user is within an area associated with a facility space. For instance, sensor 106 may include a blue tooth or sonic sensor device mounted within a doorway into a space to sense when a portable device passes through the doorway. Here, the Bluetooth or sonic signal may be transmitted periodically and may cause any portable device within the doorway or even within the space associated with the doorway to generate an identifying signal so that the identity of a user entering the space can be determined. Again, any signal obtained by device 106 is provided to server 102.
Many spaces may be equipped with wireless access devices 132 mounted in ceiling structure or at other locations to facilitate communication between server 102 and personal portable electronic devices like tablet type devices, smart phones, laptop computers, 110, etc. In at least some cases signals received by a set of access points proximate a space may be used to triangulate the location of a specific portable device and to determine when the device is located within a specific space. Triangulation algorithms are well known in the industry and therefore are not explained here in detail. Once a portable electronic device is associated with a space, control screens for the space may be presented via the interface device that are similar to the screens that can be presented via a Room Wizard interface screen.
Referring again to
Referring again to
In addition to or instead of the temperature sensor 114, other types of sensors including a motion sensor 118, a proximity sensor 120 or a presence sensor 122 may be provided within or adjacent space 220 (see again
In addition, a sensor may be located within a moveable affordance within space 220 such as within a lounge chair 252 for supporting a user in space 220. Here, in at least some cases a wireless transceiver may be provided within the lounge chair for transmitting signals when a sensor therein senses something. For instance, the sensor in chair 252 may sense presence of a user in the chair via proximity, motion, weight, etc., and may wirelessly transmit a signal to an access point 132 associated with space 220.
Furthermore, any of the motion, presence, proximity, etc., sensors may be mounted as at 115 in
Referring again to
Any of the conditions or circumstances identified using images from one or a plurality of cameras within the space can be used as a trigger for a specific space experience or for a space experience to transition from one phase to a next sequential phase. In
Use of a video conferencing camera may be particularly useful where the space 220 is relatively small so that the cameras 280 is capable of obtaining images of a relatively large portion of the space 220. In at least some cases camera 280 may have an adjustable/controllable field of view so that, when not being used to facilitate a video conference, the camera's field of view can be expanded to obtain images corresponding to a relatively large portion of the space area. Then, during a video conferencing session, the camera's field of view may be altered and optimized to obtain images of a conferee using the space 220.
The video conferencing camera may also be located in a position to view the usable space with high definition (e.g., generating high definition images). The camera may be able to generate images useable by a processor running a face recognition program to determine the identity of a user within a space. This could in turn be used to adjust the affordances in accordance with the particular preferences of the user. In addition to identifying a user via facial features, other biometric information may be sensed via other types of features including an eye scanning sensor, a finger print reader, etc.
Referring again to
Referring to
Lighting devices 180 are similar to devices 178 and therefore, in at least some cases, will include RGB LEDs and other structure for generating various lighting effects to facilitate various space experiences. Referring to
Lighting device 182 is a light panel that, when illuminated, effectively glows as it emits light to one side of the device structure. This type of lighting device is generally described in U.S. patent application Ser. No. 13/913,254 titled “Panel Light Assembly” which was filed on Jun. 7, 2013 and which is incorporated herein in its entirety by reference. The basic structure of light panel 182 is shown in cross section in
Member 304 is a light pipe type member that is defined by edges and that is formed of a generally clear material selected to guide light from the edges while leaking light out surfaces thereof. Light that leaks toward reflector member 302 is reflected back through member 304 and out the front surface thereof. In some embodiments both surfaces of member 304 are polished. In other cases one or both surfaces of member 304 may have some treatment (e.g., mechanical machinations, frosting, etc.) to cause light to disperse there from. LED sub-assemblies 308 are mounted along one, two or each edge of member 308 to direct light there into.
Member 306 is a light transmitting cover member and includes an external surface when mounted that is substantially flush with adjacent surfaces of the frame member 300. Light from member 304 passes through cover member 306 to illuminate a space adjacent thereto.
Referring to
Referring again to
In the case of either of the lighting device 182 and 290 described above, after the device is mounted to a support frame structure, an opaque panel is usually mounted on the opposite side of the frame structure to give a finished appearance.
