Patent Publication Number: US-11387004-B2

Title: Standing desk mat

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present application is a continuation-in-part and claims the benefit of U.S. patent application Ser. No. 15/921,846, filed on Mar. 15, 2018, and is incorporated herein by reference in its entirety. 
    
    
     FIELD OF THE DISCLOSURE 
     The present disclosure is generally directed toward sensing electronics and related systems. 
     BACKGROUND 
     A significant upheaval in daily life, including work life, occurred when COVID-19 reached pandemic levels. Reducing person-to-person interactions became paramount in order to reduce the rate of transmission. Workers, such as office workers, who could work from home did so to the extent possible; open floorplan offices were depopulated or emptied entirely. Workers with private offices were able to work while maintaining the prescribed social-distance practices, at least while within their office. Ideally, each worker is provided with a dedicated, single-user, private office. However, such an investment in time, money, and floorspace is beyond the ability of many employers. 
     A consequence of workers that work from home more often, is that dedicated, single-user offices and workspaces are more frequently left empty. Even employers who can provide dedicated offices may be reluctant to do so if a substantial portion of the workforce is working from home. As a result, office spaces are becoming more physically separate (e.g., increased workspace-to-workspace distances, isolated air handling, barriers, etc.), but rather than being dedicated for the sole use of one worker, are shared between a pool of workers. Such measures seek to balance resource utilization with the need to decrease the number physical exposures between the workers, as well as making contagion transmission less likely. Even with such measures, it remains a non-zero possibility that a worker, or other person, will be at a worksite while infected and expose other workers to a contagion. 
     Pressure mats are known systems whereby a component is provided in a deformable body to indicate occupancy or a lack of occupancy. Pressure mats are often utilized in situations where safety is an issue, such as to ensure a worker is standing in a designated location before a machine is enabled to operate. Alternatively, pressure mats are utilized to trigger door openers or other equipment upon detection of an occupant. 
     The use of standing desks continues to increase in popularity. Many organizations utilize wellness managers to promote the health and safety of their workers, which more and more frequently includes the use of standing desks. Wellness managers may have to decide whether purchasing standing desks, or selecting other option, would provide the greatest benefit. For example, wellness managers may know that company-provided gym memberships have a particular utilization rate. Similarly, if sit-stand desks were to be provided to workers, how often and for what duration would they be used in the standing configuration? Without being able to answer that question, wellness managers may select one of the other options and deny their workers the opportunity to improve their wellbeing while they work. 
     Workers, such as in a pilot program, could be asked about their utilization. However, workers may forget or resist additional reporting tasks or, if reported, may or may not accurately report their use. Similarly, a pressure mat may be able to determine that something is on the mat associated with a particular location, however pressure mats may report occupancy when the occupant is a box or leg of a chair. 
     SUMMARY 
     Wellness managers and other personnel responsible for making wellness purchasing decisions may be reluctant to purchase standing desks or sit-stand desks due to a lack of verifiable usage data. In contrast, gym membership utilization can be determined by monitoring equipment use, badge scans, or other well-known means. However, gyms may be intimidating, or their use postponed until “when I have the time,” for many workers. Being able to spend at least a few minutes standing at work may provide benefits to many workers who may otherwise not take advantage of other wellness opportunities or to supplement the activities that they do utilize. As insurance companies, wellness managers, and others incentivize healthful activities, some may be tempted to game the system. For example, a company owned gym may require badge-scans as a means to monitor participation in wellness activities, such as exercising at the gym, but some may be tempted to scan their badge and leave without performing any exercises. Standing versus sitting may be incentivized, however, self-reporting time spent standing may not be an accurate representation of actual time spent standing. A pressure mat may be able to determine that something is on a mat, but if that “something” is a person standing, a wheel of a chair, or a box, requires more than a pressure mat. 
     It is with respect to the above issues and other problems that the embodiments presented herein were contemplated. 
     As an overview, and in one embodiment, a pressure sensing mat (or, more simply, “mat”) is provided. The mat provides data as received from pressure sensing or other sensing components to report data to and/or trigger other systems in response to a particular use. The mat preferably provides comfort and otherwise promotes use, such as for standing upon while a user is at a standing desk or utilizing a sit-stand desk in a standing configuration. 
     In one embodiment, a system is disclosed, comprising: a pressure sensing mat comprising a plurality of sensing portions; a processor; a component configured to communicate with the processor; and wherein the pressure sensing portions provide signals to the processor in accord with a received pressure and location of the pressure on the pressure sensing mat; wherein the processor receives the signals from the plurality of pressure sensing components and further determines an indicia of use and output the indicia of use to the component and wherein the indicia of use comprises an indication of whether the pressure sensing mat is being used by a user that is standing on the pressure sensing mat; and the component provides a first response, when the indicia of use indicates the user is standing and a second response, when the indicia of use does not indicate standing. 
     In another embodiment, a pressure sensing mat is disclosed, comprising: a communication interface to a network; a supporting structure; a pressure sensing component supported by the supporting structure and configured to provide signals in accord with a received pressure and location of the pressure on the pressure sensing mat; a processor to receive the signals from the pressure sensing component and determine an indicia of use, from the signals, and output the indicia of use via the communication interface; and wherein the indicia of use comprises an indication of whether the pressure sensing mat is being used by a user that is standing on the pressure sensing mat. 
     In another embodiment, a method is disclosed, comprising: detecting pressure on a pressure sensing mat; analyzing signals from portions of the pressure sensing mat; outputting, from the pressure sensing mat, indicia of use associated with standing use, upon the analyzed signals indicating the pressure sensing mat is being utilized by a standing user, and non-standing use, upon the analyzed signals indicating the pressure sensing mat is not being utilized by a user while standing; and reporting the indicia to a component. 
     The phrases “at least one,” “one or more,” and “and/or” are open-ended expressions that are both conjunctive and disjunctive in operation. For example, each of the expressions “at least one of A, B, and C,” “at least one of A, B, or C,” “one or more of A, B, and C,” “one or more of A, B, or C,” and “A, B, and/or C” means A alone, B alone, C alone, A and B together, A and C together, B and C together, or A, B, and C together. 
     The term “a” or “an” entity refers to one or more of that entity. As such, the terms “a” (or “an”), “one or more,” and “at least one” can be used interchangeably herein. It is also to be noted that the terms “comprising,” “including,” and “having” can be used interchangeably. 
     The term “automatic” and variations thereof, as used herein, refers to any process or operation done without material human input when the process or operation is performed. However, a process or operation can be automatic, even though performance of the process or operation uses material or immaterial human input, if the input is received before performance of the process or operation. Human input is deemed to be material if such input influences how the process or operation will be performed. Human input that consents to the performance of the process or operation is not deemed to be “material.” 
     The term “computer-readable medium,” as used herein, refers to any tangible storage that participates in providing instructions to a processor for execution. Such a medium may take many forms, including, but not limited to, non-volatile media, volatile media, and transmission media. Non-volatile media includes, for example, NVRAM, or magnetic or optical disks. Volatile media includes dynamic memory, such as main memory. Common forms of computer-readable media include, for example, a floppy disk, a flexible disk, hard disk, magnetic tape, or any other magnetic medium, magneto-optical medium, a CD-ROM, any other optical medium, punch cards, paper tape, any other physical medium with patterns of holes, a RAM, a PROM, an EPROM, a FLASH-EPROM, a solid-state medium like a memory card, any other memory chip or cartridge, or any other medium from which a computer can read. When the computer-readable media is configured as a database, it is to be understood that the database may be any type of database, such as relational, hierarchical, object-oriented, and/or the like. Accordingly, the disclosure is considered to include a tangible storage medium and prior art-recognized equivalents and successor media, in which the software implementations of the present disclosure are stored. 
