A ride-sharing assistance system includes a plurality of terminals and a ride-sharing assistance apparatus capable of communicating with each of the plurality of terminals. The ride-sharing assistance apparatus sends, when the number of inquiry signals received from at least two terminals of the plurality of terminals for requesting inquiry about a parking space available at a same destination is greater than a vacancy reference value in accordance with the number of available parking spaces within a certain range from the destination, a suggestion signal for suggesting ride-sharing on a vehicle owned by any one of users of the at least two terminals, from which the inquiry signal has been sent, to each of the at least two terminals from which the inquiry signal has been sent.

A route guidance apparatus includes: a reservation information communications unit to receive reservation information which includes at least one of a parking-reserved space of the parking lot, a vehicle type, a vehicle number, and a parking time; a reserved vehicle recognition unit to recognize a vehicle number of a reserved vehicle and determine whether the reserved vehicle enters or exits the parking lot; a traffic flow determination unit that divides an area of each floor of the parking lot into a plurality of unit areas and calculates density within the parking lot based on the number of vehicles within each divided unit area; and a parking route generation unit and an exit route generation unit that respectively generate an optimal parking route and an optimal exit route based on the calculated density; and a route guidance unit to provide the user with the generated optimal parking and exit routes.

An automated valet parking system, an automated valet parking method, an automated valet parking infrastructure, and a vehicle having an automated valet parking feature each enable an unmanned vehicle to autonomously move to and park in a designated parking spot by communicating with the infrastructure. An unmanned vehicle can autonomously move to a pickup area from a parking spot by communicating with the infrastructure.

A system and method to manage a parking area. The system may include one or more tags; a license plate reader configured to read license plates; and a tag reader configured to, in response to a license plate read by the license plate reader, read the tag and determine whether the read license plate belongs to an authorized or unauthorized vehicle.

An autonomous driving method, an autonomous driving apparatus, a computer-readable storage medium, and a computer program product are provided. The method includes: receiving first driving-related information of a first road section ahead of a road on which a first vehicle currently drives and information about a parking waiting area that are sent by a network side device, where the parking waiting area is used to park the first vehicle before the first vehicle drives into the first road section (S304); then determining, based on the first driving-related information, that the first road section does not meet an autonomous driving condition requirement of the first vehicle (S305); finally, controlling the first vehicle to drive into the parking waiting area (S306).

A parking location guidance apparatus includes a vehicle detector that detects a vehicle entering a parking lot having a plurality of gates, a departure information reflecting device that reflects leaving time information and destination information of the vehicle, an exit-specific time reflecting device calculates a time required for the vehicle to exit for each gate based on the leaving time information and the destination information, and a parking location guidance device that selects, as a parking location, a location adjacent to an optimal gate, from among the gates, according to the time required for the vehicle to exit for each gate and transmits the parking location to the vehicle.

A computer-implemented method comprises: continuously monitoring, by an assisted-driving (AD) system using a sensor, surroundings of a vehicle being controlled by a driver; detecting, by the AD system using the sensor, a parking spot that is available; planning, by the AD system and in response to detecting the parking spot, a trajectory for the vehicle to park in the parking spot; and generating a prompt to the driver, by the AD system and in response to detecting the parking spot, to have the AD system handle parking of the vehicle in the parking spot, the prompt performed before the vehicle reaches the parking spot.

The various systems and methods disclosed herein provide for a secure, cost effective, and high accuracy location detection. In some embodiments of the system and method for high accuracy location detection, a mobile location device obtains and calculates location data from a plurality of sources without requiring expensive and power inefficient processors. In some embodiments, such secure, cost effective, and high accuracy location detection by the mobile location device is used in improved parking and payment management systems and methods. In some such embodiments, the location device communicates with remote geomapping servers and payment systems to provide automated parking and payment.

A vehicular communication system includes a wireless communication sensor at a vehicle equipped with the vehicular communication system for receiving wireless communication data from remote wireless communication devices. A global positioning system is operable to determine a geographical location of the vehicle. An electronic control unit (ECU) includes electronic circuitry and associated software that includes a processor for processing wireless communication data received by the wireless communication sensor and position information determined by the global positioning system. The ECU, responsive at least in part to determination that position information determined by the global positioning system is compromised, determines, via processing the received wireless communication data, distances to a plurality of the remote wireless communication devices. The ECU, responsive to determining the distances to the plurality of the remote wireless communication devices, determines a position of the vehicle relative to the plurality of the remote wireless communication devices.

A controller of an information processing apparatus is configured to acquire information indicating a loudness of sound emitted by a second vehicle parked within a predetermined range from a first vehicle or a vehicle height of the second vehicle, and in a case in which the controller determines that the loudness or the vehicle height exceeds a predetermined first threshold, the controller provides a predetermined notification to the first vehicle via a communication interface.