Referring again to
Referring again to
Referring again to
Yet another configuration where a display screen 200′ is mounted within a wall structure is shown in
In either of the two configurations shown in
Although only a lounge chair 252 and a simple table assembly 250 are shown in
Referring still to
Referring again to
Referring to
Temperature controller 170 uses signals from control system 150 to regulate temperature within space 220. To this end controller may be linked to a space heater and perhaps some type of cooling (e.g., air conditioning) unit associated with space 220. Similarly air circulation controller 172 is used to regulate air circulation within space 220 and may be linked to a fan or the like that is mounted behind a circulation vent (see 254 in
Privacy indicator 204 in at least some embodiments, includes a simple light device that is spatially associated with space 220 and that can indicate when a certain level of privacy can be relied upon. For instance in
Referring again to
While the above system includes a large number of different types of sensors, interface devices and output devices, it should be appreciated that the present disclosure contemplates systems with far fewer devices and sub-systems. For instance, while some embodiments may include dual sided light panels as described with reference to
It has been recognized that different subsets of the above described affordances may facilitate different optimized or enhanced multi-phase space experiences. For instance, in a case where a person intends to use a personal space to rest for a few minutes prior to a next meeting, a properly afforded space may automatically run through a multi-phase space experience to invite the user into the space, transition the user to a rest state, help the user maintain the rest state and help the conferee emerge from the rest state. As another example, in a case where two users intend to use a space to share content from personal portable devices with each other in a dyadic fashion, a properly afforded space may run through a space experience program to invite the users into the space, to help a first user that arrives to prepare for the dyadic session, to transition the users to a dyadic sharing environment where displays can be easily used to facilitate sharing and perhaps some content development and to help the user's transition out of the dyadic environment when the session is completed. Many other sequences
Referring now to
An invite experience should be an experience that indicates that a particular space is available for use and that can be reflected in at least some fashion in each of several different spaces irrespective of the affordances within each space. For instance, where a facility includes thirty separate spaces within a general area that can be used by one person or a small group of persons and where each of the spaces includes at least some light device that is capable of generating various colors of light, a universal invite environment may include generating green colored light using each light device in a space that is capable of generating green light. Thus, where fifteen of the thirty spaces are available for use, a user may simply observe which spaces are generating green light and therefore which spaces are inviting use. Other more complex invite environments are contemplated.
Referring again to
Once a possible interest trigger is identified, control passes to block 438 where server 102 controls the output devices in an associated space to present a “welcome environment” (e.g., a second phase of a space experience). The welcome environment is designed to welcome a user and transition the user to an activity to be performed within the space. While many different welcome environments are contemplated, it is envisioned that the welcome environments associated with different activities to perform within a space will be different depending of the activity to which the space experience is transitioning to. For example, if the activity to be facilitated within a space is a rest or meditation type activity, the welcome environment may be one designed to, in addition to indicating a transition from the invite state, reduce stress and calm the user. For instance, the welcome state may call for the color of the lighting in the space to be changed from the universal green associated with an invite environment to a warm yellow/orange and may cause a relaxing sound track to be faded in at a low volume, may reduce air circulation within the space and may control one or more display screens within the space to present a color output that is similar to the color of the light generated by the lighting devices within the space.
As another example, where the activity to be facilitated includes focused individual work, the welcome environment may first include a change from green to warm yellow/orange light and a city sound track that includes the sounds of a busy street to indicate a transition from the invite state and then the light may slowly fade to extremely bright white light throughout the space 220 and a cool blast of air via the air circulation controller 172 to invigorate the user during a two minute period prior to the focused activity. During the two minute welcome phase the user could stow a bag and/or a garment, get materials out of a bag and set them up on the work surface and get seated in a comfortable position within the space.