     While machine-executable instructions may be stored and executed locally to a particular machine (e.g., personal computer, mobile computing device, laptop, etc.), it should be appreciated that the storage of data and/or instructions and/or the execution of at least a portion of the instructions may be provided via connectivity to a remote data storage and/or processing device or collection of devices, commonly known to as “the cloud,” but may include a public, private, dedicated, shared and/or other service bureau, computing service, and/or “server farm.” 
     The terms “determine,” “calculate,” and “compute,” and variations thereof, as used herein, are used interchangeably and include any type of methodology, process, mathematical operation, or technique. 
     The term “module,” as used herein, refers to any known or later-developed hardware, software, firmware, artificial intelligence, fuzzy logic, or combination of hardware and software that is capable of performing the functionality associated with that element. Also, while the disclosure is described in terms of exemplary embodiments, it should be appreciated that other aspects of the disclosure can be separately claimed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The present disclosure is described in conjunction with the appended figures: 
         FIG. 1  depicts a mat in accordance with embodiments of the present disclosure; 
         FIG. 2  depicts the mat comprising a first configuration of sensing components in accordance with embodiments of the present disclosure; 
         FIG. 3  depicts the mat comprising a second configuration of sensing components in accordance with embodiments of the present disclosure; 
         FIG. 4  depicts a first mat usage environment in accordance with embodiments of the present disclosure; 
         FIG. 5  depicts the mat as used in the first mat usage environment in accordance with embodiments of the present disclosure; 
         FIG. 6  depicts a second mat usage environment in accordance with embodiments of the present disclosure; 
         FIG. 7  depicts the mat as used in the second mat usage environment in accordance with embodiments of the present disclosure; 
         FIG. 8  depicts a first system in accordance with embodiments of the present disclosure; 
         FIG. 9  depicts a first process in accordance with embodiments of the present disclosure; 
         FIG. 10  depicts a second process in accordance with embodiments of the present disclosure; 
         FIG. 11  depicts a third process in accordance with embodiments of the present disclosure; 
         FIG. 12  depicts a second system accordance with embodiments of the present disclosure; 
         FIG. 13  depicts a work environment in accordance with embodiments of the present disclosure; and 
         FIG. 14  depicts a fourth process in accordance with embodiments of the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     The ensuing description provides embodiments only and is not intended to limit the scope, applicability, or configuration of the claims. Rather, the ensuing description will provide those skilled in the art with an enabling description for implementing the embodiments. It will be understood that various changes may be made in the function and arrangement of elements without departing from the spirit and scope of the appended claims. 
     Any reference in the description comprising an element number, without a subelement identifier when a subelement identifier exists in the figures, when used in the plural, is intended to reference any two or more elements with a like element number. When such a reference is made in the singular form, it is intended to reference one of the elements with the like element number without limitation to a specific one of the elements. Any explicit usage herein to the contrary or providing further qualification or identification shall take precedence. 
     The exemplary systems and methods of this disclosure will also be described in relation to analysis software, modules, and associated analysis hardware. However, to avoid unnecessarily obscuring the present disclosure, the following description omits well-known structures, components, and devices, which may be omitted from or shown in a simplified form in the figures or otherwise summarized. 
     For purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the present disclosure. It should be appreciated, however, that the present disclosure may be practiced in a variety of ways beyond the specific details set forth herein. 
       FIG. 1  depicts mat  102  in accordance with embodiments of the present disclosure. In one embodiment, mat  102  comprises pressure sensing area  108 . Mat  102  may provide cushioning, ridges, or other physical features to promote comfort and use. Pressure sensing area  108  comprises a plurality of pressure sensing components and/or pressure sensing areas and may utilize communication interface  106  to send and/or receive data to other components, which will be described in greater detail with respect to the embodiments below. In another embodiment, power control component  104  receives electrical power from an electrical plug to a power source and/or battery (not shown). Power control component  104  may comprise a switch to selectively activate/deactivate power consuming components of mat  102 . Power control component  104  may be omitted when electrical power is provided by communication interface  106  (e.g., power-over-ethernet, USB, etc.). 
     In another embodiment communication interface  106  comprises a communication interface for wired and/or wireless communications to other components (e.g., Wi-Fi, Bluetooth, ethernet, USB, near field communications, etc.). Although mat  102  is depicted as rectangular in shape, it should be appreciated that other geometries may be utilized without departing from the scope of the disclosure herein. 
     In another embodiment, mat  102  may perform, at least in part, operations similar to those of a touch pad. For example, a user may provide inputs in the form of a particular gesture, tapping pattern, or touch a particular location within pressure sensing area  108 . Mat  102  may then provide the signals, such as raw signals (e.g., voltage or other reported value from one or more pressure sensing components) and/or a signal providing a determined meaning (e.g., vacant, occupied, standing user, occupied by non-standing user, etc.), to another component. Such signals may indicate distress, comprise an authentication, or initiate a particular operation. For example, a user at a bank may have a particular tapping pattern that indicates distress to alert security personnel, a user may be authorized to omit a conventional password or utilize a simplified password if they perform a certain gesture, such as perform two taps on the left portion of mat  102  and then a sweeping motion to the upper right corner, as a means of authentication. As will be described in more detail with respect to certain embodiments that follow, mat  102  may be utilized with a powered or unpowered sit-stand desk or computer workstation support. Accordingly, tapping a particular “hotspot” of mat  102  or performing a pre-determined gesture may trigger a powered sit-stand desk or support to transition from seated use to standing use or vice versa. Optionally, mat  102  may incorporate one or more of heat, massage, ventilation, haptic feedback, sound, lights, or other input, output, or usability features. 
       FIG. 2  depicts mat  102  comprising a configuration of sensing components  202  in accordance with embodiments of the present disclosure. In one embodiment, sensing components  202  are uniformly provided within pressure sensing area  108 . Each of sensing components  202  provides an output which may be further provided as a raw signal from each component via communication interface  106  and/or aggregated or otherwise processed via processor  204  performing operations to combine, modify, aggregate, or otherwise process the data from one or more of sensing components  202 . In another embodiment, communication interface  106  comprises an output, such as a speaker, LED, haptic, etc. such as may be perceived by a user. In a further embodiment, communication interface  106  may comprise processor  204  performing operations that translates signals received upon ones of sensing components  202  as commands. For example, a particular tapping pattern or a particular gesture traced out by a user&#39;s foot within pressure sensing area  108  may be interpreted as a command input. In another embodiment, processor  204  may detect a failure of one or more of sensing components  202 . For example, one of sensing components  202  may be “stuck” and continuously report a particular pressure. Processor  204  may exclude data from the stuck one of sensing components  202  or provide an alternative value in place of the “stuck” data value, such as duplicating a value of a neighboring one of sensing components  202  or an average or extrapolated value of a plurality of neighboring ones of sensing components  202 . 
     Sensing components  202  are variously embodied. Sensing components  202  may provide a heterogeneous or homogenous collection of types and/or sensitivities for ones of sensing components  202 . Sensing components  202  may comprise pressure sensing (e.g., pneumatic, piezoelectric, etc.), presence (e.g., capacitive, inductive, etc.), and/or obscured (e.g., photosensor, photo transducer. etc.). However, while utilization of sensing components  202  that comprise detecting whether or not ones of sensing components  202  are obscured may be utilized, at least in part, the embodiments herein, unless otherwise specified, are directed to sensing components  202  that provide an output indicating a pressure level, amount, or indicia to a processor, such as processor  204 , or to a processor of a component in communication with mat  102  via communication interface  106 . 
