Abstract: The measurement of electrodermal activity (EDA) can be facilitated by a sensing surface. The sensing surface can have a plurality of electrode pairs. An electrode pair can include a first electrode and a second electrode that are electrically isolated from each other. The plurality of electrode pairs can be electrically isolated from each other. A distance between neighboring electrode pairs can be larger than a distance between the first electrode and a second electrode of each electrode pair. One or more sensors can be configured to detect contact with the sensing surface. In response to the one or more sensors detecting contact with the sensing surface, one or more electrode pairs can be selected to be activated. In response to the one or more electrode pairs being selected to be activated, the selected one or more electrode pairs can be activated.

Abstract: Systems, methods, and other embodiments described herein relate to monitoring a vehicle user's reaction to an advertisement. In one embodiment, a method includes, responsive to determining commencement of an advertisement, request a user place a user's hand on an electrodermal activity (EDA) sensor. The EDA sensor is fixed to a dual-sided transparent display. The method includes acquiring EDA data relating to the user via the EDA sensor, determining a reaction of the user to the advertisement based on the EDA data, and transmitting the reaction of the user and at least one characteristic of the advertisement to a third party.

Abstract: Systems and methods for improving the brightness of a transparent display are disclosed herein. One embodiment collects ambient light using an array of Fresnel lenses disposed on an external surface of a vehicle; collects internal light from the vehicle's headlights; filters the ambient light and the internal light to produce filtered ambient light and filtered internal light; generates primary-source light using a light-emitting-diode (LED) light source; and injects, into a transparent edge-lit liquid crystal waveguide display deployed in at least a portion of a window of the vehicle, the primary-source light, the filtered ambient light, and the filtered internal light in a color-synchronized manner. The filtered ambient light and the filtered internal light improve the brightness of the transparent edge-lit liquid crystal waveguide display.

Abstract: A seat blocking system can comprise a seat. The seat can include a seat understructure and an overlying seating surface. The seat understructure can form a seat base and a seatback arranged in a seating configuration. The seating surface can be configured to morph between a sittable shape, in which the seating surface is coextensive with the seat understructure, and an unsittable shape, in which the seating surface is expanded over at least a portion of the seat understructure. The seat blocking system can include a seat blocker. The seat blocker can be integrated with the seat. The seat blocker can be operable to morph between a deactivated state, whereby the seat blocker leaves the seat understructure to impart the sittable shape to the seating surface, and an activated state, in which the seat blocker acts on the seating surface to impart the unsittable shape to the seating surface.

Abstract: Systems and methods for improving the brightness of a transparent display are disclosed herein. One embodiment collects ambient light using an array of metasurface lenses disposed on an external surface of a vehicle; collects internal light from the vehicle's headlights; filters the ambient light and the internal light to produce filtered ambient light and filtered internal light; generates primary-source light using a light-emitting-diode (LED) light source; and injects, into a transparent edge-lit liquid crystal waveguide display deployed in at least a portion of a window of the vehicle, the primary-source light, the filtered ambient light, and the filtered internal light in a color-synchronized manner. The filtered ambient light and the filtered internal light improve the brightness of the transparent edge-lit liquid crystal waveguide display.

Abstract: Dynamically adjustable EDA measurement device may include: a dynamically formable base comprising a soft robotics material, wherein the dynamically formable base comprises a formable surface configured to be dynamically formed in response to input signals; and an EDA sensing layer affixed to the formable surface of the dynamically formable base, the EDA sensing layer comprising a plurality of electrodes arranged on a flexible substrate and configured to be connected to a power supply; wherein, in response to input signals, the formable surface of the dynamically formable base and the EDA sensing layer affixed thereto are reformed into a desired contour.

Abstract: Systems, methods, and other embodiments described herein relate to monitoring a vehicle user's health and initiating a vehicle action based on the user's health and emotional state. In one embodiment, a method includes, responsive to detecting an event based on sensor data, requesting a user place the user's hand on an electrodermal activity (EDA) sensor. The EDA sensor is fixed to a dual-sided transparent display. The method includes acquiring EDA data relating to the user via the EDA sensor, determining a condition of the user based on the EDA data, and implementing a vehicle action in response to the condition of the user.

Abstract: Dynamically adjustable EDA measurement device may include: a dynamically formable base comprising a soft robotics material, wherein the dynamically formable base comprises a formable surface configured to be dynamically formed in response to input signals; and an EDA sensing layer affixed to the formable surface of the dynamically formable base, the EDA sensing layer comprising a plurality of electrodes arranged on a flexible substrate and configured to be connected to a power supply; wherein, in response to input signals, the formable surface of the dynamically formable base and the EDA sensing layer affixed thereto are reformed into a desired contour.

Abstract: A tunable optical metamaterial system includes a tunable optical metamaterial, an actuator module to selectively activate the tunable optical metamaterial, and a control system to selectively control the actuator module. The tunable optical metamaterial includes a substrate composed at least in part of an electroactive polymer (EAP), and an optically active particle array that includes a plurality of optically active elongated members populated spaced apart on the substrate in two or more orientations to form confocal lenses that are optically responsive to the expansion of the substrate. The control module, is configured to control the optical properties of the tunable optical metamaterial by causing the electrical activation of the substrate via the actuator module to selectively expand the substrate in a manner that alters the spacing between the optically active elongated members.

Abstract: An extendable biosensing device comprising a robotic structure. The robotic structure comprises a pliable exterior lining and an extendable core. The robotic structure comprises at least one sensor located on or within the pliable exterior lining. The sensor is configured to measure a physiological condition. The extendable core automatically extends from a retracted state to a deployed state in response to a triggering event.