As yet one other example, in a case where a space is to be used for dyadic collaboration between two persons, the welcome environment may, in addition to changing from green light to warm yellow/orange, call for turning on displays screens within the space and starting a process designed to enable two persons to share content via those screens. For instance, the process designed to enable sharing may include stepping through a password entry process enabling users in the space to associate their portable devices with the space whereby the system generates a random password which is presented on each screen in the space and each user enters the same password into their portable devices to associate each portable device with the space and hence with the displays mounted within the space 220. In other cases where the system includes hardware controllers like the controllers 410 described above with respect to
Referring again to
If a transition trigger occurs at block 442, server 102 presents an “activity environment” at block 444 that is designed to enhance the specific activity to be facilitated within the space. For instance, where the activity is a rest activity, server 102 may automatically fade to a rainstorm sound track that mimics rain falling on pavement and light thunder noise and may also fade to a dark blue light that pulses along with the sound of the periodic thunder noise. As another instance, where the activity is focused individual work, server 102 may automatically lower the light intensity surrounding a work surface while maintaining high intensity white light on top of the work surface and the sound may fade to a low volume white noise track to drown out any ambient noises proximate the space.
In the case of a dyadic activity, the activity environment may include fading a sound track off and lowering lighting in a space generally while still having area lighting lit up above or proximate conferees in the space.
At block 446 server 102 monitors for a trigger or action that indicates the end of a specific activity or the end of a period assigned to the specific activity. For instance, in the case of a rest activity, the trigger may be the end of a period over which the activity was to occur. Thus, if a rest period or session was to include a total of thirty minutes including a two minute transition in during the welcome phase and a two minute transition out phase near the end of the session, server 102 would be programmed to recognize the end of a 28 minute period as a trigger and, at block 448, would move to block 450 at the end of the period and would present an “emerge environment”.
As another instance, in the case of focused individual work, the trigger may be a conferee standing up within the space and opening the space door 105. In another embodiment the trigger may be a conferee turning off or otherwise disassociating her personal portable device from the space. In still another case the trigger may be 5 minutes prior to a next scheduled time for the space (e.g., prior to the start time of use of the space by another person). Other triggers are contemplated.
In the case of dyadic activities, the trigger may include opening of the space door, one or both of two conferees leaving the space, at least one conferee leaving and remaining out of a space for at least a threshold time period (e.g., five minutes), delinking of portable devices from the space, etc.
Until an end of activity trigger occurs at block 448, control continues to loop back through blocs 440, 442, 444 and 446. Once an end of activity trigger occurs, control passes to block 450 where server 102 controls the space affordances to present an “emerge” environment to indicate the end of an activity period and to help transition a space user out of the space. For instance, in the case of a rest activity within a space, the system may fade lighting up to a bright yellow light that floods the space, present a video of the sun coming up, fade in a morning sounds track including chirping birds and light waves rolling in on a beach, increase air circulation and decrease temperature by a few degrees. In the case of individual focused work, the system may increase area light generally while decreasing intensity of light on a work surface so that the light in an entire space is essentially uniform but at an intensity that is less than optimal for individual focused work, fade in a different sound track and change other environmental characteristics. In the case of dyadic work, in addition to changing lighting, sound, temperature and air circulation characteristics, the system may also facilitate storing of any digitally developed work product by querying conferees if any content (e.g., documents or files opened in the space) should be stored for subsequent use, e-mailed to one or several accounts such as one or more e-mail accounts associated with the conferees in the space, etc.
At block 452, server 102 monitors for an end of space use trigger. The end of space use trigger indicates that the person or persons that were most recently using the space no longer intend to use the space. For instance, an end of space use trigger may include a person leaving the space. In other cases an end of space trigger may require that a person remain outside a space for at least three minutes (e.g., some threshold duration). In other cases an end of space use trigger may require that a person affirmatively disconnect the person's portable device (e.g. a tablet, phone, etc.) from the space and leave the space for at least three minutes. In yet other cases a person may have to leave a larger space such as a building or a floor on a building or a depart on a floor of a building to disassociate from a personal or conference space.
