INTERACTIVE EMERGENCY VISUALIZATION METHODS
Methods for emergency visualization are disclosed. The methods include a computer-implemented method for interactive emergency visualization that includes receiving a notification concerning an incident associated with a multi-floor structure, requesting location information from a user device geographically associated with the multi-floor structure, and receiving, in response to the request, a beacon identifier from the user device, the beacon identifier being associated with a beacon disposed within the multi-floor structure. The method also includes determining on which floor of the multi-floor structure the user device is located based on the beacon identifier and stored information indicating the location of the beacon and displaying a graphical map of the multi-floor structure and information indicating the specific floor on which the user device is located.
This application claims priority to U.S. Provisional Patent Application No. 62/326,921, filed Apr. 25, 2016, which is incorporated herein by reference in its entirety.
FIELD OF DISCLOSUREThis application relates generally to devices, systems, and methods for interactive emergency visualization systems.
BACKGROUNDDuring a catastrophic event, people rely on televisions, radios, and other media-consumption devices for up-to-the-minute information about all aspects of the event. Such information may include locations of events, people involved, responding agencies, and victims. Currently, with existing systems, there is no “immediate” flow of information about the event from people in the vicinity of the event to people in a position to provide help (e.g., first responders, police, firemen, security guards, etc.). Timely response in an emergency situation or incident, however, may depend on accurate and up-to-date information about the emergency situation itself, affected persons, and their state. Prompt acquisition and exchange of such data may be essential in such situations. Current audio-visual surveillance systems in the area of an emergency situation may provide information about the identity of affected persons, but the gathering and analysis of such information may be a time-consuming process. Additionally, the deployment of such surveillance systems may be costly and, generally, is negatively perceived by the public. Historically, during emergencies, state, local, and federal agencies use systems based on radio communications, such as mobile data terminals (MDTs) in emergency response vehicles. They also rely on after-the-fact witness accounts and calls to a 9-1-1 operations center to provide “approximate data” about an event that just occurred.
Moreover, conventional systems are unidirectional and cannot provide personalized information and guidelines to individuals affected by an emergency situation, or request and receive information related to the emergency situation from the individuals, particularly on a real-time or near-real-time basis. Conventional systems additionally cannot accurately locate and verify the identity of individuals affected by emergencies when the individuals are within multi-story structures. Further, conventional systems are susceptible to physical tampering leading to the unauthorized and/or erroneous distribution of potentially life-saving emergency information. Accordingly, needs exist for a real-time, efficient, interactive emergency visualization system.
SUMMARYThis summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Provided herein are systems and methods for interactive emergency visualization, including: receiving a notification concerning an incident associated with a multi-floor structure; establishing a geo-fence encompassing at least a portion of the multi-floor structure; determining which of a plurality of user devices were previously within a first distance from the incident based on stored location information received from the plurality of user devices, wherein each user device is associated with an individual; transmitting a request for current location information to each of the user devices determined to have previously been within the first distance; receiving, in response to the request, current location information from at least a subset of the user devices determined to have previously been within the first distance, wherein the current location information includes both geographical location information and beacon information associated with respective beacons disposed within the multi-floor structure; determining, based on the received current location information, which of the plurality of user devices are currently located within the geo-fence; and displaying a graphical map illustrating the multi-floor structure, the geo-fence, and the geographical locations of user devices determined to be within the geo-fence, wherein the displaying includes displaying information associating at least one of the user devices with a specific floor of the multi-floor structure based on the detected beacon information.
In some embodiments, establishing the geo-fence includes activating a geo-fence defined before the incident. In some embodiments, establishing the geo-fence includes defining a physical area associated with the multi-floor structure based on the incident. In some embodiments, the stored location information was received from the plurality of user devices prior to receiving the notification of the incident. In some embodiments, the stored location information is indicative of last known locations of the user devices.
In some embodiments, the displaying includes displaying a floor plan of the specific floor within the multi-floor structure along with a location of the at least one user device within the floor plan. In some embodiments, the displaying the floor plan is performed in response to receiving a user selection of the specific floor on the graphical map. In some embodiments, the above method may further comprise receiving a current safety status of an individual associated with the at least one user device, wherein the displaying includes displaying the current safety status of the individual.
In some embodiments, the current safety status of the individual is visually distinguished by a characteristic of an icon representing the individual in the graphical map. In some embodiments, the above method may include receiving, after receiving the current location information, further location information from the user devices determined to be within the geo-fence; and updating the graphical map based on the further location information.
Provided herein is a computer-implemented method for interactive emergency visualization, which may include: receiving a notification concerning an incident associated with a multi-floor structure; requesting location information from a user device geographically associated with the multi-floor structure; receiving, in response to the request, a beacon identifier from the user device, the beacon identifier being associated with a beacon disposed within the multi-floor structure; determining on which floor of the multi-floor structure the user device is located based on the beacon identifier and stored information indicating the location of the beacon; and displaying a graphical map of the multi-floor structure and information indicating the specific floor on which the user device is located.
In some embodiments, the displaying includes displaying a floor plan of the specific floor on which the user device is located and displaying, in association with the floor plan, an icon representing the user device and an icon representing the beacon. In some embodiments, the icon representing the user device additionally represents a plurality of user devices associated with the beacon. In some embodiments, the icon representing the user device visually indicates the number of user devices associated with the beacon. In some embodiments, the displaying the floor plan is performed in response to receiving a user selection of the specific floor on the graphical map.
In some embodiments, the beacon identifier comprises a first component representing the multi-floor structure and a second component representing a floor of the structure. In some embodiments, the determining on which floor of the multi-floor structure the user device is located includes comparing the received beacon identifier to a plurality of stored beacon identifiers, where each of the stored beacon identifiers are respectively associated with a location of a beacon.
In some embodiments, the above method may further include: receiving from the user device, in response to the request, a plurality of beacon identifiers associated with a plurality of beacons disposed in the multi-floor structure and receiving respective indications of proximity between the user device and plurality of beacons; and determining, based on the indications of proximity, which beacon in the plurality of beacons the user device is most near.
In some embodiments, the displaying includes displaying an icon representing the user device along with an icon representing the beacon in the plurality of beacons most near to the user device. In some embodiments, requesting location information from the user device includes determining whether the last known location of the user device is within a first distance from the multi-floor structure based on stored location information.
Provided herein is a computer-implemented method for interactive emergency visualization, which may include: receiving a notification concerning an incident associated with a multi-floor structure; requesting current location information from a plurality of user devices geographically associated with the multi-floor structure, each user device being associated with an individual; receiving, in response to the request, current location information from at least a subset of the user devices, wherein the current location information includes beacon information associated with respective beacons disposed within the multi-floor structure; determining, based on the received current location information, which of the plurality of user devices are currently located within the multi-floor structure and on which floors; receiving, from the user devices determined to be located within the multi-floor structure, safety status information about respective individuals associated with the user devices; and displaying a graphical map illustrating the multi-floor structure and information indicating, for each floor of the multi-floor structure, a number of the user devices determined to be on that floor along with the safety status information about the individuals associated with the user devices determined to be on that floor.
In some embodiments, displaying the graphical map includes displaying a three-dimensional image of the multi-floor structure with representations of each floor. In some embodiments, the representations of the floors visually reflect the safety status information of the individuals associated with the user devices determined to be the respective floors.
In some embodiments the above method may further include receiving a user selection of a representation of a specific floor and, in response, displaying a floor plan of the specific floor. In some embodiments, displaying the floor plan includes displaying icons representing the user devices determined to be on that specific floor overlaid on the floor plan.
In some embodiments, the icons visually indicate the respective safety status information of the individuals associated with the user devices represented by the icons.
Embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements and in which:
Interactive emergency visualization systems and methods are described herein. In case of an emergency situation or incident, such as a shooting, a terrorist attack, and so forth, identities and locations of individuals in proximity to the location of the incident may be determined using the location services of user devices carried by the individuals (e.g., smart phones, tablet computers, etc.). In some embodiments, a multi-floor structure near the incident may be visualized by the system, and individuals may be visualized within the various floors of the structure. One or more geo-fences may be activated around the incident. The individuals within a certain distance from the location of the incident and/or within the geo-fences may be informed about the incident and requested to provide real-time feedback about the situation, such as their safety status and situational information as they perceive it. Civilian or commercial level users and/or state or local entities including first responders such as police or fire officials, or paramedics, may provide feedback. Civilian or commercial level users or individuals may provide information concerning their condition, safety, and/or whatever information they may have concerning the incident. Audio, video, and/or text data may be received from the individuals via their devices. For example, a photo of an active shooter or a video of a terrorist attack may be received. The received feedback may be forwarded to law enforcement or other appropriate agencies. The locations of incidents, buildings, geo-fences, individuals, and first responders may be included in a visualization generated by the interactive emergency visualization system.
Additionally, data from various sources, such as local Emergency Plan Actions or specific plans, e.g., those of the building management where the event occurred, may be retrieved and remotely provided to affected individuals. For example, emergency instructions relative to the incident may be extracted from the data and provided to affected individuals via a user interface of their devices. For example, emergency instructions may be provided in a graphical form as directions on a map displayed on the user device. At the same time, the current position of the individual may be displayed on the map.
In some embodiments, the interactive emergency visualization system may be used to request assistance during an incident. Thus, an individual may send an emergency notification and/or additional data related to the emergency via the user device. The individual's geographical position may be determined, and local emergency agencies may be informed about the incident affecting the individual. Depending on the nature of the emergency, notifications may additionally be provided concurrently to state emergency agencies or authorities, federal emergency agencies or authorities (e.g., FEMA, the FBI, military police, etc.), or both. Additionally, emergency instructions may be retrieved based on the geographical position of the individual, typically relative to the emergency, and provided to the individual such as via a graphical interface of the user device.
