A method and a system of deploying ignition interlock device functionality. The method comprises receiving data in authentication of a user account associated with the IID; rendering a user interface at the mobile computing device, the user interface including indication of a status of the user account associated with the IID; and receiving a selection of a user action responsive to the status of the user account associated with the IID.

A method and a system of deploying ignition interlock device functionality. The method comprises receiving data in authentication of a user account associated with the IID; rendering a user interface at the mobile computing device, the user interface including indication of a status of the user account associated with the IID; and receiving a selection of a user action responsive to the status of the user account associated with the IID.

A system for contemporaneously calibrating a gaze-tracking system and authorizing access to a first other system can include a processor and a memory. The memory can store a preliminary operations module, an authorization module, and a gaze-tracking module. The preliminary operations module can include instructions to compare a trajectory, of a point of gaze of an eye, with a pattern associated both with a calibration of the gaze-tracking system and with a first authorization process, that excludes an iris recognition process, for the first other system. The authorization module can include instructions to cause an access to the first other system to be authorized. The gaze-tracking module can include instructions to: (1) cause the gaze-tracking system to be calibrated and (2) cause, in response to the gaze-tracking system being calibrated, the gaze-tracking system to be configured to be a user interface for a second other system.

A system for contemporaneously calibrating a gaze-tracking system and authorizing access to a first other system can include a processor and a memory. The memory can store a preliminary operations module, an authorization module, and a gaze-tracking module. The preliminary operations module can include instructions to compare a trajectory, of a point of gaze of an eye, with a pattern associated both with a calibration of the gaze-tracking system and with a first authorization process, that excludes an iris recognition process, for the first other system. The authorization module can include instructions to cause an access to the first other system to be authorized. The gaze-tracking module can include instructions to: (1) cause the gaze-tracking system to be calibrated and (2) cause, in response to the gaze-tracking system being calibrated, the gaze-tracking system to be configured to be a user interface for a second other system.

Described herein is an electric motor drive system, including at least one power phase line, an external controller configured to generate a drive signal and provide the drive signal to the at least one power phase line, and motor electronics. The motor electronics include at least one switch coupled between the at least one power phase line and at least one electric motor terminal, and an internal controller configured to cooperate with the external controller to perform an authentication process therebetween. The external controller is further configured to cause the at least one switch to electrically couple the at least one power phase line to the at least one electric motor terminal in response to success of the authentication process.

Described herein is an electric motor drive system, including at least one power phase line, an external controller configured to generate a drive signal and provide the drive signal to the at least one power phase line, and motor electronics. The motor electronics include at least one switch coupled between the at least one power phase line and at least one electric motor terminal, and an internal controller configured to cooperate with the external controller to perform an authentication process therebetween. The external controller is further configured to cause the at least one switch to electrically couple the at least one power phase line to the at least one electric motor terminal in response to success of the authentication process.

The present invention relates to a biometric steering wheel including biometric sensors for scanning biometrics of a user and a display screen for displaying biometric authentication status. The invention also discloses a biometric based anti-theft and anti-carjacking system for a vehicle using the biometric steering wheel. An on-board controller is coupled to an ECU of the vehicle and is configured to enable the ignition and gear system of the vehicle upon a successful biometric authentication and to disable the ignition and gear system of the vehicle upon an unsuccessful biometric authentication. The on-board controller stores registered biometrics for comparison that are used for authentication of the present biometrics. The steering wheel can be configured to use and ‘read’ fingerprints, retinas, DNA samples, and/or face recognition as a biometric.

The present invention relates to a biometric steering wheel including biometric sensors for scanning biometrics of a user and a display screen for displaying biometric authentication status. The invention also discloses a biometric based anti-theft and anti-carjacking system for a vehicle using the biometric steering wheel. An on-board controller is coupled to an ECU of the vehicle and is configured to enable the ignition and gear system of the vehicle upon a successful biometric authentication and to disable the ignition and gear system of the vehicle upon an unsuccessful biometric authentication. The on-board controller stores registered biometrics for comparison that are used for authentication of the present biometrics. The steering wheel can be configured to use and ‘read’ fingerprints, retinas, DNA samples, and/or face recognition as a biometric.

A remote control system for a marine vessel includes at least one fob and a configuration control system configured to detect available devices on the marine vessel to be controlled remotely for the marine vessel, generate a list of available functions for at least one user-selectable fob command based on the detected available devices, present the list of available functions to the user via a fob configuration user interface such that the user can select one or more functions in the list of available functions, identify a system command associated with each selected function so as to configure a set of system commands based on the user-selected functions, and store the user-configured set of system commands in association with the fob identification and the selected fob command. The system further includes a helm transceiver module to effectuate activation/deactivation of the available devices based on the user-configured set of system commands.

A remote control system for a marine vessel includes at least one fob and a configuration control system configured to detect available devices on the marine vessel to be controlled remotely for the marine vessel, generate a list of available functions for at least one user-selectable fob command based on the detected available devices, present the list of available functions to the user via a fob configuration user interface such that the user can select one or more functions in the list of available functions, identify a system command associated with each selected function so as to configure a set of system commands based on the user-selected functions, and store the user-configured set of system commands in association with the fob identification and the selected fob command. The system further includes a helm transceiver module to effectuate activation/deactivation of the available devices based on the user-configured set of system commands.