A vehicle includes a confirmation section that confirms, at a time of vehicle door locking, whether or not an information processing device configured to be used to perform the vehicle door locking, is inside the vehicle; a determination section that, in a case in which it has not been confirmed by the confirmation section that the information processing device is inside the vehicle, determines whether or not vibration or movement of the information processing device has been detected within a predetermined period of time from the door locking; and an actuation section that, in a case in which vibration or movement of the information processing device has not been detected by the determination section, actuates an alarm.

An alarm system and method of protecting a property from intrusion is disclosed. The property can be a vehicle that includes the alarm system. The alarm system includes an exterior camera for obtaining an exterior camera image data, an interior camera for obtaining an interior camera image data, and a processor. The processor is configured to determine first threat indicator for a potential intruder from the exterior camera image data, determine a second threat indicator for the potential intruder from the interior camera image data, determine a fused threat estimate indicative of an intention of the potential intruder from the first threat indicator and the second threat indicator, determine a consolidated threat estimate from the fused threat estimate and a contextual information for the property, and provide an alarm to protect the property from intrusion based on the consolidated threat estimate.

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.

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.

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.

Provided is a vehicle, including: a communicator configured to perform communication with a user terminal or a remote control device; a sensor configured to acquire surrounding information of the vehicle; and a controller including a processor configured to process the surrounding information. The controller is configured to identify a location of the remote control device based on the communication and transmit a warning message to the user terminal when an obstruction is identified between the identified location of the remote control device and a location of the vehicle, based on processing the surrounding information.

The disclosed embodiments generally provide visual and/or audio cues to a user to guide the user to a vehicle pickup-drop-off (PuDo) location, such as an autonomous vehicle (AV) PuDo. The user’s current location is determined based on information from the user’s mobile device. A path is determined from the user’s current location to the designated PuDo location, and instructions (e.g., turn-by-turn directions) to reach the designated PuDo are displayed on the user’s mobile device, for example, using an augmented reality (AR) interface on their mobile device that is updated in real-time. Disclosed embodiments also allow vehicles to authenticate the identity of a user before allowing entry of the user into the vehicle based on a sequence of hand gestures performed by the user that are detected by exterior sensors (e.g., camera, LiDAR) of the vehicle.

An apparatus includes a vehicle control system (VCS) coupled to a computer of a vehicle via a CAN bus and configured to present selectively appearance of a presence in the vehicle of a smartkey, e.g., by energizing and de-energizing an actual smartkey of the vehicle. The VCS includes a VCS and a Bluetooth® VCS transceiver. The VCS stores VCS software. The apparatus also includes a smartphone with a Bluetooth® transceiver, and storing an app. The mobile device is paired with the VCS to communicate with the VCS via a Bluetooth® link. The app configures the smartphone to receive menu selections from a user, to generate communications that identity smartkey-enabled features of the VCS that correspond to the selections, and to send to the VCS the communications through the link. The VCS software configures the VCS to receive the communications and cause the vehicle to perform actions corresponding to live communications.

Disclosed is a system for detecting an operating state of a vehicle engine. The system comprises: an input coupled to a power line of a vehicle; means to filter out relatively high frequency transient noise components of a signal received from the power line; a first detector for receiving the filtered signal and detecting when transient noise associated with the power line rises above a first threshold and generating a first detection signal in response thereto; a second detector for receiving the filtered signal and detecting when the transient noise falls below a second threshold, which is lower than the first threshold, and generating a second detection signal in response thereto; and means for generating a first output signal in response to the first detection signal and a second output signal in response to the second detection signal.

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.