Referring now to the drawings,
The user device 130 is a network-enabled computing device used by the individual 120 and may be a mobile telephone, a desktop computer, a laptop, netbook, a smart phone, a tablet computer (e.g., an iPad®, Galaxy® or Kindle®), an RFID capable device, a GPS device, a wearable device (such as an Apple watch, or other tethered accessory or clothing, etc.), or other computing device that is capable of sending and receiving data over a network. For example the user device 130 may include any number of communication transceivers such as a cellular radio, a WiFi radio, a Bluetooth radio, and any other transceiver capable of communicating with the network 110. The user device 130 further includes a Graphical User Interface (GUI) for displaying a user interface associated with the interactive emergency visualization system 200. In some embodiments, the user interface is part of a mobile application (or “app”) that is provided by the system 200 and downloaded and installed on the user device 130, typically in advance of an emergency event. In other embodiments, the user interface may be web-based and viewable through a standard web browser. For the purposes of this disclosure, an emergency event may be referred to as an “incident” and may include one or more of a terrorist attack, a shooting event, a bombing event, an earthquake, a flood, a fire, a hurricane, tornado, an accident, collapsing building, and other natural or man-made disasters. A user device 130 may be equipped with an app by downloading the app from the Internet, an Intranet, or other network. User devices 130 may be equipped with the app as part of an enrollment or orientation. For example, if the individuals 120 are students associated with a university, the students may download an app to their smart phone and/or tablet as part of enrollment or orientation. In other instances, the app may be pre-installed on the user device or may be integrated into the operating system of the user device. Such an app may communicate with the interactive emergency visualization system 200 using any of the communication transceivers in the user device. For example, the app may receive and transmit emergency information via a cellular data connection and/or a WiFi data connection. In this manner, if cellular towers are overly congested during an incident, the app on the user device may switch to another communication means, such as WiFi, to transmit and receive data. Alternatively, the app may transmit using multiple concurrent communication means, such as cellular and WiFi, although battery life of the device must be considered when doing so. As explained in more detail below, each instance of a mobile app installed on a user device (e.g., an ARCANGEL® security app as shown in reference to
The user device 130 may also include hardware and/or software configured to determine a geographical location of the user device. For example the user device may determine its present location using a GPS receiver, the WiFi radio, the cellular radio, the Bluetooth radio, and/or any other transceiver configured to determine the current physical location of the user device, or any combination thereof.
The individual 120 may be a bearer or user of the user device 130 who may interact with the interactive emergency visualization system 200 and/or the responder 170 via a GUI. The responder 170 may communicate with the interactive emergency visualization system 200 via the work station 180 or otherwise.
The first responder user device 162 may be similar to the user device 130, but is used by individuals within emergency and law enforcement agencies. The first responder user device 162 may also include a user interface to facilitate communication with the interactive emergency visualization system 200, but this user interface may display additional information pertinent to responding to an incident, as will be discussed below. The user interface on the first responder user device 162 may be part of a mobile application (or “app”) that is downloaded and installed. In other embodiments, the user interface may be web-based and viewable through a standard web browser.
The interactive emergency visualization system 200 may be operated by a security company 140 that is hired by an entity with a plurality of individuals (such as a university, city, corporation, building management, etc.) to provide information exchange and emergency response services during incidents involving the individuals associated with the entity. In general, the interactive emergency visualization system 200 tracks the locations and safety status of individuals and first responders during incidents and coordinates the flow of information between individuals and first responders, as well as providing emergency analysis and communication directly to individuals and first responders from the system 200. In that regard, the interactive emergency visualization system 200 may communicate with one or more local, state, and federal emergency and law enforcement agencies 160 (e.g., rescue or paramedic services, police departments, fire emergency services, the FBI, Homeland Security, etc.) during an incident. The interactive emergency visualization system 200 may receive one or more notifications associated with incidents, emergency action plans, and other data from the emergency and law enforcement agencies 160. Additionally, the interactive emergency visualization system 200 may transmit information about one or more individuals in proximity to the location of the incident as well as audio, video, and/or text data received from the individual 120 to the emergency and law enforcement agencies 160. In some embodiments, first responders may be able to access a level of information in the system 200 and contact one or more individuals or other first responders via the system 200.
Connections to the interactive emergency visualization system 200 may be secured with encryption protocols (e.g., Secure Sockets Layer (SSL), HTTPS, etc.) and access may be restricted to authorized users with an authentication and/or authorization layer (e.g., log-in credentials, electronic keys, etc.). Further, all data stored on devices and in databases in the environment 102 may be encrypted to protect sensitive location and profile information associated with individuals. For example, location and profile data stored by the interactive emergency visualization system 200 may be encrypted by the Advanced Encryption Standard (AES) or other encryption protocol.
Hosting the interactive emergency visualization system 200 on virtual hardware provided by the IaaS provider 202 allows the security company 140 to scale up and scale down the capabilities of the system depending on the amount of devices accessing the system. For example, if notification of a major incident is received, additional virtual instances of the interactive emergency visualization system 200 may be initiated by the IaaS provider 202 on a temporary basis to handle a larger than normal number of connections to the system and a larger volume of data being transferred between users.
In some embodiments, the database 220 may be any type of reliable storage solution such as a RAID-based storage server, an array of hard disks, a storage area network of interconnected storage devices, an array of tape drives, or some other scalable storage solution located either within the system 200 or remotely located (e.g., in the cloud).
In some embodiments, the system 200 performs specific operations by the processor 210 executing one or more sequences of one or more instructions 230 provided by the database 220. The instructions 230 may include one or more algorithms for communication between different systems, registering users and individuals, identifying emergencies, integrating with Application Program Interfaces (APIs) and sensor systems, characterizing and generating one or more geo-fences, sending communications to users, individuals, law enforcement, and emergency response groups, or other functions. The instructions 230 may be stored on non-transitory, computer-readable medium. The term “non-transitory computer-readable medium” shall also be taken to include any medium that is capable of storing, encoding, or carrying a set of instructions for execution by the machine and that causes the machine to perform any one or more of the methodologies of the present application, or that is capable of storing, encoding, or carrying data structures utilized by or associated with such a set of instructions. The term “non-transitory computer-readable medium” shall accordingly be taken to include, but not be limited to, solid-state memories, optical and magnetic media. Such media may also include, without limitation, hard disks, floppy disks, NAND or NOR flash memory, digital video disks (DVDs), RAM, ROM, and the like.
In some embodiments, the processor 210 is operable to send and receive notifications. For example, the processor 210 may receive a notification concerning an incident. The notification may be based on information generated or received by information from user devices 130, one or more sensor systems, or third-party information platforms that interface with the system 200 via APIs. The notification may include a location of the incident and may be received from an emergency or law enforcement agency, one or more users of the system 200, and so forth. In one embodiment, user interfaces on the user device 130 and first responder user device 162 may provide a button or other control element through which an individual may submit a report of an incident. Such a report may automatically include the location of user devices 130 and any description input by individuals.
Based on the information received about the incident, the processor 210 may define a geo-fence (or geo-net) representing a physical area surrounding the location of the incident. In one embodiment, the geo-fence may be a physical area defined by a circle, rectangle, polygon, or other shape, having a specific area around the location of the incident. The size and shape of the geo-fence may be manually defined by a user, an operator of the system 200, and/or an emergency or law enforcement agency. For example, the system 200 may define a geo-fence on each floor of a multi-floor structure, as shown if
Additionally, the geo-fence may include one or more proximity zones that represent physical areas of different distances from the location of the incident. In the case of a circular geo-fence, the proximity zones may be defined by concentric circles of varying radii extending from the location of the emergency. In the case of a rectangular geo-fence, the proximity zones may be defined by nested rectangles around the location of the emergency. The system 200 may dynamically alter the size and/or shape of the geo-fence during an incident based on incoming information from first responders, law enforcement agencies, individuals with user devices, news outlets, etc.
In some embodiments, two-dimensional and three-dimensional (3D) geo-fences may be defined by the processor 210. For example, a number of geo-fences may be defined within a single building. In particular, each floor of the building may include a 3D geo-fence associated with the system 200. In the event of an emergency, the processor 210 may be operable to display the status of each of the geo-fences. This status information, as well as a visualization of the location and physical attributes of the geo-fences may be provided in one or more visualizations which are shown in reference to
The processor 210 may receive location information describing the locations of the user devices 130. The location information may be received directly from the devices based on location information gathered by the devices (such as GPS). The location information for the user devices 130 may also be based on the defined geo-fence. Since the user devices may be associated with individuals, the processor 210 may determine a position of an individual within the geo-fence based on the location information. The position may include a proximity zone associated with the position of the individual. Furthermore, the geo-fence may include one or more beacons that may assist in gathering location information about the devices. The beacons may utilize Bluetooth, WiFi, or other wireless technology and may help to locate and cluster devices 130 as discussed below.
The processor 210 may inform individuals inside and outside of the geo-fence about the incident via a user interface of the user device 130. Additionally, the user interface may provide individuals with the ability to upload feedback related to the incident to the system 200. The feedback may be received by the processor 210 and may include a request for help, a statement that no help is required, an assessment of the incident, audio information, video information, text information associated with the emergency situation, and so forth. In one embodiment, the system 200 may dynamically alter the size and/or shape of the geo-fence based on the feedback received from the user devices. For instance, an individual may report that a shooter has moved to a second location. The system 200 may then move the center point of the geo-fence to the second location. In some embodiments, two or more of reports of such a change might be required to help ensure the geo-fence is not moved prematurely or erroneously. Such a movement of the geo-fence may trigger the transmission of a new round of emergency information messages to individuals now within the newly-located geo-fence. Such a movement of the center point of the geo-fence may be performed automatically by the system 200 based on incoming information, or may be performed manually by an administrator with appropriate access to the system (based on login credentials, entered passwords, codes, etc.). Individuals that are determined by the system 200 to be outside the geo-fence may also be sent notifications to inform them that they are not in danger.
