The invention relates to a processing unit, a system, and a computer-implemented method for a vehicle interior, for detecting and reacting to odors of a vehicle occupant.

The described systems and methods determine a driver's fitness to safely operate a moving vehicle based at least in part upon observed impairment patterns. A smart ring, wearable on a user's finger, continuously monitors impairment levels. This impairment data, representing impairment patterns, can be utilized, in combination with driving data, to train a machine learning model, which will predict the user's level of risk exposure based at least in part upon observed impairment patterns. The user can be warned of this risk to prevent them from driving or to encourage them to delay driving. In some instances, the disclosed smart ring system may interact with the user's vehicle to prevent it from starting while the user is in a state of impairment induced by substance intoxication.

A system for transdermal alcohol sensing to be worn near a skin surface of a user, including: an alcohol sensor; a microporous membrane; a housing coupled to the alcohol sensor and the membrane, defining a volume between the alcohol sensor and a first membrane side, and fluidly isolating the volume from a second membrane side opposing the first membrane side; an electronics subsystem electrically coupled to the alcohol sensor, operable to power and receive signals from the alcohol sensor; and a fastener operable to position the second membrane side proximal the skin surface.

A system for transdermal alcohol sensing to be worn near a skin surface of a user, including: an alcohol sensor; a microporous membrane; a housing coupled to the alcohol sensor and the membrane, defining a volume between the alcohol sensor and a first membrane side, and fluidly isolating the volume from a second membrane side opposing the first membrane side; an electronics subsystem electrically coupled to the alcohol sensor, operable to power and receive signals from the alcohol sensor; and a fastener operable to position the second membrane side proximal the skin surface.

a substrate configured to be positioned in the presence of a fluid; a first electrode comprising a conductive film disposed on the substrate; and a second electrode comprising the conductive film disposed on the substrate and spaced from the first electrode. The device may further include a current measurement circuit configured to: apply a voltage between the first electrode and the second electrode, wherein the voltage is in an electrochemical active range of the conductive film such that a portion of the conductive film dissolves into the fluid; and transmit, to a processor, a signal indicating a current measurement of an electrical current flowing through the fluid including the dissolved portion of the conductive film.

a substrate configured to be positioned in the presence of a fluid; a first electrode comprising a conductive film disposed on the substrate; and a second electrode comprising the conductive film disposed on the substrate and spaced from the first electrode. The device may further include a current measurement circuit configured to: apply a voltage between the first electrode and the second electrode, wherein the voltage is in an electrochemical active range of the conductive film such that a portion of the conductive film dissolves into the fluid; and transmit, to a processor, a signal indicating a current measurement of an electrical current flowing through the fluid including the dissolved portion of the conductive film.

An electrochemical sensor that includes a substrate and a piezoelectric semiconductor which is configured to detect ascorbic acid using piezo-electrocatalysis. The piezoelectric semiconductor is coupled to the substrate. The piezoelectric semiconductor includes a nanostructured semiconducting ZnO catalyst. The nanostructured semiconducting ZnO catalyst has a noncentrosymmetric wurtzite configuration. The nanostructured semiconducting ZnO catalyst is shaped as a nanorod and/or a nanosheet.

An electrochemical sensor that includes a substrate and a piezoelectric semiconductor which is configured to detect ascorbic acid using piezo-electrocatalysis. The piezoelectric semiconductor is coupled to the substrate. The piezoelectric semiconductor includes a nanostructured semiconducting ZnO catalyst. The nanostructured semiconducting ZnO catalyst has a noncentrosymmetric wurtzite configuration. The nanostructured semiconducting ZnO catalyst is shaped as a nanorod and/or a nanosheet.

There is provided a system (100) and method for determining a water or lipid level of skin. The system (100) comprises at least two electrodes (108) suitable for contacting skin, and a signal generator (106) configured to generate an electrical signal at a frequency across the at least two electrodes (108). The system (100) is configured to measure a conductivity between the at least two electrodes (108). The system (100) is further configured to determine a water or lipid level of skin based on the measured conductivity and the frequency of the electrical signal.

There is provided a system (100) and method for determining a water or lipid level of skin. The system (100) comprises at least two electrodes (108) suitable for contacting skin, and a signal generator (106) configured to generate an electrical signal at a frequency across the at least two electrodes (108). The system (100) is configured to measure a conductivity between the at least two electrodes (108). The system (100) is further configured to determine a water or lipid level of skin based on the measured conductivity and the frequency of the electrical signal.