Referring again to
The space experience described above with respect to
In at least some embodiments it is contemplated that different spaces may be fitted out with different affordances that are optimized for different activities. For instance, some spaces may be optimized to facilitate individual rest activities while other spaces may be optimized to facilitate individual focused work and still other spaces may be optimized to facilitate dyadic conferencing activities or video conferencing activities. In these cases, when a user transitions to an activity within the space at block 442 in
In at least some cases it is contemplated that while a space may be optimally designed to facilitate one or another space experience, a user may be able to use the space to facilitate a different space experience, albeit one that is less than optimal given affordances within the space. For instance, where only a first space that is optimized for dyadic activities is available for use at a specific time (e.g., all other spaces are used by others) but a user wants 30 minutes of rest, the user may opt to use the dyadic space for rest. Here, the user would specify a rest activity and server 102 would identify the affordances associated with the dyadic space and present a rest space experience within the dyadic space even though the experience would not be optimized for rest.
Referring now to
Referring to
At block 500 server 102 monitors sensor 472 for an RFID device read. IN
At block 506 server 102 monitors for an end of activity trigger. Here, in at least some embodiments, the end of activity trigger will be the end of a period (e.g., a 30 minute rest period). At block 508, as the end of a period is approaching (e.g., two minutes prior to the end of the period during which the user has reserved the space for), control passes to block 510 where server 102 fades to the emerge environment. In this case the server 102 fades to a warm orange/yellow and fades in the city walk sound track again. This time the warm light may be pulsing and the city walk sound track may fade to a higher volume than presented at block 498. Near the end of the reserved period, the system may identify a next scheduled event for the space user and may generate an audible message to the user indicating the next event. In the alternative, the server may identify two or more events scheduled for the user and present a full or truncated schedule in an audible message. In
At block 512 server 102 monitors for an end of space use trigger. In
As described above, other triggers and phase environments for a rest space experience are contemplated. For instance, the simple door open trigger at block 514 may be replaced by a door open and remains open for at least three minutes trigger if the period during which the space is reserved has not lapsed. As another instance, an RFID read may not be required to kick off a rest activity and closing a door within the rest space 460 may suffice for server 102 to present a rest space experience.
Referring now to
Each of the end walls 536 and 542 is similarly constructed and each includes double sided RGB LED light panels that can be controlled to generate virtually any color light and that shine light to either side thereof when illumination is turned on. Each end wall 536 and 542 forms an egress and includes a sliding glass door 105, 531 that can be opened or closed.
Referring still to
Where each of the lounges 400a and 400b includes control devices like the ones described above with respect to
Referring to
Where one person is using space 960, in most cases it will be advantageous for that person to present content on displays that are opposite that person within space 960 and that face that person. For instance, in
In at least some cases the system server 102 may be programmed to use sensed information from within space 960 to determine user locations and may be programmed to automatically identify optimal emissive surface spaces for use by persons within the space 960 given intended use of the space. For instance, where a single person enters space 960 and closes the door 105, the system may recognize that a single person is in the space 960. Images from one of cameras 116 may be used to sense a person, the location of the person, the juxtaposition of the person within space 960, etc. When the person sits down on the right side of lounge 400a facing screen 200b and has a personal portable computing device (e.g., a tablet), the system may automatically start a process to link the portable device wirelessly to the server 102 to control content on the portion 968 of display 200b aligned with and spaced from the user. Once the portable device is wirelessly linked to the server 102, the server 102 may identify the location of the person on, for instance, the right side portion of lounge 400a and may present content in space 966. To this end, see also
Continuing, if a second person enters space 960 and sits across from the first person on the left section of lounge 400b (see the person 980 in
In some cases first and second person's can present content via the displays 200a and 200b at the same time. For instance, in
Referring to
When a single user requires two adjacent content spaces or each of two persons in space 960 requires a separate content window on one of the space walls, the sizes of the spaces used by each of the persons may again be automatically optimized. For instance, see
Referring again to
Referring yet again to
Referring to
If a second user enters space 530 to confer with the first user, images from cameras 116 may be used to recognize the second person and to present a different space experience or to transition to a different phase in an experience being presented. For instance, where a first user has been using the space 530 to view a document on screen 200b, when the second person enters the space 530, the system may automatically “hide” the document on display 200b and change the lighting in the space so that the lighting is optimized for a two person discussion. Where the second user assumes a seated position facing the first user, the system may control the lighting again to optimize for viewing display screens by dimming light in the walls 536 and 542 and increasing the intensity of light generated by the upwardly directed light fixtures mounted to the tops of bins 274a and 274b. Other changes may include coordinated light color changes and light effects (e.g., pulsing), sound track changes, temperature, air circulation, etc.