The database 220 may be configured to store a list of individuals that may need to be alerted in the case of an emergency. For example, if the environment 100 includes a university campus, such a list may include students, professors, staff, administrators, security guards, and others who need to be alerted in the event of an incident on or near the university campus. In some embodiments, the system 200 is configured to send a request for location information to each device in the system near the incident. Each individual in the database 220 may be associated with at least one user device 130 that is used to track their location and provide emergency information. The system 200 may store location information about devices. For example, if an incident is detected, the system may access the last known locations of user devices to determine which devices are located near the incident. In some embodiments, each individual is associated with a user device 130 by way of an app instance identifier representing a particular mobile application instance installed on a user device. Further, identifying information (pictures, descriptions, contact information, etc.) and third-party emergency contact information may be associated with each individual in the database 220. In some embodiments, the database 220 additionally stores information used to validate mobile app instances and to also validate location information received from the app instances. Validation of users, as well as systems and methods for securely determining the location of a user device through the use of beacons are discussed more detail in U.S. Provisional Patent Application No. 62/266,451 (Attorney Docket No. 51425.13PV01), which is hereby incorporated in its entirety by reference.
Notifications about the incident, locations of other incidents, individuals located in proximity to the incident, safety status information for individuals, and feedback received from individuals 120 via user devices 130 may be stored in the database 220. The data in the database 220 may be accessible by an operator of the system 200, one or more first responders, representatives of emergency or law enforcement agencies, and so forth.
In some embodiments, the system 200 includes a communications interface 240 that may facilitate the reception and processing of communications for the system. The communications interface 240 is operable to send and receive communications via the Internet and local networks. The communications interface 240 includes a number of interfaces configured to receive information about potential emergencies from any number of sources. For example, an internal data interface 250 is configured to receive data from one or more user devices 130, the first responder user device 162, and other data sources within the internal network of the interactive emergency visualization system 200. The data received by the internal data interface 250 may include incident reports, safety status information for individuals, audio/video associated with an incident, descriptive information about the incident such as location and severity information, etc. The data collected by the internal data interface 250 may be utilized by the processor 210 to determine that that an incident has occurred.
A sensor interface 260 may be configured to gather sensor data from a number of data sources. For example, in one embodiment, the sensor interface 260 may be a collection of APIs configured to interface with a variety of different sensors and data sources controlled and/or operated by third-parties. The sensor data may be processed at the sensor interface 260 before communication to the processor 210. In one embodiment, such processing may include normalization of the sensor data to make it amenable to analysis and display within the system 200. The sensor interface 260 may be in communication with any number of sensor systems and other data gathering devices. For example, sensor systems may include smoke alarms 262, gunfire detection systems 264, anti-drone systems 266, CCTV cameras 268, traffic cameras 270, radiation detectors 272, seismic alert systems 274, pollution sensors 276, and any number of other sensor systems. The sensor data collected by the sensor interface 260 may be utilized by the processor 210 to determine that that an incident has occurred. The sensor data collected by the sensor interface 260 may also be utilized by the processor 210 to update the status of an on-going incident (e.g., determine current severity and location).
In some embodiments, third-party sensors and data sources may include incident detection abilities. In this case, the third party sensor system may identify an incident and communicate incident information to the system 200 via the sensor interface 260. In some embodiments, beacons 574, such as those referred to in
A third-party data interface 280 is configured to collect information from any number of third-party data sources such as social media platforms and the Internet. For example, the third-party data interface 280 may include a collection of APIs to interface with third-party applications (apps) 282 such as Twitter, Facebook, Instagram, Snapchat, Flickr, LiveJournal, Tumblr, YouTube, Vimeo, LiveLeak, and any other social media or public information feed. The third-party data interface 280 may collect information related to an incident and/or related to a specific location or person of interest from these third-party data sources. As another example, the third-party data interface 280 may include a collection of APIs to interface with Internet data sources 284 such as news feeds (AP, CNN, etc.), records databases, airline tracking information, webcams, and any number of other Internet-based information sources. The data collected by the third-party data interface 280 may be utilized by the processor 210 to determine that that an incident has occurred. The data collected by the third-party data interface 280 may also be utilized by the processor 210 to update the status of an on-going incident (e.g., determine current severity and location).
As described above, the interactive emergency visualization system 200 is the emergency information server component in the client-server architecture of the emergency information dissemination scheme described herein. As will be described in more detail, the beacons are utilized by the system 200 to aid in determining the geographical location of the user device 130 and, by association, the individual 120. Such location information may be used by the system 200 to transmit location-based emergency information to the user device in the event of an emergency in the vicinity of the location 572. In addition, the beacon-based location system illustrated in FIG. 3 is secure in that location information reported by user device 130 is validated to inhibit or prevent malicious users or attackers from spoofing user locations and preventing, hindering, or otherwise misdirecting the flow of accurate emergency information.
In the illustrated example, beacons 574, 576, 578, 580 are permanently or temporarily disposed on the third floor of a multi-floor building. Other beacons may be disposed on various other floors of the location 572. The beacons may also be disposed in various rooms of each floor. As shown in the illustration of
In one embodiment, the beacons in location 572 are maintained and/or placed in specific geographic locations by the administrators of the interactive emergency visualization system 200. In other embodiments, the beacons are maintained and/or placed by third parties who report the locations of the beacons to the system 200.
The beacons 574, 576, 578, 580 transmit data wirelessly over broadcast signals 582 that may be detected by user device 130 when the user device is within the broadcast transmission range of the beacons 574, 576, 578, 580 (i.e., proximate to a beacon). The broadcast transmission range of the beacons 574, 576, 578, 580 may be as little as a few inches or as great as 500 feet or more depending on the configuration of the beacons 574, 576, 578, 580, as well as other known factors such as interference, type of signal, etc. In some instances, the broadcast signal 582 may be referred to as an advertisement or ping, and is broadcast intermittently at configurable advertisement intervals. Further, the broadcast signal 582 may be a short-distance wireless signal (e.g., a Bluetooth Low Energy signal), a medium distance wireless signal (e.g., a Wi-Fi signal), and/or any other suitable electro, magnetic, and/or electro-magnetic broadcast signal type. In some embodiments, the beacons 574, 576, 578, 580 may be configured to communicate using more than one type of wireless communications. For instance, the beacons may broadcast the signal 582 using one type of wireless signal, such as Bluetooth Low Energy, but use another type of wireless signal to engage in point-to-point communications with the user device 130. Power and/or directionality of the broadcast signal 582 on the beacons 574, 576, 578, 580 may be adjusted to communicate only within a desired range and/or direction in various embodiments.
The broadcast signal 582, in various embodiments, includes a beacon identifier (beacon ID), which uniquely identifies a beacon and allows it to be associated with a specific geographical location. For instance, the database 220 in the interactive emergency visualization system 200 (shown in
In the illustrated embodiment, the beacons 574, 576, 578, 580 do not contain long-range communication capabilities and rely on the user devices 130 to pass the beacon identifier and beacon verification information to the interactive emergency visualization system 200. In other embodiments, however, the beacons 574, 576, 578, 580 may additionally contain long-range communication (e.g., wide-area network) capabilities, such as Wi-Fi communication capabilities, cellular communication capabilities, satellite communication capabilities, etc., such that the beacons themselves communicate with the interactive emergency visualization system 200, either in addition to or in place of the user devices 130 passing such information back to the interactive emergency visualization system 200.
The broadcast signal 582 of the beacons 574, 576 578, 580, in some embodiments, also includes broadcast power information that indicates how strong the signal should be at a known distance (sometimes called transmitter power or measured power). A user device receiving the broadcast signal may use the reference broadcasting power information to estimate the range (proximity) of the user device 130 from the beacon by comparing it to the actual strength of the signal received at the device 130. In some embodiments, the distance between the user device 130 and a beacon may be used by the interactive emergency visualization system 200 to further refine location information describing the user device's 130 geographical location.
According to various embodiments, beacons 574, 576 578, 580 include various hardware and/or software components to effect communication with the user device 130. In general the beacons 574, 576 578, 580 include a processing component such as a microprocessor with working memory, non-transitory static memory, one or more wireless communications transceivers such as a BLE and/or a Wi-Fi transceiver, an antenna, a real-time clock, a battery, and various physical buttons or switches to control power and operational mode. In various embodiments, the beacons 574, 576 578, 580 may include various other components such as sensors (e.g., accelerometers, proximity detectors, motion detectors), additional wireless transceivers such as cellular-based transceivers, wired transceivers such as an Ethernet transceiver, one or more physical communication ports (such as a USB port or other port configured to facilitate a local communication connection for management or data transfer purposes), voltage monitors, speakers, microphones, lights, cameras, and other components that would aid in the distribution of location based emergency information to individuals.
Executing on the user device 130 is a mobile application (“app”) instance 584 configured to communicate with the interactive emergency visualization system 200. In one embodiment, the mobile app is provided by the system 200 and an app instance 584 of the mobile app is downloaded and installed on the user device 130, typically in advance of an incident. For example, if the individuals 120 are students associated with a university, the students may install an instance of the app instances 584 on their smart phone, laptop, and/or tablet (or other suitable network-enabled computing device as disclosed herein) as part of or in association with enrollment or orientation. In the illustrated embodiment, each app instance 584 installed on a user device 130 includes an app instance identifier, which uniquely identifies the particular app instance 584 and allows it to be associated with a specific individual. For instance, the database 220 in the interactive emergency visualization system 200 may store a list of app instance identifiers that respectively represent unique installations of the mobile application on user devices 130. In database 220, each app instance identifier may be associated with a specific individual and other relevant information useful during an emergency, such as emergency contact information for the individual. In some embodiments, the mobile app is a standalone mobile application, but in other embodiments, the app is executable through a web browser application or is an integrated part of the operating system of the user device 130. The app instance 584 may communicate with the interactive emergency visualization system 200 via network 110 using any of the communication transceivers in the user device 130. For example, the app instance 584 may receive and transmit emergency information via any available route, including a cellular data connection, Bluetooth, and/or a Wi-Fi data connection.