     In another embodiment, mat  102  may be utilized with one or more discrete components to provide additional or alternative physical properties. For example, mat  102  may provide substantially no padding and be attached to a padding component. In another example, mat  102  may be place on top of or underneath a carpet, rug, ridged pad, etc. Accordingly, mat  102  may incorporate a calibration operation. Processor  204  and/or another processor or computing system in communication with mat  102  via communication interface  106  may prompt a user to perform calibration actions (e.g., step on, step off, etc.) and thereby associate signals produced by sensing components  202  with a user or a particular user. Calibration may be prompted periodically or upon sensing an event, such as dissimilar signal from sensing components  202 , such as to determine whether mat  102  is being utilized by a different user or if it has been moved and is now being utilized on a different surface (e.g., carpeted floor to wood floor). A user-event may also prompt calibration. Additionally or alternatively, communication interface  106  may comprise a speaker, LED, or other input-output component to prompt a user to perform calibration activities without requiring another component, such as a computer, smart phone, etc., utilizing an application to communicate with mat  102  via communication interface  106 . 
       FIG. 3  depicts mat  102  comprising a configuration of sensing components  302  in accordance with embodiments of the present disclosure. In one embodiment, sensing components  302  are distributed heterogeneously within pressure sensing area  108 , such as having a greater concentration within areas  304 A-B, such as may be utilized more extensively by a user standing as compared to sensing components  302  outside of areas  304 A-B. As a benefit, pressure sensing area  108  may provide a greater resolution associated with usage as without the need to add excessive sensing components  302  within pressure sensing area  108  that see infrequent or irrelevant usage (e.g., usage while a user transitions to or from standing, but not utilized while standing). It should be appreciated that other distributions may be provided for sensing components  302  without departing from the scope of the disclosure provided. 
       FIG. 4  depicts mat usage environment  400  in accordance with embodiments of the present disclosure. In one embodiment, mat usage environment  400  comprises user  402  seated in chair  404  which is located, partially or entirely, upon mat  102 . User  402  is seated, such as to engage sit-stand desk  412 , comprising support  406 , monitor  408 , and devices placed upon keyboard/mouse tray  410 . Desk  412  may comprise height-adjusting powered legs to elevate the worksurface of desk  412  or be stationary but comprise a height adjusting structure, such as support  406  and monitor  408  and/or keyboard/mouse tray  410  attached to support  406 . Mat  102  may communicate, such as via a wireless connection, to computer  414 . Computer  414  may be a dedicated device solely monitoring mat  102  or a collection thereof for an associated collection of users  402 . In another embodiment, computer  414  may provide a workstation for user  402  and thereby provide other computing and communication services. 
     User  402  and chair  404  contacts mat  102  via a number of points. User  402  would have the bulk of their weight distributed across each of the wheels, pads, or legs of chair  404 . A trivial portion of weight would be provided by the feet of user  402  or other contact points. Accordingly, computer  414  and/or processor  204  may monitor mat  102  by receiving outputs from sensing components  202 ,  302 . 
       FIG. 5  depicts rendering  500  of mat  102  with sensing components  202  in accordance with embodiments of the present disclosure. In one embodiment, sensing components  202  are depicted as different sizes to indicate dissimilar pressure signal outputs, such as those detected when utilized in mat usage environment  400 . For example, chair legs (e.g., contact points of chair  404 ) on mat  102  may cause portion  504  of sensing components  202  to provide greater input values, portion  502  of sensing components  202  may provide an increased output value (less than portion  504 , greater than sensing components  202  not identified as portions  502  or  504 ). Accordingly, processor  204  and/or computer  414  may determine a plurality of contact points exist associated, at least in part, with usage of chair  404 . 
     In other embodiments, chair  404  may comprise one contact geometry (e.g., pedestal), two contact points (e.g., “skid” type chairs), or three or more legs or wheels providing a non-zero number of contact points. Should zero contact points be detected, processor  204  and/or computer  414  may determine mat  102  is unoccupied. Seated humans, such as user  402 , are known to provide a substantially uniform pressure with respect to those contact points accounting for the majority of the weight of user  402  and/or chair  404 . Portion  502 , which accounts for a trivial portion of the weight provided by user  402  in a seated configuration, may vary in terms of position and/or force measured. However, such motion may be discounted for points associated with a below-threshold amount. For example, if portions  502  account for ten pounds, while the aggregate of portion  504  accounts for two-hundred pounds (e.g., weight of user  402  and chair  404 ), processor  204  and/or computer  414  may then conclude portion  502  represent a user not standing (e.g. user  402 ). Additionally, portion  504  may move linearly in unison or rotate around a point upon mat  102 . Based on at least the forgoing, user  402  may be determined to be seated. 
       FIG. 6  depicts mat usage environment  600  in accordance with embodiments of the present disclosure. In one embodiment, user  602  is standing on mat  102  while using sit-stand desk  412  in a standing configuration. Mat  102 , via processor  204  and/or computer  414 , receiving inputs from sensing components  202 . Mat  102  will then determine user  602  is standing. In another embodiment, mat  102 , while in use by standing user  602  may comprise static non-zero readings from a subset of sensing components  202 , such as due to box  604 . 
       FIG. 7  depicts mat  102  with sensing components in accordance with embodiments of the present disclosure. In one embodiment, sensing components  202  are depicted as different sizes to indicate dissimilar pressure signal outputs, such as those detected when utilized in mat usage environment  600 . Portion  702  may result from user  602 , in a standing configuration, and providing pressure to at least a portion of portions  702 A-B. Additionally or alternatively, portion  704  may result from box  604 . It should be appreciated that a portion of a chair (e.g., chair  404 ) or other object may provide inputs resulting in portion  704 . 
     It should also be appreciated that the number and/or distribution of sensing components  202  may be varied as a matter of design choice. As depicted in mat usage environment  700 , user  602  is detected by some, but less than all, sensing components within portions  702 A and  702 B. Had additional sensing components been deployed within portions  702 A and/or  702 B, the geometry may be more foot or shoe-like, however, while denser placement of sensing components  202  may provide for a more precise image or may have other advantages, providing such a high resolution is not a requirement. In one embodiment, imaging provided by sensing components  202  reporting dissimilar pressures may be provided with as few as one of sensing components  202  reporting an additional pressure and one of sensing components  202  reporting an absence of additional pressure. 
       FIG. 8  depicts system  800  in accordance with embodiments of the present disclosure. In one embodiment, mat  102  provides data signals of individual values for one or more sensing components  202  and/or processed values, such as from processor  204 , for one or more sensing components  202 . Data signals may be provided to local workstation  802 , such as utilized by user  402  and/or  602  or a wellness manager or other personnel, which may be a dedicated device only monitoring one or more mats  102  or providing additional functionality (e.g., work processing, spreadsheets, communications, etc.), such as when workstation  802  is embodied as computer  414  in whole or in part. Additionally or alternatively, mat  102  may provide data signals, via network  804 , to one or more of server  806  or database  808 . As a further option, data signals may be provided and/or received from optional devices  810 , which may include server  812  or other components (e.g., controllers, actuators, switches, relays, routers, etc.). In a further embodiment, data signals may utilize workstation  802  to connect to, and communicate via, network  804 . It should be appreciated that additional or fewer components, or different configurations thereof, may be utilized to receive data signals, directly or indirectly and/or raw signals (e.g., readings from ones of sensing components  202 ) or processed data signals, without departing from the scope of the embodiments. Network  804  may comprise wired/wireless networks and may further comprise, in whole or in part, one or more networks such as the Internet, telephony, cellular, ethernet, Wi-Fi, Bluetooth, etc. 