Other space affordance packages optimized for specific activities are contemplated. For instance, see
In
In at least some embodiments, as explained above, the characteristics of any space experience of a specific type may all be substantially similar such that, for instance, any rest space experience presents the same phase characteristics to the extent possible given space affordances in specific spaces. To this end, referring again to
For instance, see
Referring still to
Referring yet again to
Again, default preferences are indicated by phantom boxes about specific preferences in column 736. Thus, for instance, the lighting color preference for the welcome phase is “fade to warm orange/yellow”, the lighting effect is “no pulse”, the sound effect is “fade to city walk”, etc.
Some phases may have different subsets of triggers, environmental factors and preferences than others. For instance, see in
In addition to including the experience specifications, database 130 also includes a sub-database 718 that associates different spaces with different default space experiences. Here the default experiences will usually be the experiences for which specific spaces have been optimized. Sub-database 718 includes a space column 716 and a default specification column 714. Column 716 lists each space that is associated with the
Referring again to
It has been recognized that, in at least some cases, a space user will want the ability to customize space experiences during different space sessions. For instance, while a rest space experience may, by default, present blue illumination that pulses with a sound track during the rest activity phase of the experience, a specific user may instead prefer a dark orange non-pulsing illumination during the activity phase. As another instance, the same user may prefer a different sound tract and a higher volume than the default track and volume during the emerge phase of the rest experience.
To accommodate customization of space experiences by specific users, in at least some embodiments a space user may use a computer (e.g., 140 in
In addition or instead of providing users the capability of setting parameters via a computer 140 that is separate from a space, an environment interface may be presented via a space or room controller (e.g., a Room Wizard) that is extremely intuitive and which can be used at the location of a space to set various space experience characteristics during any space session. To this end see the exemplary space controller interface screen shots in
Referring specifically to
When light control icon 774 is selected, the screen shot 770 in
Referring to
Referring to
In other embodiments additional space control icons may be presented within the ribbon of control icons along the bottom edge of the space control interface. For instance, see in
Icon 822 is a notice control icon which can be selected to control electronic notifications such as e-mails, texts, social updates, etc., to a space user during a space experience or during a phase of one of the experiences. For instance, during the activity phase of a rest space experience, a space user likely would not want any electronic notifications/disturbances but the user may want all electronic notifications or updates received during a rest activity to be presented immediately at the end of the rest activity and during the emerge phase of an experience. Icon 822 can be used to control notifications. When icon 822 is selected, screen shot 839 may be presented including notice control icons 840, 842 and 844. Icon 840 can be selected to turn off all electronic notifications to the user in the space. Icon 842 can be used to turn on notifications to the user. Icon 844 can be selected to selectively activate notifications. For instance, a space user may always want to receive notifications from the user's boss regardless of any activity the user is participating in. A set of message senders that are particularly important may be associated with icon 844 in the system database 130 for each system user so that notifications from any of those users are receivable within an associated space while notifications from others are blocked.
When a notice icon is selected from screen shot 839, an indication of the selection is sent to system server 102 which uses the selection to control notice to the user in the space accordingly. Here, server 102 may send wireless signals to user devices within an associated space causing those devices to enter a no notice mode so that those devices do not provide notice during an experience or during one or more phases of an experience. At the end of a no notice phase, all notices received during the no notice phase may be provided as if they were received at that time.
