A method is presented for controlling power output by a battery in a vehicle. The method includes: measuring voltage of the battery during a sequence of vehicle events to form a time series, where each vehicle event is powered by the battery; constructing an unknown fingerprint from the voltage measurements made during the sequence of vehicle events, where the unknown fingerprint is indicative of a sequence of vehicle events; comparing the unknown fingerprint to the at least one fingerprint; receiving a start signal, where the start signal is a request to start the engine of the vehicle; and, in response to receiving the start signal and based on the comparison of the unknown fingerprint to the at least one fingerprint, outputting electric power from the battery to an electric starter motor of the vehicle.

Systems and methods are provided for adding supervised stops to an autonomous vehicle route. In particular, systems and methods are provided for allowing a primary passenger, who is accompanied by one or more other passengers, to pause a ride, exit the vehicle, and request supervision of the other passengers while the primary passenger is away from the vehicle. Supervision of the other passengers can include monitoring vehicle temperature, making sure the other passengers remain safely inside the vehicle, preventing strangers from accessing the vehicle, providing any requested feedback regarding the other passengers to the primary passenger, and enabling communication between the first passenger and the other passengers.

Improved systems and techniques are disclosed for controlling the security states of anti theft security systems such as product display assemblies using security fobs. The tasks relating to fob authentication are offloaded to a computer system, and these authentications can be based on identifiers for the different security fobs. The computer system can maintain a list of identifiers for authorized security fobs that is easily updated when new security fobs are added to or existing security fobs are de-authorized from the system.

The disclosed vehicle Camera System captures live video and audio to ensure driver protection. Vehicle Camera System introduces a novel, high-quality, vehicle camera system to be mounted on multiple parts of the vehicle, including on the dashboard, side-view mirrors, rear-view mirror, and rear of the vehicle. These cameras are activated as soon as the user pushes the wireless GPS tracking operator button down. The button is located on the inside of the steering wheel and enables the entire system with no abrupt movement. The Vehicle Camera System ensures a fully operational, vehicle camera recording system, and, therefore, guarantees that no victim is wrongfully convicted and is capable of providing exact evidence of the events that occur.

Methods and systems for communicating between autonomous vehicles are described herein. Such communication may be performed for signaling, collision avoidance, path coordination, and/or autonomous control. A computing device may receive data for the same road segment from autonomous vehicles, including (i) an indication of a location within the road segment, and (ii) an indication of a condition of the road segment. The computing device may generate, from the data for the same road segment, an overall indication of the condition of the road segment, which may include a recommendation to vehicles approaching the road segment. Additionally, the computing device may receive a request from a computing device within a vehicle approaching the road segment to display vehicle data. The overall indication for the road segment may then be displayed on a user interface of the computing device.

A vehicular exterior door handle assembly includes a base portion configured to mount at an exterior door handle region of a vehicular door of a vehicle, a handle portion, and a sensing module that includes a light emitter and a light sensor. With the base portion of the handle assembly mounted at the exterior door handle region of the vehicular door, the light emitter is episodically energized to emit light. When the light emitter is not energized to emit light, the light sensor senses ambient light at the handle portion, and when the light emitter is energized to emit light, the light sensor senses emitted light emitted by the light emitter. The sensing module determines presence of a person's hand at the handle portion based at least in part on a difference between the sensed ambient light and the sensed emitted light being below a threshold light level.

The invention discloses an electronic sound signaling system that generates warning sounds in the forward and reverse mode of operation of a vehicle. The signaling system incorporates an electronic circuit with a standard automotive horn or alarm device in place of mechanical contacts or circuit breakers. The electronic circuitry includes electronically powered programmable microcontroller, a horn driver circuit, voltage sensing circuit, on a printed circuit board (PCB) Assembly and one or more sensors. The sound signaling system uses the standard automotive horn device to generate warning sounds in response to one or more sensor signals. The system also performs multiple functions and is compatible to operate in different voltage ranges. The system has many advantages, including increased reliability, increased operating voltage range, reduced circuit complexity, reduced cost and reduced ambient noise.

An affixable device can include a locking mechanism, a force-limiting mechanism, and a sensing mechanism. The locking mechanism can include an engagement component configured to disable the locking mechanism. The force-limiting mechanism can be configured to limit a locking force of the locking mechanism. The sensing mechanism can be coupled to the engagement component, and can be configured to determine that the force-limiting mechanism has limited the locking force of the locking mechanism. In response to determining the force-limiting mechanism limiting the locking force, the sensing mechanism can cause the engagement component to disable the locking mechanism.

Techniques for using a detector coupled to a controller area network (CAN) bus of a vehicle system to identify and generate alerts in response to wake-up attacks on the vehicle system. Techniques include an electronic control unit (ECU) sending a wake-up message across the CAN bus that is detected by the detector. The detector includes memory and a processor to identify the timestamp of the wake-up message when the vehicle ignition is off. The detector determines a total operational time for the ECU over an observation time period and generates a notification of a wake-up anomaly when the total operational time over the observation time period exceeds a predetermined threshold.

Techniques for using a detector coupled to a controller area network (CAN) bus of a vehicle system to identify and generate alerts in response to wake-up attacks on the vehicle system. Techniques include an electronic control unit (ECU) sending a wake-up message across the CAN bus that is detected by the detector. The detector includes memory and a processor to identify the timestamp of the wake-up message when the vehicle ignition is off. The detector determines a total operational time for the ECU over an observation time period and generates a notification of a wake-up anomaly when the total operational time over the observation time period exceeds a predetermined threshold.