The invention relates to a method for transmission of a secure virtual key (VK) from a server (50, S) to a mobile terminal (20, T) capable of communicating with the server (50, S), comprising the steps of: a) reception by the server (50, S) of a certification request from the mobile terminal (20, T), b) provision and downloading on the mobile terminal (20, T), by the server (50, S), of a user application (25), and c) provision of the mobile terminal (20, T), by the server (50, S), with a virtual key (VK), and d) downloading and securing of the virtual key (VK) in a security element (27) of the mobile terminal (20, T), characterised in that said security element is formed by an encrypting software environment (27).

The present invention provides an intelligent security system, where the system includes an in-vehicle information detection apparatus, a telecommunication server, a smartphone, and an unlocking apparatus, where the in-vehicle information detection apparatus sends collected instant vehicle information to the telecommunication server; the network server sends processed instant vehicle information to the smartphone by using a signal; the smartphone sends mobile phone control signal to the telecommunication server; the telecommunication server sends the mobile phone control signal to the in-vehicle information detection apparatus; the unlocking apparatus sends an unlocking signal to the in-vehicle information detection apparatus; and the smartphone and the unlocking apparatus receive a detection signal of an in-vehicle hardware apparatus. The present invention belongs to the technical field of electronic products. An objective of the present invention is to provide an intelligent security system having a real-time anti-theft function and a function of real-time information sharing after a vehicle is stolen.

Systems and methods disclosed herein include providing an on-sale vehicle, receiving an access request for the on-sale vehicle from a buyer, approving the access request, transmitting at least one authentication key, confirming an identity of the buyer, initiating a test drive, monitoring the test drive, and completing a transaction upon conclusion of the test drive including revoking the at least one authentication key in response to the buyer not purchasing the on-sale vehicle or revoking an authentication key of a prior titleholder in response to the buyer purchasing the on-sale vehicle.

A smart key system includes a first transmitting unit, a first receiving unit, and a certification unit that are mounted on a vehicle, and a second receiving unit and a second transmitting unit that are mounted on a portable device. The certification unit performs certification processing of the portable device when the first receiving unit has received a reply signal. The first transmitting unit transmits the polling signal at a transmission timing that is later or earlier than a transmission timing based on the polling signal before the predetermined manipulation is performed, by a predetermined time shorter than a predetermined transmission cycle, when the predetermined manipulation has been performed in a situation where the certification unit does not certify the portable device.

A vehicle includes a communication interface, a sensor configured to detect biological information for a user of the vehicle, and a controller configured to perform electronic payments. The controller receives authentication information from a first terminal apparatus using the communication interface and acquires the biological information from the sensor when a first authentication using the received authentication information succeeds. The controller acquires authorization information indicating authorization to perform an electronic payment for the user, who is associated with the authentication information, when a second authentication using the acquired biological information succeeds.

The invention relates to a method (100) for remotely controlling at least a first function of a security device (1) of a vehicle (2), wherein a remote control device (10) has a first radio unit (12), whereby a connection to a mobile radio network (4) can be established. According to the invention, the following steps are carried out: a) determining the position of the vehicle (2) b) determining the position of the remote control device (10) c) determining an actual distance (20) between the position of the vehicle (2) and the remote control device (10) d) comparing the actual distance (20) with at least one defined specified distance (21), wherein the first function is activated if the actual distance (20) is less than or equal to the specified distance (21).

This disclosure relates to a method and system for exchanging data between users of a vehicle, including a main user equipped with a first personal electronic device and a secondary user equipped with a second personal electronic device. The method includes a preparatory phase and a transmission phase, which comprise the following steps: the application installed on the first personal electronic device sends data to a remote server including the second email address of the secondary user and instructions for the transfer of information regarding the vehicle; the remote server sends data to an information cloud including the mobile identifier assigned to the application installed on the second device and information regarding the vehicle, and the cloud sends information regarding the vehicle to the application installed on the second personal electronic device.

A long-range power-efficient multiple-band identification system and method includes, for example, a base-station control module and paired electronic key fob. The base-station control module and paired electronic key fob is arranged to provide a UHF (ultra-high frequency) wake transmitter for transmitting a wakeup signal in a UHF frequency range to the paired electronic key. When in range, the electronic key is awakened by the wakeup signal and in response transmits an acknowledgment reply to the base-station control module. After receiving the acknowledgment, the base-station control module transmits a relatively high power localization signal for determining an electronic key location.

The present disclosure relates to a one-chip system for a control device of a vehicle with at least one bus, at least one control unit connected to the at least one bus for controlling a peripheral device assigned to the at least one control unit and several processors connected to the at least one bus.

An information processing system includes an object information acquiring unit, a receiver information acquiring unit, and an authentication information issuing unit. The object information acquiring unit acquires delivery object information of an object from a deliverer of the object. The object is stored in an interior space of a vehicle and of which delivery is desired. The receiver information acquiring unit acquires receiver information on a receiver of the object. The authentication information issuing unit issues authentication information for locking and unlocking a door of the vehicle based on the delivery object information and the receiver information and transmits the authentication information to a terminal of the receiver.