Referring to
In at least some embodiments a space may not include a dedicated space control device like 104. In these cases it is contemplated that the functionality of the space control device 104 described above may be provided via portable user devices like smart phones, tablet computing devices, laptops, etc. Here, for instance, when a user is proximate or within a specific space, the system may enable the user to access a space control program that presents screen shots akin to the screen shots described above with respect to
In at least some embodiments when space characteristics are set via interface screen shot 770, the space characteristics may remain as set during an entire space session. For instance, where light characteristics are set by a user during a welcome phase of a rest experience, the light characteristics may remain set until the end of the rest experience without cycling through different activity and emerge phases. In other embodiments it is contemplated that users will always want an emerge phase to indicate that a session period is nearing an end and to help transition the users out of the space. In these cases, user set light and other characteristics may persist from the time set through the activity phase of a space experience and the emerge phase may always occur per the default settings. In still other cases user light and other characteristic settings may be set only for a specific phase of a space experience and the settings may revert to default settings at the end of a current phase.
It has also been recognized that a space user may perceive that a specific set of space characteristics are optimal for the specific user. For instance, a user may perceive that a specific set of space characteristics set during a rest activity phase of an experience were particularly effective. In this case, instead of requiring the user to remember the settings and reselect the settings the next time the user participates in a rest space experience, the system enables each user to store their preferred and customized settings for any of the space experiences. For instance, a user may customize settings for a rest space experience and each time the user participates in a rest space experience thereafter in any space, the user's preferred phase settings may be replicated automatically. Thus, the next time a user claims or uses a space for a rest experience, the customized experience would be presented without requiring the user to set or select any settings. In this case, for example, a user may use a first space in a first facility for a rest experience on Monday and may use a second space in a second completely different facility for a rest experience on Friday and the same rest experience customized for the specific user may be presented in each space automatically.
To enable a user to save a customized particular type of space experience, referring again to
In at least some embodiments it is contemplated that an invite phase may include different sub-phases to indicate status of a space prior to a user actually assuming control of or claiming the space for a session. For instance, where a first space is scheduled for use at 10 AM, server 102 may be programmed to control lighting in the space to present a standard invite phase (e.g., pulsing green light) within the space until fifteen minutes prior to the scheduled time (e.g., until 9:45 AM) and then the pulsing light may change to steady state green light for the 15 minute period preceding the scheduled use to indicate to perspective user's in the area that the space is only available for a relatively short period. Then, at 10 AM, if no user has assumed control of the space, server 102 may be programmed to start the welcome phase of the scheduled experience by changing the color of light associated with the space to warm orange/yellow, fade in a programmed sound track and adjust other parameters per the experience specification. If no one arrives in and assumes control of the space within a period (e.g., 10 minutes) of the start of the scheduled session, server 102 may perform some automated process designed to free up the space for others to use. In this regard, for instance, at 10:10 AM server 102 may change the space light again to a steady green and may discontinue the sound track. This change of conditions should prompt a user that intends to take control of the space to do so. This intermediate set of conditions may be presented for another short period (e.g., 5 minutes) after which server 102 may revert back to the invite phase so that other users in the area of the space can see that the space is available for use.
In at least some cases where one or more specific users are scheduled to use a specific space during a specific period, if other users are sensed within the space and the specific users are not sensed within the space, server 102 may be programmed to change conditions within the space to indicate that someone else has reserved the space during the period. For instance, where each space user includes a personal RFID badge, smart phone, tablet, or the like from which user identity can be determined, if users other than scheduled users are in a space, the server 102 may cause lighting in the space to turn bright red to indicate that the space is reserved for use by some other user.
While the system described above is described as one wherein invite phases for spaces used for different space experiences are similar (e.g., pulsing green light to invite use), in at least some embodiments the invite phase characteristics of spaces earmarked or optimized for different space experiences may be different so that users searching for specific experiences can fine optimized space for those experiences. For instance, all spaces optimized for facilitating a rest experience may pulse green to invite use while all spaces optimized for individual focused experiences may pulse red and still other spaces optimized for dyadic activities may pulse orange.
In at least some cases it is contemplated that a user that intends to use a space may indicate a specific space experience that the user would like and server 102 may control invite phases to, in effect, highlight spaces that are optimized or that are available for the specific experience. For instance, where there are thirty different spaces in an area and five of those spaces are optimized for rest space experiences, a user may use an application on the user's tablet or smart phone device to indicate that the user want a rest space experience. Upon receiving the request for a rest experience and identifying the location of the user in the general area, server 102 may be programmed to control space affordances only in available spaces optimized for rest experiences to present invite environments. In this case the user can simply walk about the space and identify one of the spaces presenting the invite environment and can assume control or use thereof in the way that is supported by the specific system (e.g., RFID reading, entering the space and closing the door, a verbal command within the space to take control, etc.).