The interactive emergency visualization system 200 may further include one or more services executing on the processor 210 that are accessible via the network 110. Such services may provide the interface through which the user devices 130 communicate with the system 200. For example, the system 200 may expose an emergency location service 586 that the plurality of deployed app instances 584 interact with to affect the emergency services describes herein. In one embodiment, the app instance 584 transmits beacon-based location information to the emergency location service 586, which verifies the location information and, if verified, uses it to update the recorded location of the individual 120. In some embodiments, the emergency location service 586 is a specialized web service configured to expose a machine-to-machine interface with which the app instances 584 exchange emergency and location data. In other embodiments, the emergency location service 586 is a hardware-based, specialized server system operating within the interactive emergency visualization system 200 with which the mobile application (“app”) instances 584 are configured to communicate. In either scenario, the hardware and/or software on which the emergency location service 586 executes is scalable to accommodate a large amount of concurrent interactions with a large number of app instances 584 during an emergency event.
The user device 130 is configured to detect the broadcast signal 582 from beacons 574, 576 578, 580 when the user device 130 is located within the transmission range of a beacon. In the illustrated embodiment, the app instance 584 executing on the user device 130 is configured to scan for broadcast signals emanating from nearby beacons. Such scanning techniques may, in various embodiments, be carried out by hardware, software, or a combination of hardware and software in the user device 130. As will be described in greater detail below, the app instance 584 is configured to detect a broadcast signal 582 from one or more of the beacons 574, 576 578, and 580, capture the information—such as the beacon identifier and proximity indication—in the signal, and provide it to the system 200 to report that it is physically near the detected beacon. The system 200 utilizes the known location of the beacon to determine that the user device 130 is near such known location, or even the approximated or actual distance.
The visualization 300 may include graphical map data relating to an area of interest, such as a city or building complex. This map data may be overlaid with a number of images, symbols, view screens, status bars, and other visual data to track the incident. In the example of
In some embodiments, the visualization 300 may include patterns and/or colors that represent various risk and status levels. In the example of
The visualization 300 may include one or more geo-fences 330, 332, 333. In some embodiments, the size and shape of the geo-fences 330, 332, 333 may be determined before information about an incident is received by the system 200. For example, a pre-defined geo-fence may correspond to the perimeter of a building. In other embodiments, the size, shape, and safety level of each geo-fence 330, 332, 333 may be determined in relation to an incident. The safety level of each geo-fence 330, 332, 333 may be represented by a pattern or color. In the example of
Still referring to
In some embodiments, the safety status of each individual does not necessary correspond to the safety level of the geo-fence 330 in which the individual is located. For example, the visualization 300 includes a number of individual markers 306 with medium and light patterns 305, 307 within the geo-fence 330 with a dark pattern 303. This difference in status may be show that not all individuals within the geo-fence 330 have been affected in the same way by the incident. For example, an isolated shooting may affect some of the individuals, such as the individual markers 306 with the dark pattern 303 around the incident marker 302, while other individuals further away are not affected. In
Individuals may also be represented in clusters. For example, cluster markers 351 and 353 are shown on the visualization 300 of
In some embodiments, the clusters may allow a user of the visualization 300 to quickly assess the location and safety status of individuals without having to view each individual separately. The clusters may also simplify the visualization 300. The clustering of individuals may vary according to the needs of the user of the visualization 300. For example, in the event of an incident involving a large number of people, such as an incident during a large concert, the visualization 300 may be configured to represent large numbers of people with each cluster marker. In the event of an incident involving a smaller number of people, such as incident in a house or small commercial building, the visualization 300 may be configured to represent smaller number of people in clusters or even individual markers 306 without clustering.
In some embodiments, the size of each cluster makers may scale based on the view level of the visualization 300. For example, a user may zoom into a region of the map which includes one or more clusters. As the map becomes more detailed, the clusters may split into smaller clusters and finally into individual markers 306. This scalability may allow a user to view the safety statuses of many individuals while representing their general locations. Furthermore, a user of the visualization 300 may be able to “zoom into” areas of interest to view more granular data on individuals.
In some embodiments, the system 200 may assign individuals to clusters based on proximity to a beacon. For example, when an incident is detected, the system 200 may request location information from the user devices 130. The user devices 130 may in turn receive beacon information from nearby beacons, including one or more of a Universally Unique Identifier (UUID), a major number, a minor number, a proximity measurement (as determined by the signal strength of the beacons), and a Received Signal Strength Indicator (RSSI) transmitted by the one or more beacons. This information is sent from the user devices 130 to the system 200 where is it analyzed to determine the closest beacon to each user device 130. After this determination, the system 200 checks the status of the beacon to see if the devices are part of an incident. The system 200 compares the beacon information received from the device 130 to stored beacon information in a database. If the beacon information matches, the system determines the user device is near a specific beacon and the device is clustered to that beacon on the visualization.
In other embodiments, the system 200 may generate clusters based on criteria such as proximity and status. For example, the system 200 may cluster determine that a number of individuals are located in close proximity to each other. The system 200 may assign these individuals to the same cluster. The system 200 may make this determination based on a maximum distance between individuals or a minimum radius of a circular area in which individuals are located. In the case of a multi-floor structure, such as an office building, users may be clustered together based on the floor on which they are located.
The system 200 may also assign individuals to clusters based on similar status. For example, the system 200 may cluster a number of individuals with a “safe” status in a single cluster. Combinations of the above clustering methods may also be used. For example, the system 200 may determine that all individuals with a “in danger” status that are less than 200 feet from a beacon will be clustered to that beacon.
In some embodiments, the shape, pattern, or color of an individual marker 306 may represent a type of individual. For example, an individual marker 306 with a light, medium, or dark pattern (or a green, yellow, or red color) may represent a civilian, employee, or passer-by, while an individual marker 306 with a different shape, pattern, or color (such as a shield for law enforcement or a cross for a paramedic) may represent a first responder. Furthermore, various types of first responders may be individually displayed on the visualization 300. For example, first responders may be identified as “Fire”, “EMS”, “Police”, “Other”, or have other custom designations (such as “mall security”). The separation of individuals by type may allow a user of the visualization 300 to quickly assess the location and number of first responders near an incident. The various types of individuals may be tracked independently on the visualization, such as being included on different individual safety status lists 350 for each type, or by being clustered according to type. For example, a first cluster may include only law enforcement individuals, a second cluster may include only medical professionals, and a third cluster may include only civilians. Furthermore, a user may be able to select the type of individuals displayed on the visualization 300. For example, the visualization 300 may display only law enforcement individuals in one window while all individuals are displayed in another window.
Individuals may be clustered together according to type and location, as discussed previously, as well as other criteria. For example, clusters may be formed on the visualization to represent individuals with the same safety status. Clusters may also be formed around certain important locations, such as checkpoints, safe zones, areas adjacent to an incident. Clusters may also be formed around beacons. For example, beacons may be located on floors throughout a building. Individuals may be clustered throughout the building based on their location relative to the closest beacon.
Additionally, the visualization 300 may display representations of data received via the sensor interface 260 and the third-party data interface 280. As discussed above, the sensor interface 260 may receive incident-related data from any number of sensors such as closed-circuit televisions, shot-detectors, etc. The third-party data interface 280 may receive incident-related data from social media platforms such as Twitter and Facebook. The incident-related data elements received from each source typically include both content and location information describing where the content originated. For example a “tweet” from a Twitter user will include the content of the tweet and a location associated with the tweet (typically the location of the user device at the instant the tweet was submitted). As another example, an incident-related data element may contain a CCTV live video stream and the location of the CCTV camera. During and incident, users may submit information from their device which may include video, images and/or text. The information submitted by users may include the present location of the user or the location where the information was captured. This feature may help to add context to the submitted information. In some embodiments, the use and visualization of relevant social media in the visualization 300 may provide for focused intelligence related to the incident.
As shown in
Each of the user-selectable graphical representations 308, 312, and 313 is displayed on the visualization 300 at a location on the map corresponding with the geographical location from which the underlying incident-related data element originated. Further, as shown in
In some embodiments, the interactive emergency visualization system 200 may be operable with control third party sensors such as the CCTV system displayed in box 320. In this case, the operator may be able to access data from third party sensors that are located near an incident. For example, the operator may recognize that the CCTV system includes a camera (shown by the graphical representation 312) that is close to the incident marker 302. The operator may click on the graphical representation 312 to pull up the current or past feeds from the camera, and may even be able to control the camera to change the view angle. Local sensors, such as those in a CCTV or a gun-shot detection device, may be able to process incident information locally before that information is provided to the interactive emergency visualization system 200, and/or concurrently to first responders and/or to building security and management.
In some embodiments, the visualization 300 may display only a subset of user-selectable graphical representations according to the input from a user. For example, different types of user-selectable graphical representations may correspond to different graphical layers, and the visualization 300 may display any combination of layers. In one embodiment, the layers may be based on the content type of the incident-related data elements underlying the user-selectable graphical representations. For example, a user may choose to display on the visualization only the user-selectable graphical representations that are based on video content, or Twitter content, or audio content, etc. In another example, the visualization may display a subset of user-selectable graphical representations based on the timestamp or the location associated with the underlying incident-related data elements.