Abstract: The present disclosure is related to utilizing contactless brainwave detectors to gather a user's unique electroencephalogram (EEG) data. EEG data, as well as an additional biometric, such as gait, can be used to determine whether users have access to enter a locked system, such as a door. An access list can be created and pre-registered with the EEG data and any additional biometric data of users who have access to enter the locked system. As the user nears the locked system, they can generate the EEG data to unlock the locked system by thinking of a pre-registered password stored in the access list.

Abstract: A system for acoustically monitoring a heartbeat includes an acoustic body having a first material in contact with a second material, a density and a propagation speed of sound of the first material is matched with a density and a propagation speed of sound of a human body, and a density and a propagation speed of sound of the second material is matched with the density and the propagation speed of sound of the first material, a covering material in contact with a first surface of the acoustic body formed by the first material, and a microphone acoustically coupled to a second surface of the acoustic body formed by the second material.

Abstract: A surface of a vehicle component can be dynamically deformable surface. The dynamically deformable surface can be configured to undergo deformations to dynamically form a dynamic button or other user interface element on demand. The dynamically deformable surface can include one or more biosensors. When a user engages the dynamic button with a portion of the body, the one or more biosensors can acquire user biodata. The user biodata can be used by the vehicle as input for various purposes. For instance, the vehicle can operate as a health-monitoring and/or comfort monitoring system. As a result of these arrangements, buttons and other user interface elements can appear and disappear depending on the need and/or application, providing a cleaner vehicle cockpit interface and greatly expanding the possibilities of where such buttons can be located at and how many things can be controlled by the driver using physical interfaces.

Abstract: A vehicle can include a window. The window can include an interior side and an exterior side. The vehicle can include a camera operatively positioned to capture visual data of a portion of an exterior environment of the vehicle. The vehicle can include a dual-sided transparent display forming at least a portion of the window. The vehicle can include a processor operatively connected to the camera and the dual-sided transparent display. The processor can be configured to selectively cause the dual-sided transparent display to display exterior visual information on the exterior side. The processor can be configured to cause the dual-sided transparent display to display interior visual information on the interior side. The interior visual information can include the visual data of the portion of the exterior environment of the vehicle.

Abstract: A method for passenger transportation and health monitoring includes determining, with a contactless biomonitoring sensor, a location of one or more passengers within a monitoring area of a vehicle, and generating, with the contactless biomonitoring sensor, a health profile of one or more passengers. The method may also include identifying, with a processor, a health condition, an action, an accompanying item, or combinations thereof of one or more passengers based on the health profile corresponding to the one or more passengers, and determining, with the processor, a vehicle action based on the health condition, the action, the accompanying item, or combinations thereof. The method may further include directing, with the processor, the vehicle to perform the vehicle action.

Abstract: A touchpad for use in an infotainment system and a method of use is provided. The touchpad comprises a bottom layer comprising processing circuitry configured to control operation of a plurality of tactile pixels. The tactile pixels are disposed in a tactile pixel layer on top of the bottom layer. Each tactile pixel comprises a top plate having a plurality of vertices and a support strut coupled to each vertex, each strut comprising a liquid crystal elastomer (LCE) hinge disposed between a first rigid portion and a second rigid portion.

Abstract: Systems and methods for a fluidic elastomer actuator-based handle is provided. A processor determines when a person is approaching a vehicle door and, in response to determining a person is approaching the vehicle door, the processor determines if the door handle is necessary based on a determined intent of the person. If the intent is determined to open the door, the processor manipulates a soft robotics material enclosing the door handle into an in-use state to present the handle to the person through the application of one or more stimuli. When not in a rest state, the soft robotics material provides a smooth surface aligned with a surface of the door panel.

Abstract: A system for acoustically monitoring a heartbeat includes an acoustic body having a first material in contact with a second material, a density and a propagation speed of sound of the first material is matched with a density and a propagation speed of sound of a human body, and a density and a propagation speed of sound of the second material is matched with the density and the propagation speed of sound of the first material, a covering material in contact with a first surface of the acoustic body formed by the first material, and a microphone acoustically coupled to a second surface of the acoustic body formed by the second material.

Abstract: A tunable optical metamaterial system includes a tunable optical metamaterial, an actuator module to selectively activate the tunable optical metamaterial, and a control system to selectively control the actuator module. The tunable optical metamaterial includes a substrate composed at least in part of an electroactive polymer (EAP), and an optically active particle array that includes a plurality of optically active elongated members populated spaced apart on the substrate in two or more orientations to form confocal lenses that are optically responsive to the expansion of the substrate. The control module, is configured to control the optical properties of the tunable optical metamaterial by causing the electrical activation of the substrate via the actuator module to selectively expand the substrate in a manner that alters the spacing between the optically active elongated members.

Abstract: A vehicle subsystem for cleaning a vehicle cabin may include one or more light sources, a sensor module, and a vehicle cleaning control module. The one or more light sources are mounted in the vehicle cabin to project a collimated beam of light to contact one or more target surfaces in the vehicle cabin. The sensor module includes an array of one or more sensors mounted adjacent to the one or more target surfaces, to detect as sensor data the light reflected from the one or more target surfaces. The vehicle cleaning control module includes one or more processors, coupled to the sensor module, to execute a set of instructions to conduct, in response to the detection, specular reflection analysis of the sensor data, and determine, in response to the specular reflection analysis, a state of cleanliness of the vehicle cabin.