In cases where a space user selects a space experience for a specific space where a different available space is better suited for the experience, server 102 may present an indication that the other space is better suited for the experience. For instance, referring again to
In some cases space experiences may be programmed to mirror the natural light patterns people experience in nature. For instance, at the beginning of a rest period, light may fade from warm orange/yellow to dark blue to mimic the changing from day light to evening light. Here, at the beginning of an emerge phase, light may fade from dark blue to warm orange/yellow to mimic a sun rise. The fading from blue to the warm color may start with one light device and spread throughout a space to further mimic a rising sun. For instance, in a case where all walls that define a space are light emissive, centrally located LEDs along a lower edge of a first wall 466 may be controlled to fade from blue to orange/yellow initially followed by the laterally located LEDs along the lower edge of the first wall 466, followed by LEDs along the lower edge of the other two walls (e.g., 464) adjacent first wall 466 and that are near the side edges of the other two walls adjacent wall 466 and then followed by the LEDs in wall 462.
As another instance, where a space include light emissive walls as well as a central globe type light device 193 as in
In still other cases where a space includes a display screen 200 (see again
During any of the experience phases, server 102 may be programmed to detect other intermediate triggers and to present other non-persistent characteristic sets. For instance, during the activity phase of a rest space experience, if a user stands up in an associated space (e.g., to get something out of a book bag), images from a camera in the space may be examined to determine that the user is standing and server 102 may control the space affordances in a way designed to help the user. For example, when the user stands, server 102 may change lighting of at least a subset of light devices within the space to help the user see within the relatively dark space. As another example, during individual focus activity where light is bright on a work surface but dimmed throughout the rest of a space, server 102 may increase the intensity of ambient light generally in the space if the user stands up, if a second person enters the space or if a door to the space is opened. In either of the above cases, if the intermediate condition ceases (e.g., the user sits down, the second person leaves the space, etc.), server 102 control may revert back to the phase characteristics specified for a specific space and/or a specific user.
While at least some embodiments of the present disclosure contemplate essentially completely automatic systems where space experiences are presented with little or no specific controlling activities by a user, in other cases more specific controlling actions may also operate as triggers for experiences, phase changes, etc. To this end, referring again to
While the systems described above include speakers, microphones and, in some cases, space control devices 104, in at least some other embodiments a smart phone, tablet type computing device, etc., may be used to provide those components. For instance, once a space user's personal device (see 600 in
Referring again to
In at least some cases panel light devices may be replaced by display screens that can generate virtually any light color.
In some cases a welcome phase may include playing an audible welcome message to a user in a space or presenting a welcome message via a display screen if one exists within the space. The welcome message may also invite the user to take some other action to transition to the experience to be facilitated within the space. For instance, in some cases the system may require a user to place an RFID card or other device within the reading range of an RFID reader device (see 108 in
It should be appreciated from the above description that environmental factors or conditions may be controlled as a function of various factors and inputs, some being simple actions or activities that are not dedicated to initiating control but that are used as proxies to start some control action and others that are specifically dedicated to initiating control. For instance, presence of a personal portable device within a space may operate as a control trigger in some cases while in other cases some dedicated action may be required to initiate a control activity.
While the invention may be susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and have been described in detail herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Thus, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the following appended claims.
This application is a continuation application of U.S. patent application Ser. No. 16/041,199 filed on Jul. 20, 2018, which is a continuation application of U.S. patent application Ser. No. 15/458,376 filed Mar. 14, 2017, which is a continuation application of U.S. patent application Ser. No. 15/184,225 filed Jun. 16, 2016, which is a continuation application of U.S. patent application Ser. No. 14/730,996 filed Jun. 4, 2015, which claims the benefit of U.S. Provisional patent application Ser. No. 62/008,283 filed on Jun. 5, 2014, each of which is incorporated herein by reference in its entirety.
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