     In one embodiment, data signals are received by a component, such as workstation  802  or other component comprising a data reception interface and/or network interface and at least one processor. Workstation  802 , server  806 , and/or processor  204  may receive data signals and provide additional processing. In one embodiment, workstation  802  determines if mat  102  is occupied or unoccupied. The determination of whether mat  102  is occupied or not is variously embodied and may comprise determining if the aggregate data signals provided by mat  102  indicate a weight that could be a human user. For example, mat  102  may indicate an aggregate detected weight is three pounds and, accordingly, may be due to an object, inaccurate readings from one or more sensing components  202 , or other non-occupied cause. One target environment of mat  102  is for use by adults in the workforce, however, other environments, such as grade schools are also contemplated. As a result, the users of mat  102  may vary greatly in weight. However, certain minimum values, which may be further selected based upon a factory, administrator, or user configuration may be set and, any aggregate weight upon mat  102  that is below such a threshold value will be considered to be absent occupancy. While such a determination may be conclusive of a lack of occupancy, a detected weight above a minimum threshold may be insufficient to conclude occupancy. Accordingly, in additional or alternative embodiments, additional processing may be provided. 
     In another embodiment, sensing components  202  may detect static or dynamic variations in pressure and provide a corresponding output. The timeframe for which a determination of whether or not a data signal output by one or more sensing components  202  is considered static is variously embodied. The timeframe may be dynamically varied depending on the type of variations encountered. For example, a subtle swaying, whereby overall weight remains substantially constant, but increases with regard to sensing components  202  in one portion, such as portion  702 A (e.g., detecting pressure from one foot) while decreasing with regard to sensing components  202  in another portion, such as portion  702 B (e.g., detecting pressure from a different foot). Such subtle swaying may result in a dynamic signal over a short timeframe, such as less than 5 seconds. Additionally, the number of variations may be considered. In another embodiment, occupancy on mat  102  may be discarded entirely if observed for less than another threshold period of time. User  602  may stand on mat  102  for less than five minutes, as an example, and be considered an inconsequential occupancy and discarded as if there were no occupancy at all. Accordingly, outlier pressure readings from any one or combination of sensing components  202  that may indicate occupancy, but only last for less than a minimum threshold of time, such as a few seconds up to a few minutes, may be the result of another object (e.g., an object being dropped on or traversing mat  102 ) or an inconsequential usage of such a short duration that any health benefits gained are so minor than they may be discarded. 
     In another embodiment, the number and size of portions of sensing components  202  reporting pressure indicating occupancy may be evaluated. Humans will generally stand on two feet and produce two distinct portions of sensing components  202  indicating occupancy (e.g., portions  702 A and  702 B). The density of sensing components  202  and/or attribute of a standing user (e.g., standing with feet close together, amputee, etc.) may produce a single contact area. However, sway, aggregate detected weight above a threshold, shuffling, etc. will cause variations in the particular ones of sensing components  202  reporting pressure and/or the amount of pressure detected. Additionally or alternatively, standing user  602  may utilize a can, walker, or other standing device. Much like portion  704  of sensing components  202  reporting occupancy, if static, such as when the cane or walker is freestanding while the user is engaging with standing desk  412  or box  604  produces static portion  704 , such static portions may be omitted from consideration. However, if such portions are not static (e.g., user  602  is utilizing a cane or walker while utilizing desk  412 ) then user  602  may be determined to be standing whether or not two or more portions of contact are detected. 
     However, not all dynamic pressure outputs are associated with standing use of mat  102 . In another embodiment, a portion of sensing components  202  may indicate a path which may terminate, originate, or be maintained on mat  102 . Such a path does not indicate standing use of mat  102  and may be caused a wheel of a chair or other object passing over mat  102 . Accordingly, in another embodiment, dynamic changes in the number or indicated amount of sensing components  202  reporting pressure, when the pressure indicates a traversal path, may be considered a non-standing use of mat  102  and/or traversal by a wheel of a chair or other object. Accordingly, even if the detected object remains on mat  102 , which may further be dynamic, such as when seated user  402  fidgets or provides other oscillations to mat  102  while seated. Therefore, portion  504  of sensing components  202  may be identified, via their traversal, as associated with non-standing use and even subsequent dynamic pressures may be considered a non-standing use. 
     Additionally or alternatively, seated user  402  may place their feet on mat  102  without a chair or other object being on mat  102 . Portion  502  may detect occupancy and/or feet/shoes, such as when the density of sensing components is sufficient to indicate a feet/shoe geometry thereon. However, portion  502  are merely the feet of seated user  402 . Sensing components  202  may indicate an aggregate weight across all sensing components  202  or only sensing components  202  associated with feet (e.g., portions  502 A-B) to determine if a minimum weight is provided to indicate standing at a position associated with portions  502 A-B. Additionally or alternatively, certain sensed activity of portions  502 A-B may indicate a lack of standing. For example, standing user  602 , even if swaying, jumping, etc. will provide an aggregate pressure indicating their weight when measured over a relatively short period of time as even a user jumping or otherwise moving on mat  102 . Similarly, a swaying standing user  602  may reduce pressure on one foot while the add it to the other. A front-back sway can similarly be determined to be standing as pressure within a portion (e.g., portion  702 A) will remain constant on the aggregate as individual sensing components  202  detect the variations within. 
     In contrast, seated user  402  may lift or otherwise shift their weight from of one foot without adding the corresponding decrease to the other foot. A feat that can be performed over a very short time (e.g., jumping, falling, etc.) by standing user  602  or routinely and/or indefinitely by seated user  402 . If outlying observations are ignored, such as those occurring a single time and/or for a short duration (e.g., one minute, a few seconds or less) then user  602 , even if falling or jumping may be determined to be standing while the reoccurrence of such observations for seated user  402  may indicate seated use of mat  102  and/or an absence of standing use of mat  102 . 
     With usage of mat  102  determined (i.e., standing use or seated use) by workstation  802 , server  806 , and/or processor  204 , additional operations may then be performed. In one embodiment, identification of a particular user may be provided. Profile information may be maintained, such as in database  808  or a memory associated with processor  204 , computer  414 , and/or workstation  802 . Profile information may include information such as time/day of use and/or attributes of a particular user (e.g., weight, sway pattern, etc.). Accordingly, sensing components  202  may determine a particular pattern and/or amount of aggregate and/or individual pressure, oscillations, etc. and determine the identity of a user. However, conventional identification (e.g., sign-in, badge swipe, etc.) may be utilized as an alternate or additional means of authentication, such as to provide a more secure and/or more certain identification of a specific user. 
     In another embodiment, data recording may indicate utilization of standing to indicate use of a desk  412  in a standing configuration over one or more periods of time. For example, use of a particular asset (e.g., sit-stand desk  412 ) may be utilized in a standing configuration 39% of the time in the last month, 31% of the time the previous month, etc. User  602  stood for 29 hours last week, 35 hours the week before, etc. While data gathering and reporting are useful, other operations may be provided once it is known whether mat  102  is occupied and/or occupied in either for standing use or seated use. 
