A system is provided and includes a receiver and an access module. The receiver is configured to receive a signal transmitted from a portable access device to a vehicle. The access module is configured to generate a differentiated signal based on the received signal, up-sample the differentiated signal to generate a first up-sampled signal, up-sample an expected signal to generate a second up-sampled signal, cross-correlate the first up-sampled signal and the second up-sampled signal to generate a cross-correlation signal, determine, based on the cross-correlation signal, a phase difference between the first up-sampled signal and the second up-sampled signal, determine a round trip time of the signal received by the receiver based on the phase difference, and permit access to the vehicle based on the round trip time.

The present invention relates generally to the field of vehicle key fobs. More specifically, the present invention relates to a vehicle key fob device comprised of a vehicle key fob that has a housing, a flashlight, a biometric scanner, a plurality of LED-illuminated buttons/emblems and a button that allows the color of the LED-illuminated buttons to change. The fob may have a plurality of buttons in differing embodiments, which are preferably illuminated via at least one LED that is positioned below each button. However, in one embodiment a singular large LED may sit below all buttons to illuminate the buttons simultaneously. The at least one LED can also produce any color known in the art, which can be changed by a user by pressing a color change button located on the side surface of the fob.

A vehicle anti-theft device that is operable to inhibit the operation of a keyless vehicle module wherein the present invention includes a first mode and a second mode. The present invention includes a second controller wherein the second controller is installed in a suitable location within a vehicle. The second controller is electrically coupled to the wiring harness of the vehicle wherein a circuit portion thereof is utilized to supply direct current power to the second controller. A key fob is provided wherein the key fob is operably coupled to the second controller. The key fob includes a first switch and a second switch wherein the first switch and second switch transition the present invention between the first mode and second mode. In the first mode of the present invention the second controller inhibits direct current flow to the first controller and as such renders the keyless vehicle module inoperable.

A method for a secure Passive Entry Passive Start (PEPS) authentication protocol measures the walking gait of a user approaching a related vehicle using a passive key device carried by the user. The method also includes measuring the user's gait from the perspective of the vehicle using a vehicle perception system to compare the two and validate the security of an unlock request, authenticate the unlocking session, and protect against relay attacks. The two-factor authentication protocol validates the physical presence and temporal state of the key fob or mobile phone relative to the vehicle using detected key gait measurement (key G-gait) and a vehicle perception-based gait (C-gait) measurement by comparing the independent gaits and generating control commands responsive to consistent and inconsistent measurements.

A vehicular exterior rearview mirror assembly includes a ground illumination module or turn signal indicator that includes at least one light source operable to emit light when electrically powered. A near field communication device communicates utilizing a near field communication (NFC) standard. Responsive to a near field communication-enabled device being present exterior the vehicle, the near field communication device wirelessly receives a communication from the near field communication-enabled device and determines whether the near field communication-enabled device is an authorized device. Responsive to determining that the near field communication-enabled device is an authorized device, the near field communication device authenticates the near field communication-enabled device as an authorized device for communication with the near field communication device. When the near field communication-enabled device is within a threshold distance to the vehicle, the at least one light source is electrically powered.

A vehicle control system (VCS) includes external communication interfaces, such as a Bluetooth interface, for communicating with a user communication and control device, such as a smart phone or a tablet. The user is enabled to operate certain features of the vehicle, such as the remote start, power locks/trunk, climate control, and security features, through the smart phone. The VCS may also communicate with a remote server via the user's smartphone, for example, providing telematics data and receiving service reminders for display to the user on the smartphone, the VCS, or a display built into the vehicle. The VCS may be custom installed in the vehicle using the user's or the installer's smartphone, without a physical connection from the VCS to the smartphone.

The present disclosure relates to methods and associated systems for unlocking a vehicle. The vehicle has a first input device and a second input device. The method includes (1) receiving a passcode from the first input device; (2) receiving a confirmation of the passcode from the second input device; and (3) in response to the confirmation, storing the passcode in a storage device associated with the vehicle. The passcode is input by operating the first input device in a first predetermined way, and, the confirmation is input by operating the second input device in a second predetermined way.

A vehicle information display system includes a digital license plate attachable to a vehicle and having a display able to present electronically readable visual information. This electronically readable visual information is usable to facilitate provision of services, including but not limited to vehicle rental or providing vehicle access to authorized service providers.

A remote control system for a vehicle including: a user terminal; and a vehicle configured to transmit/receive information to/from the user terminal through a communication network. The vehicle performs first authentication on a user by comparing a captured image of the user to a reference image in response to an unlocking signal or start-up request signal received from the user terminal, and transmits second authentication pre-processing information to the user terminal, the second authentication pre-processing information being obtained by generating an encryption key from a feature vector extracted from the image of the user and encrypting unique information of the user. The user terminal performs second authentication on the user by decrypting the second authentication pre-processing information received from the vehicle with a decryption key stored therein.

An engine is prevented from being started by a remote operation in a case where an angle of inclination detected by an acceleration sensor is not within a predetermined angle range in a situation where a shift position is not set to a neutral position in a manual transmission.