In some embodiments, the visualization 300 may include an individual safety status list 350. This safety status list may include a list of individuals within various areas of the visualization 300. In some embodiments, the safety status list may group individuals by their location within different geo-fences. In other embodiments, the safety status list may group individuals by safety status level. In the example of
An incident description box 440 may be included in the visualization 400. The incident description box 440 may include a title for the incident, as well as background information. In the example of
In some embodiments, the visualization 400 may include a safety status list 450. In some embodiments, each incident may include a separate safety status list 450. In some embodiments, each geo-fence may include a separate safety status list 450. The safety status list 450 may include a list of individuals within various areas of the visualization 400. In some embodiments, the safety status list 450 may group individuals by safety status level. The safety status list 450 may also include one or more selectable icons for each safety level. In the example of
The visualization 400 may also include a box 431 displaying the type and number of first responders near an incident. In the example of
In some embodiments, the visualization 460 may include various modes configured to display different layers of information. For example, the visualization 460 may include a “Monitor Mode” which allows a user to view all new alerts that are received by the visualization 460. This may allow a user to view the most updated information regarding an incident. The visualization 460 may also include a “Live Mode” which is configured for a user actually responding to an incident. In some embodiments, the “Live Mode” may allow a user to view updates as well as interact with users in the visualization 460, (i.e., to message users, add incident updates, modify existing incident updates, add, modify, and/or delete safe zones or perimeters). To streamline efforts and avoid confusion among first responders, the “Live Mode” may include a setting to restrict access of the visualization 460 to a certain number of viewers. In some embodiments, access is restricted to a single user. In other embodiments, the number may be five or less users, ten or less users, or other numbers of users. Access to the visualization 460 may require a user to enter a code or PIN number. In some embodiments, the visualization 460 may include a “Playback Mode” which allows an operator to view the timeline of an incident. For example, an operator may be able to view when the incident occurred, which it was reported, the actions of individuals near the incident, the activation of geo-fences, and the actions of first responders. In some embodiments, this information may be displayed in the context of a visual timeline such as timeline 310 shown in
In some embodiments, each floor of the building may be visualized individually by selecting the desired floor in a building view window 421. The building view window 421 may include a title of the building 422, information about each floor, and information about individuals on each floor, including safety status information. For example, the number of users on each floor that are in each safety status category (“safe,” “in danger,” “unknown,” etc.) may be displayed in a visually distinguishable manner. In some embodiments, individuals may be clustered together and represented by cluster markers 472, 474 according to their location on a floor. Although the cluster markers 472, 474 are shown in the floor view window 473, cluster markers 472, 474 may also be displayed in other areas of the visualization 470. The clustering of individuals may allow for simplification of visualizations with many individuals while still representing their locations and statuses. Furthermore, individuals on floors with beacons may be clustered around the beacons. As individuals move throughout the floors of the building 422, they may be clustered in different clusters according to their proximity to a beacon. The cluster markers 472, 474 may include a number of individuals represented by the cluster, as well as the safety status information for each individual in the cluster. Furthermore, cluster markers 472, 474 may include information about the beacon around which they are clustered. For example, the cluster markers 472, 474 may contain a label with the beacon title.
Still referring to
In another similar embodiment (not shown), a two-dimensional visualization may be used. For example, for certain types of incidents in a low-lying building with only a few floors it may be simpler to use a two-dimensional visualization, optionally using color coding or shapes to represent individuals and the different floors on which they are located.
The visualization 470 may also include one or more user-selectable graphical representations 312 (
In the example of
In some embodiments, the visualization 490 may include a timeline 310. In some embodiments, the addition of the timeline 310 creates a “four-dimensional” visualization which allows the operator to view aspects of an event in relation to time. In some embodiments, the timeline 310 related to an incident may be accessed via a “Playback Mode.” Different sources of information may contribute to this timeline, including a selection of data relating to user devices as well as from local networks and the Internet, and the various types of information described in this disclosure. In some embodiments, time-stamped data is received by the system 200 and is placed in the visualization 490 according to time received. Time-stamped data may be collected for individuals, geo-fences, social media feeds, safety status lists, and other features. A user of the visualization 490 may be able to move back and forth across the timeline by pressing the timeline tools, such as rewind, fast-forward, play, stop, skip forward and backward, and slow to see temporal aspects of the visualization 490. By moving the timeline 310 back and forth, the visualization 490 may display only the events occurring during the corresponding time frame. In some cases, this may allow the operator to analyze an incident forensically.
In some embodiments, the timeline 310 may include events 311 such as the detection an incident or the activation of a geo-fence. The events 311 may also correspond with alerts generated by the system 200. For example, a user of the visualization 490 may receive an alert that an incident is detected within an assigned geo-fence. The user may be prompted to contact first responders, notify individuals, activate geo-fences, etc. via the visualization 490. The alerts may be selectable, allowing a user to see more details of selected alerts. The alerts may also include “accept” or “reject” options, and may allow a user to assign an alert to a task list. In some embodiments, the alerts are listed by type and source (such as a fire that was reported on Twitter).
At step 502, the method 500 may include detecting an incident associated with a multi-floor structure. In some embodiments, the incident may include a terrorist attack, a shooting event, a bombing event, an earthquake, a flood, a fire, a hurricane, tornado, an accident, collapsing building, and other natural or man-made disasters. In some embodiments, the interactive emergency visualization system 200 receives information regarding the incident from one or more sensors, such as a smoke alarm, radiation detector, seismic alert system, other sensor systems shown in
In some embodiments where the incident is reported by a mobile device (such as user device 130 or first responder device 162), the device is configured to display a selectable incident report button. The incident report button may be any type of selectable area on the device, such as a button, icon, marker, or image. The incident report button may appear on a screen of the device when an incident is detected by the device. In other embodiments, the incident report button is activated by a user upon receiving word of an incident. The incident report button may be an alarm or panic button. Upon activation of the report button, the device may be configured to automatically send a notification to the interactive emergency visualization system 200. In some embodiments, the incident report button may include a phone call to an emergency response line (such as 9-1-1 or a police department) and/or a phone call directly to the interactive emergency visualization system 200. This phone call may help to verify the incident and provide emergency services to the user of the device.
At step 504, the method 500 may include activating or defining a two-dimensional or three-dimensional (3D) geo-fence around the incident with the interactive emergency visualization system 200. The geo-fence may be configured to represent areas with various risk levels. In some embodiments, the geo-fence is a high geometry geo-fence, meaning that the geo-fence is activated in close proximity to the incident. For example, a high geometry geo-fence may be activated around the perimeter of a building where an incident has been detected. In other embodiments, medium or low geometry geo-fences are used. For example, a medium geometry geo-fence may include a city block where an incident is detected. A low geometry geo-fence may be a 5 mile radius around an incident. Each of the high, medium, and low geometry geo-fences may have a different pattern or color. For example, high geometry geo-fences may be red, while medium geometry geo-fences are orange, and low geometry geo-fences are yellow. Other colors, as well as patterns or shapes may be used to represent various geo-fences.
More than one geo-fence may be activated or established at this step. For example, a small 3D geo-fence may be activated around a particular floor or set of floors of the structure where the incident is occurring. This geo-fence may represent an area with a high risk. Larger geo-fences may be activated around the perimeter of the structure and around the city block of the structure, representing areas of lesser risk. In some embodiments, 3D geo-fences are activated on each floor of the multi-floor structure, such that the geo-fences form a stacked formation. In other embodiments, a 3D geo-fence may be activated around the entire structure, around a multi-block area with the structure at the center, on a number of specific floors, etc. The 3D geo-fence may assist first responders in quickly assessing not only the geographical location of individuals within the building, but also which floor they are on. Examples of two-dimensional and three-dimensional geo-fences that may be activated or established in step 504 are illustrated in
In some embodiments, one or more geo-fences may be pre-defined in the system 200 based on some static physical feature such as a building, university campus, harbor, etc. For example, the system 200 may assign a geo-fence to each floor of the multi-floor structure. The safety level of the pre-determined geo-fences may be updated according to the proximity and danger level of an incident. In other embodiments, geo-fences may be generated by the system 200 according to the magnitude and nature of the emergency. In particular, geo-fences may be defined in real-time in response to an incident. For example, geo-fences may be defined automatically (at least initially) based on the description, classification, and/or type of the incident. For example, a large fire in a commercial area may be recognized as an incident by the system 200. In this case, the system 200 may generate a geo-fence that includes a number of buildings and conforms to the shape and size of the fire. The formation of geo-fences is further explained in U.S. Pat. No. 9,247,408 and its continuation, U.S. Pat. No. 9,572,002, both of which are hereby incorporated in their entirety by reference.
At step 506, the method 500 may include using stored location data to determine which devices may be close to the incident and/or associated with the multi-floor structure. In that regard, a user device's last known location may be used to geographically associate the device with the multi-floor structure for the purposes of determining whether the user device may be near the incident. In some embodiments, the system 200 is configured to store location information about devices registered with the system 200 or otherwise associated with the system 200 (such as user devices 130 and first responder user devices 162 shown in
At step 508, the method 500 may include sending a request for current location information to all user devices determined to have been previously close to the incident (i.e., the user devices with last known locations within a specific distance from the incident, as discussed above). In some embodiments, this includes the system 200 sending a “silent request” to all devices whose last known location is within the radius determined in step 506. In one embodiment, a silent request means that a user of the device is not aware of the request. In response to the request, the devices may determine their geographical location based on location services such as GPS, Wi-Fi, cellular triangular, etc. Additionally, in response to the request, the devices may scan for signals broadcast by nearby beacons associated with the system 200 (such as beacons 574, 576, 578, 580 discussed in reference to
At step 510, the method 500 may include receiving current location information from devices including geographical information (such as GPS location data) and beacon information in response to the request sent by the system 200. In some embodiments, the location information is received via a wireless communication system forming part of the system 200. At this point, the system 200 may determine both a specific current geographical location and beacon-based location for each device. For example, the system may utilize GPS location data to determine a latitude and longitude of the user device (a “horizontal” location) and may utilize the beacon-based location data to determine on which floor (or a particular location on a floor) of a building a user device is located (a “vertical” location). In one embodiment, the beacon-based information may include a beacon identifier comprising a Universally Unique Identifier (UUID), a major number, and a minor number associated with a multi-floor structure, a particular floor of the multi-floor structure, or even a particular location on the floor, such as a certain room. The system 200 may compare the received beacon identifier with a database of known beacon identifiers, where each beacon identifier is associated with the known location of a beacon. If the received beacon identifier matches a known beacon identifier, the system determines that the user device is physically near the known location of the beacon associated with the known beacon identifier. Further, in some embodiments, when a user device is near multiple beacons, the system may receive a plurality of beacon identifiers and associated proximity indication information from the user device. In such an embodiment, the system may utilize the proximity indication information to determine the beacon to which the user device is physically nearest. In other embodiments, the system may utilize the proximity indication information to more accurately pinpoint the location of a user device at a position between multiple beacons. These locations may be stored within the system 200 and updated periodically.