     In another embodiment, any occupancy of mat  102  may be utilized as a trigger to other systems or components. In other embodiments, occupancy in one of seated or standing or a transition (e.g., seated to standing, standing to seated, vacant to occupied, vacant to seated and/or standing, occupied to vacant, etc.) may be utilized as the trigger. For example, detecting a transition from unoccupied to occupied may signal optional devices  810 , when embodied as heat, cooling, fan, lighting, etc., to operate in accordance with an occupied area. Similarly, a transition to unoccupied may cause optional devices to transition to an unoccupied mode of operation (e.g., turn off some or all lights, reduce heating/cooling, etc.). Computer  414  and may be configured to, at least partially, operate differently whether utilized by a standing or seated user as well as perform operations for a transition. For example, computer  414  may detect a transition from occupied to unoccupied and lock, enter a low-power mode, or other operation associated with an absence of a user. 
     Conversely, transitioning from an unoccupied to an occupied state may “wake” computer  414 , such as to terminate a low-power mode of operation or perform other operation more conducive to being utilized rather than being unused by a user. Furthermore, knowledge of a specific user, either by identifying attribute (e.g., sign-in, weight, etc.) or by estimation (e.g., last user) may cause computer  414  to perform certain operations with such knowledge or assumed knowledge. For example, the user who comes in at 8:00 AM Monday-Friday typically uses sit-stand desk  412  in a standing configuration, therefore, when occupancy upon mat  102  is detected at 7:53 AM on a Tuesday, computer  414  which may further comprise a controller for support  406  and/or powered height-variable legs of desk, such as an actuator (not shown) of desk  412 , to cause the worksurface to raise or otherwise accommodate standing use without requiring any further input or action to adjust the desk. Similarly, if a user is determined to utilize desk  412  in a seated configuration at 1:00 Monday-Friday, then support  406  and/or powered legs of desk  412  may lower to accommodate seated use when occupancy is detected at 1:09 AM on a Wednesday or alternatively lowered following detecting a transition to an unoccupied state of mat  102  at 12:03 PM (e.g., the user went to lunch and historically works in a seated position following lunch). As can be appreciated, a detected event, such as a transition from occupied to unoccupied or vice versa, may not trigger any action unless it occurs at a specific time or within a particular time window. Additionally, the time or time window may be provided or learned, such as the occurrence of a manual transition (e.g., raising or lowering) that occurs over many observations to develop a probability curve. A particular probably threshold may then be utilized, such as a user who starts work at 8:00 AM, and has a two-standard deviation time window that covers 7:43 to 8:21 and may be considered to be the trigger. However, anything outside of that time window may have a probability that may or may not indicate a particular usage and, accordingly, disabled. For example, a user&#39;s workstation may be available to any user if the assigned user does not show up by 8:30 AM. 
     In another embodiment, a request (manual or automated) to transition desk  412  from standing use to sitting use, or vice versa, may signal computer  414 , such as when mounted to support  406  and/or comprising monitor  408 , to alter its operations accordingly. For example, users generally are farther away from monitor  408 , when standing, as compared to when seated. Accordingly, transitioning from seated to standing configuration may cause computer  414  to enlarge the text or other display components presented on monitor  408  or, when transitioning to seated, reduce the size of text or other visual components. A computer mouse, keyboard, or other motion sensitive component may then operate at a reduced sensitivity to accommodate a user standing as compared to seated. 
     In another embodiment, workstation  802  may comprise a processor executing instructions that time a user&#39;s mode of operation and provide alerts and/or automatic actions. For example, user  402  may have been seated for three hours and, in response, workstation  802 , when embodied as computer  414 , may present a pop-up message on monitor  408 , send a text message, or send other communication to user  402  to prompt user  402  to transition to standing. Similarly, a user may “overdue it” if they stand to long and similar alerts may be provided to users who stand beyond a threshold duration. Additionally or alternatively, desk  412  may automatically transition from one mode of use to the other based on time of day, day of week, duration of usage in one mode, aggregate duration over two or more days in one mode, etc. 
     Mat  102  may be utilized at a dedicated workstation for a particular user. Accordingly, in certain embodiments, mat  102  may assume use thereof is use by the particular user. In other embodiments, mat  102  may be utilized in a shared workspace, such as a conference room or in close proximity to one or more other mats  102 . As a result, associating a user with a specific one of mat  102  may be necessary. When communication interface  106  is a wired connection to workstation  802  a user may be identified via sign-in on an application executed on workstation  802 . When communication interface  106  is a wireless connection to workstation  802  or workstation  802  is not paired with mat  102 , a user may be prompted to identify themselves. For example, one of a plurality of mats  102  may issue a prompt a user to step off then back on. The prompt may be on a specific one of workstations  802  utilized by a known user. If the user complies, then workstation  802  may identify the particular one of mats  102  being utilized by a particular user. Tapping, swiping, or other motions, which may be required to be performed within a particular time window, may be utilized to identify a particular user. An application, such as one executing on server  806 , workstation  802 , or processor  204  of a designated mat  102  may coordinate authentication/identification so that no two mats  102  request the same authentication/identification activity or, if the same activity is requested, different timeframes are utilized. 
       FIG. 9  depicts process  900  in accordance with embodiments of the present disclosure. In one embodiment, step  904  detects occupancy. Step  904  may detect a lack of any sensed pressure, or a detected pressure below a previously determined threshold, on mat  102  as an absence of occupancy. Test  906 , in conjunction with the operations of step  904 , then response according to whether occupancy is or is not detected. If test  906  is determined in the negative, process  900  may continue back to step  904  to continue monitoring for occupancy. Optionally, step  902  may initiate or maintain a lower-power mode (e.g., sleep, power-off, etc.) in response to test  906  being determined in the negative. If test  906  is determined in the affirmative, processing may continue to test  910 . Optionally, step  908  may initiate or maintain a wake state (e.g., full power). Step  902  and/or test  910  may manage the power utilization of mat  102  or another component, such as computer  414 , workstation  802 , optional devices  810 , etc. 
     Next, test  910  may identify whether occupancy is caused by a human or non-human (e.g., leg or wheel of a chair, box, etc.). Test  910  may determine that there is a periodic motion, such as a sway, that is associated with human use. Other motions, such as sliding, tapping, etc. may also be associated with a human. Static pressure readings (e.g., no variation over a previously determined period of time) for all or a portion of non-zero pressure readings for a particular portion of mat  102  (e.g., portion  704 ), may indicate a “stuck” sensor or a non-human object (e.g., box, leg of a chair, etc.). Accordingly, test  910  may consider such points as non-human and eliminated from further consideration. If no points then remain, test  910  may be determined in the negative. However, if at least one point or portion of non-zero pressure indicates a sway, shift, or other motion associated with a human, test  910  may be determined in the affirmative. 
     Optionally, step  912  may identify a particular user. A database, such as database  808  or other data storage, may comprise records associating a particular pressure pattern observed by mat  102  with a known user. A known user may be expressly identified (e.g., “John Smith”) via login or other data entry means or categorized (e.g., the same user as yesterday, a user different from the previous user, a user different from “John Smith,” etc.). Accordingly, if a recognized pressure pattern is encountered, the user may be identified and an action perform in accordance with the user (e.g., place the height of desk  412  at the configured height desired by the identified user, cause a computer to load an associated profile, etc.). 
