Abstract: Systems and methods for wayfinding in hazardous environments are disclosed. In one embodiment, a method for wayfinding in a hazardous environment may include: (1) receiving, at an emergency response computer program executed by an electronic device, a plurality of real time streams of data, each real time stream of data from a sensing device in an area; (2) detecting, by the emergency response computer program, an alarm condition in the area based on the real-time streams of data; (3) determining, by the emergency response computer program, that the alarm condition satisfies an alarm condition rule; (4) calculating, by the emergency response computer program, a plurality of routes to an egress point from the area; and (5) controlling, by the emergency response computer program, a digital signage in the area to display one of the plurality of routes the egress point.

Abstract: A method performs location-based multi-factor authentication. The method includes a mobile device that receives a first set of authentication credentials provided by a user, and transmits the first set of authentication credentials to an authentication server, which verifies the first set of authentication credentials. The authentication server transmits verified first factor authentication to the mobile device that sends a request for second factor authentication to an authentication system, which causes the mobile device to scan identifier information associated with a secure device, the secure device then sending a second set of authentication credentials to the authentication system. The authentication system verifies the second set of credentials system and transmits verified second factor authentication to the authentication server, which subsequently grants final authentication based on the verified first factor authentication and the verified second factor authentication.

Abstract: Systems and methods for uniquely identifying and regularly authenticating users at login are disclosed. A method may include an authentication computer program receiving a user identifier for a user as part of a login attempt from a workstation computer program; communicating a multifactor authentication request to an authenticator application executed on a user mobile electronic device; receiving a response to the multifactor authentication request from the authenticator application; verifying that the response to the multifactor authentication request matches an expected value; and saving user activity data associated with the login attempt, and a user trust computer program calculating a user trust score based on the user activity data; determining that the user trust score is above a threshold; and authorizing the login attempt to the workstation and a user session on the workstation.

Abstract: Systems and methods for wayfinding in hazardous environments are disclosed. In one embodiment, a method for wayfinding in a hazardous environment may include: (1) receiving, at an emergency response computer program executed by an electronic device, a plurality of real time streams of data, each real time stream of data from a sensing device in an area; (2) detecting, by the emergency response computer program, an alarm condition in the area based on the real-time streams of data; (3) determining, by the emergency response computer program, that the alarm condition satisfies an alarm condition rule; (4) calculating, by the emergency response computer program, a plurality of routes to an egress point from the area; and (5) controlling, by the emergency response computer program, a digital signage in the area to display one of the plurality of routes the egress point.

Abstract: A method performs location-based multi-factor authentication. The method includes a mobile device that receives a first set of authentication credentials provided by a user, and transmits the first set of authentication credentials to an authentication server, which verifies the first set of authentication credentials. The authentication server transmits verified first factor authentication to the mobile device that sends a request for second factor authentication to an authentication system, which causes the mobile device to scan identifier information associated with a secure device, the secure device then sending a second set of authentication credentials to the authentication system. The authentication system verifies the second set of credentials system and transmits verified second factor authentication to the authentication server, which subsequently grants final authentication based on the verified first factor authentication and the verified second factor authentication.

Abstract: Embodiments disclosed herein provide for systems and methods for authenticating a mobile device. The systems and methods provide for a wireless, touchless multi-factor authentication process for the mobile device, wherein a first factor of authentication includes providing authentication credentials to the mobile device and a second factor of authentication includes scanning a physical identification at a secure device.

Abstract: Systems, methods, and devices for WiGig computing are disclosed. In one embodiment, a system may include a wearable computing device having a computer processor, a first WiGig interface, and a sensor that senses whether the wearable computing device is being worn by a user. The sensor either enables the WiGig interface when it senses that the wearable computing device is being worn, or disables the WiGig interface when it senses that the wearable computing device is not being worn. The system may also include a display device having a display, a second WiGig interface, and a human interface device that receives a human input. The wearable computing device transmits display data to the display device using a WiGig communication network, and receives human input data from the display device using the WiGig communication network so that the wearable computing device functions as a central processing unit for the display device.

Abstract: Embodiments disclosed herein provide for systems and methods for authenticating a mobile device. The systems and methods provide for a wireless, touchless multi-factor authentication process for the mobile device, wherein a first factor of authentication includes providing authentication credentials to the mobile device and a second factor of authentication includes scanning a physical identification at a secure device.

Abstract: Systems, methods, and devices for WiGig computing are disclosed. In one embodiment, a system may include a wearable computing device having a computer processor, a first WiGig interface, and a sensor that senses whether the wearable computing device is being worn by a user. The sensor either enables the WiGig interface when it senses that the wearable computing device is being worn, or disables the WiGig interface when it senses that the wearable computing device is not being worn. The system may also include a display device having a display, a second WiGig interface, and a human interface device that receives a human input. The wearable computing device transmits display data to the display device using a WiGig communication network, and receives human input data from the display device using the WiGig communication network so that the wearable computing device functions as a central processing unit for the display device.

Abstract: Systems, methods, and devices for WiGig computing are disclosed. In one embodiment, a system may include a wearable computing device having a computer processor, a first WiGig interface, and a sensor that senses whether the wearable computing device is being worn by a user. The sensor either enables the WiGig interface when it senses that the wearable computing device is being worn, or disables the WiGig interface when it senses that the wearable computing device is not being worn. The system may also include a display device having a display, a second WiGig interface, and a human interface device that receives a human input. The wearable computing device transmits display data to the display device using a WiGig communication network, and receives human input data from the display device using the WiGig communication network so that the wearable computing device functions as a central processing unit for the display device.

Abstract: Systems, methods, and devices for WiGig computing are disclosed. In one embodiment, a system may include a wearable computing device having a computer processor, a first WiGig interface, and a sensor that senses whether the wearable computing device is being worn by a user. The sensor either enables the WiGig interface when it senses that the wearable computing device is being worn, or disables the WiGig interface when it senses that the wearable computing device is not being worn. The system may also include a display device having a display, a second WiGig interface, and a human interface device that receives a human input. The wearable computing device transmits display data to the display device using a WiGig communication network, and receives human input data from the display device using the WiGig communication network so that the wearable computing device functions as a central processing unit for the display device.