Abstract: A method includes logging, at a processor, user-performed actions in a computer-generated interactive environment. The method also includes determining statistics of the user-performed actions. The statistics indicate at least a frequency of each particular type of user-performed action and a sequential order of the user-performed actions. The method further includes accessing a data structure that includes a plurality of nodes. Each node of the plurality of nodes corresponds to a choice presented within the computer-generated interactive environment. The method also includes linking different nodes of the plurality of nodes based on the statistics to generate sequential action data and applying a set of rules to at least a portion of the statistics to generate character profile data. The method further includes generating a recap of the user-performed actions based on the sequential action data and the character profile data.

Abstract: Example techniques are described for determining a driving route based on factors such as amounts and relative concentrations of different types of vehicles. The amounts and relative concentrations of different types of vehicles includes concentration of degrees of autonomy for the different types of vehicles such as amount and concentrations of autonomous and semi-autonomous vehicles.

Abstract: A method includes logging, at a processor, user-performed actions in a computer-generated interactive environment. The method also includes determining statistics of the user-performed actions. The statistics indicate at least a frequency of each particular type of user-performed action and a sequential order of the user-performed actions. The method further includes accessing a data structure that includes a plurality of nodes. Each node of the plurality of nodes corresponds to a choice presented within the computer-generated interactive environment. The method also includes linking different nodes of the plurality of nodes based on the statistics to generate sequential action data and applying a set of rules to at least a portion of the statistics to generate character profile data. The method further includes generating a recap of the user-performed actions based on the sequential action data and the character profile data.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.

Abstract: Embodiments relate to use of proximity sensors to control a digital interface. More specifically, proximity detection and analysis of the sensors, and translating the proximity into one or more commands is utilized to control the interface. In various embodiments, a system is provided with a set of sensors operatively coupled to a secondary surface. The sensors are in communication with a hub positioned proximal to the sensors. The hub is configured to be in communication with a remote interface. Similarly, the remote interface is configured operatively coupled to a remote physical device (e.g. digital interface). As changes in the sensor position data are measured, the remote interface device communicates an action based on a set of rules. The action is communicated from the interface to the remote physical device and functions to physically transform a functional aspect of the device.