At step 512, the method 500 may include determining which devices are within the active geo-fence. In some embodiments, the system 200 compares the current locations of the devices received in step 510 with the boundaries of the geo-fence activated in step 504 to determine which devices are within the geo-fence. This comparison may include utilizing both the geographical location information and the beacon-based location information. For example, if the geo-fence encompasses a two-dimensional geographical area, for example, a city block or a defined geometric shape surrounding an incident, the system may utilize the geographical location information to determine if the user device is within the geo-fence. In another example, if the geo-fence encompasses a three-dimensional area such as a multi-floor structure or a portion of a multi-floor structure, then the system may utilize the geographical location information in combination with the beacon-based location information or just the beacon-based location information to determine if the user device is within the geo-fence
At step, 514, the method 500 may include transmitting notifications to user devices determined to be within the active geo-fence in order to notify the individuals associated with the user devices of the incident. In some embodiments, the device is notified via a prompt, a text message, an alarm, a sound, emergency action plans, data from emergency and law enforcement agencies, or other notifications. Notifications sent by the system 200 to the devices may be push messages, for example, messages received by the devices without the device requesting them. In one embodiment, the app instance 584 on a user device 120 (
At step 515, the method 500 includes receiving safety status information from at least some of the user devices notified of the incident in step 514. The safety status information corresponds to the current level of danger perceived by the individual associated with the user device. In one embodiment, the app instance 584 prompts the individual to input his or her current safety status via a user interface displayed on the user device. For example, the individual may be prompted to select from options such as “I'm in danger,” “I need help,” or “I'm OK.” and the like. The collection of individual safety status information via user devices is further explained in U.S. Pat. No. 9,247,408 and its continuation, U.S. Pat. No. 9,572,002, both of which are hereby incorporated in their entirety by reference.
At step 516, the method 500 may include generating a 3D interactive visualization of the locations of user devices in relation to the incident and in relation to structures, landmarks, and the like. The visualization may include any of the visualizations 300, 400, 460, 470, 600, 700 of
The visualization may also include the safety status of individuals. This safety status may include one of several safety status levels, such as “in danger”, “at risk”, “unknown”, and “safe.” The safety status of the individuals may be determined by feedback from the individuals themselves, as well as their proximity to the incident. The locations and safety status of each individual may be updated on the display as time passes and the conditions of the incident change. The display may include a user interface which may display all or part of the information gathered by the system.
In some embodiments, individuals are clustered in various ways within the visualization, as shown in
At step 518, the method 500 may include receiving information regarding the incident from multiple sources. For example, the system 200 may receive information about the incident from any of the sensor systems shown in
At step 520, the method 500 may include receiving location updates from the devices within the active geo-fence. These location updates may be requested by the system 200 similarly to step 508. The location updates may be requested and received by the system 200 periodically, or with varying frequency. In other embodiments, the user devices transmit location updates automatically without further prompting once they receive a notification of an incident. In some embodiments, the frequency at which the location updates are received may vary depending on how close the device is to the incident. For example, the system 200 may receive location updates every minute for a device that is located within the multi-floor structure where the incident is occurring, while the system 200 may receive location update every 15 minutes for a device located a mile from the incident. The frequency may also be varied based on the safety status of an individual corresponding to the device, the remaining battery life of the device, and other factors. The variation in frequency may minimize the information received by the system and avoid oversaturating communication lines.
At step 522, the method 500 may include updating the 3D interactive visualization. In some embodiments, the visualization is updated with location information from the devices, information regarding the incident received from the devices, safety status information for individuals, information received from sensor systems, first responder reports, information from the Internet including social media information, news feeds, official reports on the incident, status updates on the incident, and information from other sources.
At step 524, the method 500 may include determining if the incident is over. In some embodiments, the incident is considered to be over when first responders send a notification to that effect to the system 200. In other embodiments, the system 200 determines that the incident is over when the various sensors systems stop detecting the conditions of an incident. If the system 200 determines that the incident is not over, it continues to receive information from multiple sources in step 518 including safety status information from user devices. If the system 200 determines that the incident is over, the system 200 may notify the devices that the incident is over in step 526. This step 526 may include the system 200 sending an “all clear” notification to the devices. After step 526, the method 500 may repeat, such as when the system 200 detects another incident in step 502.
At step 552, the method 550 may include detecting an incident near or in a multi-floor structure. In some embodiments, the structure is a building like those shown in
At step 554, the method 550 may include locating user devices near the structure (or within, or affixed to) based on location data as described above. Location data may include GPS or wireless communication signals.
At step 556, the method 550 may include transmitting signals to the user devices near the structure to scan for signals broadcast by beacons, such as Low Energy Bluetooth beacons. In one embodiment, the user devices are instructed to turn on their respective Bluetooth radios in order to detect the signals from Bluetooth beacons. In other embodiments, the beacons may broadcast signals using other short-range radio technology.
At step 558, the method 550 may include receiving, from the user devices, beacon identifiers broadcast by the beacons near the user devices. These identifiers may include any of a Universally Unique Identifier (UUID), a major number, and a minor number.
At step 560, the method 550 may include looking up beacon identifiers of the beacons detected to be within the structure by major-minor registration. In some embodiments, the particular registration of each beacon is tied to tiered geo-fences which are tied to the processing capability of the system 200. In some embodiments, the beacons are coded according to varying degrees of granularity. During an incident, the beacon allows communication with the individual through the user device, which may be tied to the geo-fence. This may allow the user device to communicate a registered beacon identification signal to the system 200 and provide for real time temporal data.
At step 562, the method 550 may include detecting the location of user devices, including by floor or z-axis coordinate. It should be understood that the x- and y-coordinates may also be used for horizontal location detection as well.
At step 564, the method 550 may include selecting a floor to see which user devices are located on the floor. In this way, visualizations of the system may be able to track users easily, including in a three-dimensional manner.
At step 566, the method 550 may include communicating with individuals via user devices based on the floor. In this way, the visualization may alert individuals to an incident and gather feedback. In some embodiments, each user device may activate multimodal communications during an incident. This may allow immediate registration of the user device on the floor on which is located, further helping to track users in a three-dimensional manner.
At step 593, the method 590 may include reporting an incident to the interactive emergency visualization system 200 with a device such as user device 130. In some embodiments, the user device 130 is configured to display a selectable incident report button. The incident report button may be any type of selectable area on the device, such as a button, icon, marker, or image. The incident report button may appear on a screen of the device when an incident is detected by the device. In other embodiments, the incident report button is activated by a user upon receiving word of an incident. The incident report button may be an alarm or panic button. Upon activation of the report button, the device may be configured to automatically send a notification to the interactive emergency visualization system. In some embodiments, the incident report button may include a phone call to an emergency response line (such as 9-1-1 or a police department) and/or a phone call directly to the interactive emergency visualization system 200. This phone call may help to verify the incident and provide emergency services to the user of the device.
At step 594, the method 590 may include transferring device information from the device to the interactive emergency visualization system 200. In some embodiments, the device information may include a location and safety status of the device. The location information may include information from location services as well as data from nearby beacons, as discussed in step 510 of method 500. In some embodiments, safety status information for the device may be based on feedback from the device. For example, an individual may select a button on an app running on the device to report that he or she is “in danger” or “safe.” If no information is received from the device, the system may record the safety status of the device as “unknown.” In other embodiments, the safety status of the individual associated with the device is based on the received location information from the device in relation to the incident. For example, if the device is located on a floor of a multi-floor structure where the incident is occurring, the system 200 may determine that the individual associated with the device is “in danger.”
At step 595, the method 590 may include generating a visualization of the incident and device information. In some embodiments, geo-fences in the visualization may be selected and activated by certain users (such as security guards). These geo-fences may be selected using an app on the device, and may require certain credentials. The visualization may include the location of the incident, relative location of the device, one or more geo-fences, the safety status of the device user, and the safety status and location of other individuals near the device.
At step 596, the method 590 may include updating incident and device information. This step may involve updating the visualization as more information about the incident is received by the interactive emergency visualization system. The location and safety status of the device and individual associated with the device may also be updated.
At step 597, the method 590 may include sending updates to the device with the interactive emergency visualization system. These updates may include changing information about the incident, queries about the status of the user of the device, suggestions to the user, etc. The frequency of the updates sent to the device may vary according to distance from the device to the incident. For example, a device that is very close to the incident may receive constant updates whereas a device that is far from the incident may receive updates at longer intervals. Information may be sent from the device to the system at this step, such as location information, messages, and/or media (such as still photos, video, etc.). This information may be visualized by the system in selectable areas.
At step 598, the method 590 may include notifying a device when the incident is resolved. At this step, the device may stop sending location information to the system.
In some embodiments, in order to determine which individuals are located on each floor, one or more beacons 574 may be deployed on each floor. In that regard, the user devices 610 detect their proximity to a beacon on a specific floor and report the beacon detection to the system 200. The system 200 includes a database of beacon locations and, thus, may determine the floor-based location of the user devices 610 based on the location of the detected beacons. Examples of beacons are radio frequency (RF) beacons, Bluetooth Low Energy (BLE) beacons (also known as Bluetooth Smart beacons), Wi-Fi beacons, infrared beacons, Near Field Communication (NFC) beacons, and radio frequency identifier (RFID) tags, and any one, two, or combination of additional types of beacons may be used separately or in a single beacon device to help ensure continuity of signals to and from the beacon. The beacons may communicate with a user device to enable determination of the location of individuals within the geo-fences. In addition to the beacons, user device 610 may utilize data associated with GPS satellites 614, cell tower triangulation 616, and/or WiFi signal origination 618 to determine location.
The visualization 600 may also include one or more one or more proximity zones 630, 632, 634 that represent physical areas of different distances from the location of the incident. These proximity zones 630, 632, 634 may be color-coded in the visualization to represent various danger levels. For example, the dark patterned (or red) proximity zone 634 may represent a dangerous area, the medium-dark patterned (or orange) proximity zone 632 may represent an area at risk, and the medium patterned (or yellow) proximity zone 630 may represent an area with an unknown status. The proximity zones may be updated over time with information about the nature and size of the incident. In the case of a circular geo-fence, the proximity zones may be defined by concentric circles of varying radii extending from the location of the emergency. The visualization 600 may also include a safe zone 636 which may be used as a gathering place for individuals.