     Test  914  determines if the usage of mat  102  is a standing usage or a non-standing usage. Test  914  may determine if portions of pressure on mat  102  that have non-static values (e.g., portions  702 ) have at least a minimum threshold aggregate weight, position, variations, etc. that indicate a user is standing on mat  102  and, thereby, cause test  914  to be determined in the affirmative. Optionally, test  914  may determine whether the usage is a seated usage. For example, if dynamic portions (e.g., portions  502 ) fail to provide an aggregated weight associated with a user or a usage pattern that indicates seated use (e.g., one portion, such as portions  502 A, may be decreased without a corresponding increase in another portion, such as portions  502 B, or an corresponding increase in more than two points, such as portions  504 ). If test  914  is determined in the affirmative, process  900  may then continue to step  916  whereby the user may be reported as standing. Step  916  may comprise updating a record, terminating a “time seated” timer, signaling a component to alter operations (e.g., raise desk  412  for standing use, etc.). 
     If test  914  is determined in the negative, process  900  may then continue to step  918  whereby the user is reported as seated. Step  918  may comprise updating a record of time spent seated, start or continue a “time seated” timer, signal a component to alter operation (e.g., lower desk  412  for seated use, etc.). In another embodiment, test  920  determines if the “time seated” exceeds a previously determined threshold. If no, process  900  may continue back to test  914 . If test  920  is determinized in the affirmative, step  922  may imitate a signal. The signal may be a message sent to a user (e.g., pop-up message on computer  414 , text message, vibration on mat  102 , update record, etc.). It should be appreciated that other embodiments, such as resuming process  900  at step  904  and/or test  910 , another point may be provided, such as when test  920  is determined in the negative or following step  922 , without departing from the scope of the embodiments. As a further option, time or duration spent seated or standing may be reported and utilized for various triggers, such as a congratulatory notification upon standing for a previously determined duration or having stood for at least a particular number of times in given day, week, etc. Process  900  may operate intermittently, periodically, and/or continually 
       FIG. 10  depicts process  1000  which may comprise, in whole or in part, step of test  914  to determine if a user is standing in accordance with embodiments of the present disclosure. As a further option, process  1000  may comprise additional or alternative steps otherwise provided in process  900 . In one embodiment, step  1002  receives signals indicating pressure and/or location of pressure from mat  102 . Next, test  1004  determines that mat  102  comprises at least one portion providing dynamic values. It should be appreciated that the timeframe to determine whether or not a value is dynamic may be selected in accordance with human physiology and what may be utilized to determine a human stance. For example, small motions of a human standing stationary may be detected over a period of a few seconds or less, such as five or ten seconds. A human in a more normal mode, may impart variations observed on mat  102  within one second or less. A pressure sensing area that is entirely static for a longer period of time one minute or more may be determined to be non-human (e.g., box, chair leg, etc.). As a human may occupy mat  102  along with a non-human object (e.g., user standing while a box also rests on mat  102 ), only dynamically varying portions may be considered further for human occupancy and/or sitting/standing determinations. If test  1004  determines there is not at least one dynamic portion, test  1004  may be determined in the negative and step  1008  determines use is a non-standing use. Step  1008  may further consider the use to be non-use (e.g., lack of occupancy) or static use (e.g., presence of an inanimate object on mat  102 ). If test  1004  is determined in the affirmative, step  1012  may then be executed. Optionally, test  1006  and step  1010  may be performed. Test  1006  determines if there is a static portion in addition to the at least one dynamic portion. If no, processing may continue to step  1012 . If test  1006  is determined in the affirmative, step  1010  may report the object to a user, maintenance personnel, or other system or component, such as to indicate a defect (e.g., “stuck” pressure sensing component) or misuse (e.g., chair or table leg on mat  102 ). Following step  1010 , processing may resume at step  1012 . 
     Step  1012  comprises one or more criteria  1018  utilized to determine if a user is standing or not standing or, additionally or alternatively, seated. Certain criteria  1018  may provide a conclusive determination, such as to override or omit other criteria  1018 . For example, criterion  1018 C registers only a few pounds that varies to zero—associated with a seated user lifting their foot. Other criteria  1018  may provide support or a lack of support for a particular determination provided by other criteria  1018 . For example, criterion  1018 A may indicate a foot or shoe-like geometry is pressing on mat  102 . However, as feet and shoes vary considerably in their size and geometry (e.g., high-heals versus running shoes versus dress shoes, etc.), such a determination may not be conclusive. However, if criterion  1018 B indicates a sway associated with a human standing, the determination may be more certain. Conversely, if criteria  1018  indicates no sway or a weight not associated with a human occupant on mat  102  (e.g., a user left their shoes on the mat), then the confidence that a user is standing may be less certain or discounted entirely. Step  1012  then utilizes the one or more criteria  1018  to determine whether the user is standing, and thereby executing step  1014 , or not-standing, and thereby executing step  1016 . Steps  1014  and  1016  may cause a component to perform a particular operation, such as raise/lower desk  412 , cause workstation  802  to operate in a mode for seated use (e.g., smaller font, accept fine inputs on a mouse or other tactile input component) or standing use (e.g., larger font, ignore fine inputs and only consider coarser inputs on a mouse or other tactile input component). 
     Criteria  1018  is variously embodied and may include criteria  1018 A-D, such as to evaluate wither a foot or shoe-like geometry is detected, sway is detected, a mean weight of dynamic portions is substantially constant, a foot or shoe-like traversal, etc.). It should be appreciated that other criteria may also be implemented. For example, criterion  1018 D determines if a sensed portion on mat  102  is foot-like. For example, a linear or curvilinear path may be indicative of a wheel of a chair and, therefore, not a standing user at least with regard to the sensed portion. However, if a sensed portion of mat  102  indicates a user stepping onto mat  102 , then the user is, or is likely, standing. In another embodiment, timing or duration is considered. For example, an indication of seated use, when previously determined to be a standing use, or vice versa that lasts for less than three seconds, may be ignored as an anomaly. The specific duration may be selected in accordance with learned behaviors or previously determined threshold values to balance responsiveness with the duration of anomalies. 
       FIG. 11  depicts process of step  912  in accordance with embodiments of the present disclosure. Step  912  may be executed to determine the identity of a particular human occupant on mat  102 . In one embodiment, each of steps  1102  and  1104  are executed. Step  1102  accesses a record associated with a particular pressure pattern observed on mat  102 . Step  1104  accesses an identifier of users and associated recorded pressure patterns. Test  1106  determines if the observed pressure pattern matches one of the recorded pressure patterns. If test  1106  is determined in the negative, step  1108  is executed whereby operation of mat  102  and/or associated components is performed in a mode associated with an unknown user, such as to prompt the user to sign-in, or otherwise identify themselves, or to operate in an anonymous user-mode. If test  1106  is determined in the affirmative, step  1110  the operation of mat  102  and/or associated components is performed in a mode associated with the identified user, such as to cause a component to be configured in accordance with a setting for the known user. 
       FIG. 12  depicts system  1200  in accordance with embodiments of the present disclosure. In one embodiment, mat  102  identifies a user of mat  102 . In one embodiment, use of mat  102  comprises standing on mat  102  by the user. In another embodiment, use of mat  102  comprises siting on a chair that, in whole or in part, rests on mat  102 . In yet another embodiment, use of mat  102  comprises being proximate to mat  102 , such as to be identified (as described herein) by mat  102  and/or the user, such as by communication device  1206 , identifying mat  102 . Use of mat  102  may be intermittent. For example, a user may be on, and then off, a number of times within a relatively short period of time (e.g., within a work shift) such as may be characteristic of a user working at workspace having mat  102 , and standing/siting thereon, and leaving mat  102  to tend to other tasks. 