The operator may be able to click on the various geo-fences to view a geo-fence status window. For example, a user may click on geo-fence 704 and the geo-fence status window 730 may be displayed, which may include a name for the geo-fence 704, the number of individuals located within the geo-fence 704, and the safety statuses of each individual. In the example of
In some embodiments, the proximity of a user device 130 to the incident may increase the speed of communication between various components. In some embodiments, a user device 130 that is closer to the incident than another device may communicate with a beacon 574 with increased data transmission speed. In some embodiments, a closer user device 130 may communicate more frequently with a beacon 574 than user devices 130 that are further away. The system 200 may also prioritize data transmissions to and from user devices 130 and beacons 574 that are located closer to an incident.
In some embodiment, the data transfer of various user devices is prioritized according to safety status level. For example, the system 200 may communicate to and from user devices in danger at the highest data transfer rate and frequency for accuracy and better visualization. This may allow the system 200 to triage the information and/or may provide critical information faster for users in greater danger or potential danger.
At step 902, the method 900 may include receiving incident information about an incident. This information may come from a number of sensors such as those discussed in relation to
At step 904, the method 900 may include defining geo-fences with an environment. In some embodiments, the environment includes natural or man-made features and may include building layouts or floor plans. In particular, geo-fences may be defined on a per-room basis within a building. These geo-fences may be pre-defined based on a known floor plan, or they may be generated dynamically after the detection of an incident or emergency. In this case, each room of a building may be monitored individually by the system 200.
At step 906, the method may include determining safety status levels for each of the geo-fences. The safety status levels may be determined based on proximity to and nature of an incident. Additionally, the safety status levels for each geo-fence may be determined by the status of individuals within the geo-fence. For example, a geo-fence may be defined around a hallway in a building. An incident may occur in the hallway, such as a fire near one of the exits. As the system 200 receives updates from the individuals calling for help, the system 200 may determine that may of the individuals are in danger. Accordingly, the geo-fence around the hallway may be assigned a safety status level of “in danger.”
At step 908, the method 900 may include detecting individuals within the geo-fences. This step may include tracking the location of individuals as they cross over the edges of the various geo-fences. For example, the system 200 may track the number of individuals entering and exiting the lobby of the building and maintain a tally of the number of individuals inside during a time period.
At step 910, the method 900 may include determining the position of individuals within the geo-fences using location information. In some embodiments, this location information is gathered from beacons located around each geo-fence. For example, the location of an individual in a room may be determined by measuring the distances between the individual and various beacons, and then determining the location of in the individual by triangulation. In other embodiments, the location of individuals within the geo-fences may be determined by other systems, such as WiFi triangulation or Bluetooth signal triangulation.
At step 912, the method 900 may include estimating the safety status of individuals depending on the location of each individual. This step may include estimating the distance of each individual from an incident, as well as determining the size and nature of the incident. In some cases, biographical information may also be used in this calculation. For example, although a young child may be located a distance from a danger area around an incident such as a fire, the system 200 may assign the child a status of “in danger” due to the age of the child and the risk of harm. Similarly, individuals with health problems may be assigned more serious safety statuses than other individuals located at the same distance away from an incident. Individuals may be distinguished by other criteria, including job positions, skill sets, medical knowledge, etc. In some cases, individuals with a certain criteria may be represented differently than other individuals in a visualization. For example, all doctors may appear with a blue color, in the event a doctor on-site may be routed to help another user or first responders in need of medical assistance. In some embodiments, multiple individuals may be connected to or associated with a single user device. For example, a user device may be assigned to a child as well as his or her parent. When an incident is detected, both the parent and child may be notified.
At step 914, the method 900 may include notifying the individuals of their safety status. This notification may be communicated on a mobile device, such as on a view screen. Additionally, the notification may be communicated to individuals on over an intercom, computer screens, advertisement screens, or other methods.
At step 916, the method 900 may include updating visualizations with the status information. These visualizations may include overall visualizations of the incident and surrounding environments, as well as visualizations sent to the individuals affected by the incident. For example, an individual may be inside a building during a fire. The individual may be sent a notification and a visualization showing that the individual is in danger. As the individual leaves the building, his or her visualization may be updated to show that he or she is not in danger after leaving the premises.
At step 1002, the method 1000 may include receiving and displaying map information. In some embodiments, the map information may be used as a basis for the visualization. In particular, satellite photographs or map programs such as Google Earth may be used as a base level of the visualization. In some embodiments, other layers are added to the visualization, which may be viewed together or individually by the operator. The visualization may include any of the visualizations 300, 400, 460, 470, 600, 700 of
At step 1004, the method 1000 may include receiving and displaying information from data sources. These data sources may include floor plans, building diagrams, sensor feeds (such as the sensors shown in
At step 1006, the method 1000 may include receiving incident information. In some embodiments, the incident information may include a time and a location of the incident or emergency. This information may be displayed on the visualization in the form of a symbol or marker such as the incident marker 302 shown in
At step 1008, the method 1000 may include determining and displaying geo-fences. These geo-fences may be determined according to their proximity to the incident or around important features such as buildings or parks. In some embodiments, geo-fences may be grouped in the visualization, such as shown in
At step 1010, the method 1000 may include displaying an expanded view of geo-fences within a certain location. This step may involve the operator selecting a building or other feature on the visualization and zooming into to see more details about it. The geo-fences within the building or other feature may be displayed overlaid on a two-dimensional floor plan. The expanded view may include symbols representing individuals within the geo-fences, such as the individual markers 306 shown in
At step 1012, the method 1000 may include displaying the safety status of individuals within the geo-fences. In some embodiments, the safety status of the individuals is displayed as a pattern, color, shape, or texture on individual symbols. In other embodiments, the safety status of individuals is displayed textually or by one or more symbols.
At step 1014, the method 1000 may include displaying biographical information about individuals. This information may be accessed by the operator clicking the individual marker which may automatically display a window (such as window 810 in
At step 1016, the method 1000 may include displaying an individual safety status list. In some embodiments, this list is similar to the safety status lists 450 of
The geo-fence window 1310 may include information about the name and safety status level of each geo-fence. In the example of
The information displayed in the geo-fence window 1310 may be displayed visually in the map 1320. In some embodiments, the map 1320 is operable to display any of the visualizations depicted in
Still referring to
The sensor list 1340 may include a list of the sensors in the visualization. In some embodiments, this may include sensor systems within a building, such as smoke detectors, gunshot detectors, and CCTV cameras. The sensor list may include the status of each detector, as well as an optional tool 1342 to view the sensor of the map 1320. In some embodiments, the operator may press the tool 1342 to pull up a diagram showing the location and status of each sensor, such as those shown on layer 1120 in
The incident uploads 1350 may include media uploaded by individuals during an incident. A picture 1302 of the individual uploading media may be displayed alongside the media, including videos 1352, images 1354, and other forms of media. The media uploads may include time stamps. As in previous visualizations, the operator may be able to expand portions of the display 1300 by clicking on the windows. Expanded portions may include more detailed information about aspects of the display 1300.
In
In some embodiments, a system includes an interactive emergency visualization system configured to receive information about an incident and information representing locations of a plurality of user devices, each user device being associated with an individual. The interactive emergency visualization system is also configured to determine, based on the location information, which of the user devices are located within a geo-fence encompassing a geographical location of the incident. The system also includes a first tier application executing on a first user device, the first tier application configured to (i) receive, from the interactive emergency visualization system, and display the information about the incident and the information representing locations of the plurality of user devices and (ii) alter the geo-fence. The system also includes a second tier application, different from the first tier application, executing on a second user device, the second tier application configured to (i) receive, from the interactive emergency visualization system, and display a first subset of the information about the incident and a first subset of the information representing locations of the plurality of user devices and (ii) alter the geo-fence if the geo-fence is within the jurisdiction of the individual associated with the second user device. The system also includes a third tier application, different from the first and second tier applications, executing on a third user device, the third tier application configured to (i) receive, from the interactive emergency visualization system, and display a second subset of the information about the incident and a second subset of the information representing locations of the plurality of user devices and (ii) alter the geo-fence if the third user device is within the geo-fence. In one embodiment, the first, second, and third tier applications are the same application configured to receive login credentials via a user interface, wherein the login credentials differentiate options available in the user interface. In one embodiment the second subset of information about the incident and the second subset of the information representing locations of the plurality of user devices are respectively smaller than the first subset of information about the incident and the first subset of the information representing locations of the plurality of user devices.
The example computer system 1500 may include a processor or multiple processors 1502, a hard disk drive 1504, a main memory 1506 and a static memory 1508, which communicate with each other via a bus 1510. The computer system 1500 may also include a network interface device 1512 that provides wired and/or wireless access to communication networks, such as the Internet. The hard disk drive 1504 may include a computer-readable medium 1520, which stores one or more sets of instructions 1522 embodying or utilized by any one or more of the methodologies or functions described herein. The instructions 1522 may also reside, completely or at least partially, within the main memory 1506 and/or within the processors 1502 during execution thereof by the computer system 1500. The main memory 1506 and the processors 1502 also constitute non-transitory, machine-readable media.
While the computer-readable medium 1520 is shown in an exemplary embodiment to be a single medium, the term “computer-readable medium” should be taken to include a single medium or multiple media (e.g., a centralized or distributed database, and/or associated caches and servers) that store the one or more sets of instructions. The term “computer-readable medium” shall also be taken to include any medium that is capable of storing, encoding, or carrying a set of instructions for execution by the machine and that causes the machine to perform any one or more of the methodologies of the present application, or that is capable of storing, encoding, or carrying data structures utilized by or associated with such a set of instructions. The term “computer-readable medium” shall accordingly be taken to include, but not be limited to, solid-state memories, optical and magnetic media. Such media may also include, without limitation, hard disks, floppy disks, NAND or NOR flash memory, digital video disks (DVDs), RAM, ROM, and the like.
Embodiments of the present disclosure include a method for visualizing an emergency, which comprises receiving, at a first time, incident location information describing the geographical location of an incident; displaying on a user interface a map of an area encompassing the location of the incident; displaying a graphical indication of the incident location on the map; receiving, at a second time subsequent to the first time, a first incident-related data element, the first incident-related data element including a content portion and a location portion describing the geographical location from which the first incident-related data element originated; displaying a user-selectable graphical representation of the first incident-related data element at a location on the map corresponding with the geographical location from which the first incident-related data element originated; receiving a user selection of the graphical representation of the first incident-related data element; and displaying, in response to the user selection, the content portion of the first incident-related data element. In some embodiments, the method further comprises showing data elements on the graphical representation occurring during the same time period. In some embodiments the content of the first incident-related data element is selected from one of a video, an image, and textual information. In some embodiments, the method further comprises establishing a geo-fence based on the incident location information; and displaying the geo-fence on the map. In some embodiments, the method further comprises altering the geo-fence based on the first incident-related data element; displaying the altered geo-fence on the map. In some embodiments, the method further comprises receiving a plurality of incident-related data elements; and in response to user input, displaying a subset of the plurality of incident-related data elements. In some embodiments, the subset is a selected based on the content portions of the plurality of incident-related data elements. In some embodiments, the subset is selected based on the respective time at which each incident-related data element originated.
Embodiments of the present disclosure include a method for visualizing an emergency, which comprises: displaying a visualization having three-dimensional depiction of a multi-floor building, each floor being independently selectable by a user; receiving a user selection of one of the floors; displaying a two-dimensional floor plan of the floor, the floor plan depicting a plurality of rooms; graphically differentiating each room based on emergency information about the safety status of each room; and graphically indicating the locations of users within each room. In some embodiments, the method further comprises graphically indicating the safety status of each user. In some embodiments, the method further comprises graphically displaying aggregated user safety statuses as an icon representing a plurality of user devices. In some embodiments, the icon is graphically color-coded according to the relative percentages of safety statuses of the individuals associated with the user devices. In some embodiments, the icon is associated with an icon of a beacon detected by the user devices represented by the icon. In some embodiments, the method further comprises graphically indicating a safe zone.
Embodiments of the present disclosure include defining geo-fences in an incident visualization, which comprises receiving incident information associated with a multi-room building, the information including a location of an incident within the building; defining a geo-fence for each room, the boundaries of each geo-fence corresponding with the boundaries of a respective room; determining a safety level for each room based on the location of the emergency within the multi-room building; receiving location information associated with the location of a user device physically located within the building, the user device being associated with an individual, and the location information indicating in which room the user device is physically located; determining in which geo-fence the user device is located; and assigning a safety status of the individual based on the geo-fence in which the user device is located. In some embodiments, the location information is based a location of a beacon within the multi-room building.
Embodiments of the present disclosure include a method for defining a dynamic emergency route on a visualization, which comprises receiving incident information associated with a multi-room building, the information including a location of an incident within the building; determining a safety level for each room based on the location of the emergency within the multi-room building; receiving location information associated with the location of a user device physically located within the building, the user device being associated with an individual, and the location information indicating in which room the user device is physically located; determining an evacuation route for the individual based on the respective safety levels of the rooms; and transmitting the evacuation route to the user device, such that it can be displayed to the individual. In some embodiments, determining the evacuation route includes determining a route that goes through rooms with the same or higher safety level than the room in which the user device is located. In some embodiments, the evacuation route is does not pass through rooms with a lower safety level than the room in which the user device is located. In some embodiments, the evacuation route is graphical form. In some embodiments, the evacuation route graphically depicts a route though the multi-room building.
The exemplary embodiments described herein may be implemented in an operating environment comprising computer-executable instructions (e.g., software) installed on a computer, in hardware, or in a combination of software and hardware. The computer-executable instructions may be written in a computer programming language or may be embodied in firmware logic. If written in a programming language conforming to a recognized standard, such instructions may be executed on a variety of hardware platforms and for interfaces to a variety of operating systems. Although not limited thereto, computer software programs for implementing the present method may be written in any number of suitable programming languages such as, for example, C, C++, C# or other compilers, assemblers, interpreters or other computer languages or platforms.
Thus, various interactive emergency visualization systems and methods have been described. Although embodiments have been described with reference to specific exemplary embodiments, it will be evident that various modifications and changes may be made to these embodiments without departing from the broader spirit and scope of the system and method described herein. Further, elements of different embodiments in the present disclosure may be combined in various different manners to disclose additional embodiments still within the scope of the present embodiment. For instance, elements from the described environments may be combined, exchanged, or otherwise altered to form additional embodiments. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense.
Claims
1. A computer-implemented method for interactive emergency visualization, which comprises:
- receiving a notification concerning an incident associated with a multi-floor structure;
- establishing a geo-fence encompassing at least a portion of the multi-floor structure;
- determining which of a plurality of user devices were previously within a first distance from the incident based on stored location information received from the plurality of user devices, wherein each user device is associated with an individual;
- transmitting a request for current location information to each of the user devices determined to have previously been within the first distance;
- receiving, in response to the request, current location information from at least a subset of the user devices determined to have previously been within the first distance, wherein the current location information includes both geographical location information and beacon information associated with respective beacons disposed within the multi-floor structure;
- determining, based on the received current location information, which of the plurality of user devices are currently located within the geo-fence; and
- displaying a graphical map illustrating the multi-floor structure, the geo-fence, and the geographical locations of user devices determined to be within the geo-fence, wherein the displaying includes displaying information associating at least one of the user devices with a specific floor of the multi-floor structure based on the detected beacon information.
2. The method of claim 1, wherein establishing the geo-fence includes activating a geo-fence defined before the incident.
3. The method of claim 1, wherein establishing the geo-fence includes defining a physical area associated with the multi-floor structure based on the incident.
4. The method of claim 1, wherein the stored location information was received from the plurality of user devices prior to receiving the notification of the incident.
5. The method of claim 1, wherein the stored location information is indicative of last known locations of the user devices.
6. The method of claim 1, wherein the displaying includes displaying a floor plan of the specific floor within the multi-floor structure along with a location of the at least one user device within the floor plan.
7. The method of claim 6, wherein the displaying the floor plan is performed in response to receiving a user selection of the specific floor on the graphical map.
8. The method of claim 1, further comprising receiving a current safety status of an individual associated with the at least one user device, wherein the displaying includes displaying the current safety status of the individual.
9. The method of claim 8, wherein the current safety status of the individual is visually distinguished by a characteristic of an icon representing the individual in the graphical map.
10. The method of claim 1, further comprising;
- receiving, after receiving the current location information, further location information from the user devices determined to be within the geo-fence; and
- updating the graphical map based on the further location information.
11. A computer-implemented method for interactive emergency visualization, which comprises:
- receiving a notification concerning an incident associated with a multi-floor structure;
- requesting location information from a user device geographically associated with the multi-floor structure;
- receiving, in response to the request, a beacon identifier from the user device, the beacon identifier being associated with a beacon disposed within the multi-floor structure;
- determining on which floor of the multi-floor structure the user device is located based on the beacon identifier and stored information indicating the location of the beacon; and
- displaying a graphical map of the multi-floor structure and information indicating the specific floor on which the user device is located.
12. The method of claim 11, wherein the displaying includes displaying a floor plan of the specific floor on which the user device is located and displaying, in association with the floor plan, an icon representing the user device and an icon representing the beacon.
13. The method of claim 12, wherein the icon representing the user device additionally represents a plurality of user devices associated with the beacon.
14. The method of claim 13, wherein the icon representing the user device visually indicates the number of user devices associated with the beacon.
15. The method of claim 12, wherein the displaying the floor plan is performed in response to receiving a user selection of the specific floor on the graphical map.
16. The method of claim 11, wherein the beacon identifier comprises a first component representing the multi-floor structure and a second component representing a floor of the structure.
17. The method of claim 11, wherein the determining on which floor of the multi-floor structure the user device is located includes comparing the received beacon identifier to a plurality of stored beacon identifiers, where each of the stored beacon identifiers are respectively associated with a location of a beacon.
18. The method of claim 11, further comprising:
- receiving from the user device, in response to the request, a plurality of beacon identifiers associated with a plurality of beacons disposed in the multi-floor structure and receiving respective indications of proximity between the user device and plurality of beacons; and
- determining, based on the indications of proximity, which beacon in the plurality of beacons the user device is most near.
19. The method of claim 18, wherein the displaying includes displaying an icon representing the user device along with an icon representing the beacon in the plurality of beacons most near to the user device.
20. The method of claim 11, wherein requesting location information from the user device includes determining whether the last known location of the user device is within a first distance from the multi-floor structure based on stored location information.
21. A computer-implemented method for interactive emergency visualization, which comprises:
- receiving a notification concerning an incident associated with a multi-floor structure;
- requesting current location information from a plurality of user devices geographically associated with the multi-floor structure, each user device being associated with an individual;
- receiving, in response to the request, current location information from at least a subset of the user devices, wherein the current location information includes beacon information associated with respective beacons disposed within the multi-floor structure;
- determining, based on the received current location information, which of the plurality of user devices are currently located within the multi-floor structure and on which floors;
- receiving, from the user devices determined to be located within the multi-floor structure, safety status information about respective individuals associated with the user devices; and
- displaying a graphical map illustrating the multi-floor structure and information indicating, for each floor of the multi-floor structure, a number of the user devices determined to be on that floor along with the safety status information about the individuals associated with the user devices determined to be on that floor.
22. The method of claim 21, wherein displaying the graphical map includes displaying a three-dimensional image of the multi-floor structure with representations of each floor.
23. The method of claim 22, wherein the representations of the floors visually reflect the safety status information of the individuals associated with the user devices determined to be the respective floors.
24. The method of claim 22, further comprising receiving a user selection of a representation of a specific floor and, in response, displaying a floor plan of the specific floor.
25. The method of claim 24, wherein displaying the floor plan includes displaying icons representing the user devices determined to be on that specific floor overlaid on the floor plan.
26. The method of claim 25, wherein the icons visually indicate the respective safety status information of the individuals associated with the user devices represented by the icons.
Type: Application
Filed: Apr 24, 2017
Publication Date: Oct 26, 2017
Inventors: John A. SOUTH (McLean, VA), Richard Daniel MURPHY, JR. (Silver Spring, MD)
Application Number: 15/495,497