     Use of mat  102  may be, or is expected to be, limited to a single individual, one of a finite set of individuals (e.g., workers who are authorized to access a workspace having mat  102 ), semi-private (e.g., any user who is in a school, a guest of a hotel, within an airport lounge, etc.), or public (e.g., anyone who decides to enter a public library or other public space, such as a shopping center, public area of an airport, etc.). In other embodiments, it may be important to identify who is not the user of mat  102 . For example, if a workspace having may  102  is utilized by an infected user, another user who is known to be elsewhere when the contagion may be transmitted, may be eliminated and resources directed to contact tracing those what could have been exposed or who cannot be eliminated from a pool of potentially exposed individuals. 
     Exposure, or potential exposure, to contagion may be limited to known transmission pathways for a particular contagion. If a pathogen is viable on a surface (e.g., doorknob, break room surfaces, etc.) for a period of time, then any individual who interacts with such a surface, within the period of time the surface was visited by an infected person, may be considered to be exposed and potentially infected. However, if the contagion is considered to be only spread when people are closer than a particular distance, then only individuals who got closer to an infected (or suspected infected) individual may be considered to be exposed. Conversely, individuals who never got closer than the particular distance (or second distance greater than the particular distance) may be considered to be not exposed. 
     In order to facilitate contact tracing of infected (or suspected infected) individuals and other parties, mat  102  and systems comprising mat  102  may be utilized to identify persons involved in a potential transmission and/or eliminate individuals who are determined to not be involved in a potential transmission. Accordingly, and in one embodiment, a user of mat  102  may be determined. Mat  102  comprises communication interface  106 . In one embodiment, communication interface  106  further comprises radio frequency signal  1204 , such as Bluetooth, near-field communications (NFC), cellular, WiFi, and/or other radio signal comprising an encoded identification of mat  102  and/or identification of a communication device, such as communication device  1206 , when within communication range of each other. Additionally or alternatively, mat  102  may comprise visual identifier  1202 . Visual identifier  1202  may be a QR code, bar code, Snaptag, Microsoft tag, etc. that, when captured by a camera (not shown) of communication device  1206  associated with a user, wherein communication device  1206  communicates with mat  102  and/or server  1208 , to pair mat  102  with communication device  1206 . The pairing may exist until a de-pairing event occurs, such as mat  102  becomes idle for a previously determined period of time, communication device  1206  becomes paired with a different mat  102  and/or a component at a different location from mat  102 , communication device  1206  is no longer in communication with mat  102 , and/or a different communication device (associated with a different user) is paired with mat  102 . Server  1208  may be a dedicated server to one or a plurality of mats  102 , general purpose server, networked server, public shared appliance (e.g., “cloud” server) connected to mat  102  and/or communication device  1206  via private network and network connectivity (e.g., Ethernet, WiFi, Bluetooth, etc.), public network (e.g., Internet), or a combination thereof. 
     In another embodiment, pairing of mat  102  with a user may be provided by accessing a computer or other sign-in device proximate to mat  102 . Additionally or alternatively, communication device  1206  may scan a visual code and/or radio frequency paring with a different component physically proximate to mat  102 . For example, a keycard may be utilized to unlock a computer (not shown) or access other resource. The computer and/or resource may then communicate via communication interface  106  of mat  102  and vice versa. A sign-on and/or pairing may perform other actions, such as setting a workstation, utilized with mat  102 , to a user&#39;s preference (e.g., raising/lowering the height of a worksurface, monitor, keyboard, etc., setting lighting, heating/cooling, and/or other environmental controls, routing telephone communications to a telephony endpoint near the workstation, etc.). 
     While pairing of communication device  1206 , which is personal and specific to a user, with mat  102  provides one means to specifically identify an individual user of mat  102  and/or to eliminate other potential users from consideration while utilized by the identified user. In another embodiment, a user may be identified from biometrics provided by the user&#39;s current and/or past interactions with mat  102 . For example, a user of mat  102  may have an overall weight, standing pattern, shifting pattern (e.g., shifting from one foot to the other while standing, shifting weight from one part of a foot/feet while standing), tapping, and/or other motions. Such a user, even if not specifically known, may provide identifying attributes of the user or, to a subset of users. A data storage of mat  102  and/or server  1208  may maintain records of use for a number of users and their biometric patters. Accordingly, at the time of a potential transmission of a contagion, a user engaged with mat  102  may have a biometric pattern matching, or sufficiently matching, the user of mat  102  and/or a different mat, at a prior time. Accordingly, the user at the time of potential transmission can be identified as also being a user of mat  102  (or a different mat) at a prior time to further eliminate unknown candidates as the user and/or identify the user. Biometric patters may also be determined from a pattern of use. For example, a user who routinely needs to step away from their workstation would have a pattern of being on and off mat  102 . Accordingly, an unidentified user that has the same pattern of being on and off map  102  may be, or be considered a candidate match. Similarly, a user&#39;s who, once on mat  102 , is rarely or has limited periods of being off mat  102  and may be excluded as matching the current user. 
       FIG. 13  depicts work environment  1300  in accordance with embodiments of the present disclosure. In one embodiment, work environment  1300  comprises work areas  1302 . Work areas  1302  may further comprise similar or dissimilar collection of furniture and equipment, such as work surface  1304 , work surface  1306 , keyboard  1308 , monitor  1310 , and chair  1312 . In one embodiment, work area  1302 A has therein mat  102 A and work area  1302 B has therein mat  102 B. In one embodiment, work areas  1302  are private offices where interaction between occupants while in each of work area  1302 A and  1302 B, is minimal (assuming proper ventilation ducting of work areas  1302 ). 
     In one embodiment, work areas  1302  are separated by no or partial walls (e.g., cubical partitions) where interaction between occupants while in each of work area  1302 A and  1302 B, is potentially sufficient to transmit a contagion. For example, a user of mat  102  while standing may be more likely to expose, or be exposed, to a contagion present in a current or recent user of work area  1302 B. Accordingly, if a user of work area  1302 A may be considered too far to transmit a contagion to a user of work area  1302 B if seated substantially all of the time, but close enough to transmit the contagion if standing. The distance may be reduced further if each of the users, of work area  1302 A and  1302 B, are both using mat  102 A and  102 B, respectively, while standing. Seated use of mat  102 A and/or  102 B may be determined by a pressure pattern and or wheel tracking patterns of legs or wheels of chair  1312 A and/or  1312 B, respectively, on mat  102 A and/or  102 B, also respectively. 
     Mat  102 A and/or mat  102 B may be proximate to other people, such as user  1320  in hallway  1318 . User  1320  may carry communication device  1322 . As such mat  102 A and/or mat  102 B may detect the passage of user  1320  via radio frequency signals, including but not limited to, Bluetooth. Accordingly, if a user of work area  1302 A,  1302 B, or user  1320  is identified as infected with a contagion, mat  102 A, mat  102 B, and/or server (e.g., server  1208  in communication with mat  102 A and  102 B) may have a record of the encounter and those in proximity to the infected person for a period of time—such as a period of time the contagion is considered to be a viable outside of an infected person. 
     In another embodiment, the use of mat  102  by an infected person may require prompt action to hinder further spreading of the contagion. For example, mat  102 A and  102 B may be available on a first-come basis. Accordingly, display, such as display  1324 , may be integrated into mat  102 B, for example. If work area  1302 B is available the message may be a welcome message (e.g., “Sign-in to get started,” “Welcome Hotel Guest,” “Work area available,” etc.). However, if mat  102 B is determined to be unsafe, such as due to a potential exposure to a contagion, display  1324  may provide a notification message, such as “Keep Out!”, until such time as work area  1302 B (and any additional areas) are sanitized or otherwise deemed safe for use (e.g., the suspected infected user was subsequently determined not to have the contagion). In another embodiment, notification to an access control system (e.g., electromechanical lock, badge/card reader, biometric reader, etc.) may be notified and automatically restrict access to an area suspected of having an active contagion. In yet another further embodiment, users currently at a location that is deemed at-risk for the contagion may be provided with an automatic notification to leave and/or have components disabled (e.g., a computer or other equipment utilized within work area  1302 A and/or  1302 B may be locked or powered off in response to a signal from mat  102 A,  102 B, and/or server  1208  in communication with mat  102 A and/or  102 B and the respective external device (e.g., security system, display, access control system, etc.). 
       FIG. 14  depicts process  1400  in accordance with embodiments of the present disclosure. Process  1400  may be executed as machine-readable instructions for execution of a processor, such as a processor of mat  102 , server  1208 , and/or other electronic processing device. It should be apparent to those of ordinary skill in the art that certain steps of process  1400  may be performed in the order illustrated or, in other embodiments, a different order. 
     In step  1402  a first person is identified, such as by methods and systems described elsewhere herein. Step  1402  may comprise the identification of a specific individual, such as by entering an identification number, swiping or scanning an access badge or card, entering a username and/or password into a computing system, etc. The component or system utilized to receive the identification may then interface with mat  102  and/or server  1208  to maintain a record in a data storage memorializing the usage. 
     In another embodiment, step  1402  may identify a characteristic of the first person, such as via a biometric indicator or pattern, such as an overall weight as observed by mat  102 , a pattern of standing (e.g., shifting weight, tapping, etc.), foot/shoe size, frequency/pattern of getting on and off the mat, etc. Step  1402  may attempt to identify the person the first person by matching a data record maintained in a data storage device of, or accessible to, mat  102  and/or server  1208 . If a match to another record is determined, the other record may provide a specific identification of the user (e.g., a prior usage of mat  102  where they explicitly identified themself) or, at least, the knowledge that the user was also utilizing mat  102  at the prior time. It should be appreciated that a prior usage of mat  102  may be the same or a different mat. 
     In another embodiment, step  1402  may identify a user that is proximate to mat  102  without actually utilizing mat  102 , such as a passerby who was able to be identified via a Bluetooth or other radio frequency signal. 
     Similarly, step  1404  identifies an encounter with a second person, such as by methods and systems described elsewhere herein. The encounter may be a “live” encounter, such as when two people are having a face-to-face conversation; a proximity encounter, such as when two people are generally in the same area at the same time; and/or an indirect encounter, such as when two people occupy generally the same space but at a different time, however the time difference is sufficient to enable transfer of a contagion from the first person to the second person or vice versa. 
     Step  1406  receives indicia of an infected person. In one embodiment, the indicia identifies a specific individual (e.g., name, user name, member number, etc.). Accordingly, step  1406  may determine what, if any, mat  102  and/or other locations or equipment may be impacted. In another embodiment, a data storage comprising biometric patterns of usage for one or more mats  102  may be accessed. For example, if the infected person is a known user of mat(s)  102 , then records in a database having the biometric records of the infected user may be identified, such as with records of non-specifically identified individuals. Accordingly, if a match is discovered, then then infected person may be determined to have utilized a particular mat(s)  102 . 
     In another embodiment, a “best match” may be performed, such as to eliminate users of mat(s)  102  that are definitively not the infected person and/or to identify users of mat(s)  102  that are or are sufficiently likely to be the infected person. 
     Test  1408  determines if a match is found between ether the first person or the second person having had the encounter. If test  1408  is determined in the negative, process  1400  may end or be repeated for a different first person, second person, and/or indicia of an infected person. If test  1408  is determined in the affirmative, then step  1410  sends a notification to an external component. The external component is variously embodied and may comprise, but is not limited to, server  1208 , display  1324  of one or more mats, communication and/or computing devices (e.g., text messages, emails, etc.), and so on. Accordingly, individuals who have had an encounter with the infected person or other resources (e.g., sanitization personnel, medical personnel, workforce allocation personnel, security personnel, etc.) may be notified. Optionally, automatic measures may be performed in step  1412  without requiring human intervention. Such actions include, but are not limited to, automatically displaying signage to display a warning to stay away, locking/unlocking access points, disabling systems to discourage their current and/or future use, minimizing interactions between suspected infected personnel with other personnel, such as denying access to a previously authorized area and/or granting access to a previously unauthorized area. 
     In the foregoing description, for the purposes of illustration, methods were described in a particular order. It should be appreciated that in alternate embodiments, the methods may be performed in a different order than that described. It should also be appreciated that the methods described above may be performed by hardware components or may be embodied in sequences of machine-executable instructions, which may be used to cause a machine, such as a general-purpose or special-purpose processor (GPU or CPU), or logic circuits programmed with the instructions to perform the methods (FPGA). These machine-executable instructions may be stored on one or more machine-readable mediums, such as CD-ROMs or other type of optical disks, floppy diskettes, ROMs, RAMs, EPROMs, EEPROMs, magnetic or optical cards, flash memory, or other types of machine-readable mediums suitable for storing electronic instructions. Alternatively, the methods may be performed by a combination of hardware and software. 
     Specific details were given in the description to provide a thorough understanding of the embodiments. However, it will be understood by one of ordinary skill in the art that the embodiments may be practiced without these specific details. For example, circuits may be shown in block diagrams in order not to obscure the embodiments in unnecessary detail. In other instances, well-known circuits, processes, algorithms, structures, and techniques may be shown without unnecessary detail in order to avoid obscuring the embodiments. 
     Also, it is noted that the embodiments were described as a process, which is depicted as a flowchart, a flow diagram, a data flow diagram, a structure diagram, or a block diagram. Although a flowchart may describe the operations as a sequential process, many of the operations can be performed in parallel or concurrently. In addition, the order of the operations may be re-arranged. A process is terminated when its operations are completed, but could have additional steps not included in the figure. A process may correspond to a method, a function, a procedure, a subroutine, a subprogram, etc. When a process corresponds to a function, its termination corresponds to a return of the function to the calling function or the main function. 
     Furthermore, embodiments may be implemented by hardware, software, firmware, middleware, microcode, hardware description languages, or any combination thereof. When implemented in software, firmware, middleware or microcode, the program code or code segments to perform the necessary tasks may be stored in a machine-readable medium, such as a storage medium. A processor(s) may perform the necessary tasks. A code segment may represent a procedure, a function, a subprogram, a program, a routine, a subroutine, a module, a software package, a class, or any combination of instructions, data structures, or program statements. A code segment may be coupled to another code segment or a hardware circuit by passing and/or receiving information, data, arguments, parameters, or memory contents. Information, arguments, parameters, data, etc. may be passed, forwarded, or transmitted via any suitable means including memory sharing, message passing, token passing, network transmission, etc. 
     While illustrative embodiments of the disclosure have been described in detail herein, it is to be understood that the inventive concepts may be otherwise variously embodied and employed, and that the appended claims are intended to be construed to include such variations, except as limited by the prior art.