A method for vehicle function control includes: in response to determining that a distance between a vehicle and a terminal is within a bluetooth low energy (BLE) communication distance and the terminal has a digital vehicle key of the vehicle, establishing a BLE connection between the vehicle and the terminal and performing a BLE ranging; and when a BLE ranging result meets a preset condition, controlling the vehicle to unlock a door lock.

An electronic key includes a housing including a battery housing portion that houses a battery, the battery housing portion being provided in the housing, a battery terminal, arranged within the battery housing portion, that makes contact with one electrode of the battery housed within the battery housing portion, and a board, arranged within the battery housing portion, including a first conductive portion that makes contact with the battery terminal and is electrically connected to the one electrode of the battery via the battery terminal, and a second conductive portion that makes contact with and is electrically connected to another electrode of the battery.

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 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).

The invention relates to a method for operating an internal combustion engine (14) of a motor vehicle (10), in that the internal combustion engine (14) is started using a remote start unit (18) for wireless reception of a remote start signal (R) and afterwards is monitored by a shutdown unit (36) to determine whether a shutdown condition is fulfilled. When appropriate, the internal combustion engine (14) is shutdown again. A radio key device (26) of the motor vehicle (10) is designed to detect a radio key presence in a passenger compartment (28) of the motor vehicle (10) using a key scan and to signal a radio key presence by means of a key presence signal (A). The problem addressed by the invention is to adapt the subsequent shutdown of the internal combustion engine (14) more flexibly to the position of the driver following a remote start. The shutdown condition comprises for this purpose that the key presence signal (A) must have been inactive for a predefined minimum time period. A presence of a person in the passenger compartment (28) is detected by a monitoring device (32) by means of a sensor unit (24, 38, 40 42) and, upon detecting the presence of a person, at least one key scan is triggered at at least one predefined time by means of a control signal (P).

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.

A fashionable bracelet operates as a remote car key fob and a clock. The bracelet provides multiple buttons allowing a user to operate the bracelet to control access to the vehicle coupled to the bracelet. The bracelet receives voice commands to operate the vehicle. Moreover, the bracelet incorporates a GPS subsystem for auto-piloting the vehicle to the location of the user. The bracelet further incorporates multiple LEDs to provide operational feedback to the user. The clock can be turned on and off using one of the buttons. The wireless key fob functions and the clock are controlled by a microcontroller disposed within the bracelet. The bracelet includes a battery to provide power to various components of the bracelet. The battery is operatively coupled to a solar panel. The bracelet is conveniently and securely attached to the wrist of the user.

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 invention concerns a method (PR) for detecting an identifier (Id) for starting a motor vehicle (V), said motor vehicle comprising a first antenna (A1) and said identifier (Id) comprising a second antenna (A2). The method (PR) is characterised in that it comprises: —transmitting, by said first antenna (A1), a first Bluetooth Low Energy™ signal (Sg1) to said identifier (Id) at a nominal power (P1); —measuring the power (P1′) of said corresponding signal (Sg1′) received by the second antenna (A2) of said identifier (Id); —comparing said measured power (P1′) with a threshold power (Ps), said threshold power (Ps) corresponding to a threshold distance (ds) from said first antenna (A1) that is less than the radius (r1) of a circle (C1) inscribed within the passenger compartment (H) of the motor vehicle (V), said circle (C1) being centred on said first antenna (A1); —authorising the starting of the motor vehicle (V) if the measured power (P1′) is greater than or equal to said threshold power (Ps).

The present invention relates essentially to a device for controlling locking/unlocking and/or starting of a vehicle (V) comprising a first communication device (COM1) mounted in the vehicle (V), said first communication device (COM1) being linked to the control unit (ECU) of the vehicle (V), and a second communication device (COM2) disposed in a mobile apparatus (SP), the first communication device (COM1) and the second communication device (COM2) being able to communicate with one another according to a first mode of communication so as to carry out an authentication of the mobile apparatus (SP) by the vehicle (V), said authentication authorizing the locking/unlocking and/or starting of the vehicle (V), characterized in that the first communication device (COM1) and the second communication device (COM2) are able to communicate also according to a second mode of communication, so as to determine data representative of the position of the mobile apparatus (SP) with respect to the vehicle (V), and in that the execution, by the control unit (ECU), of the command for locking/unlocking and/or starting the vehicle (V), is dependent on said data representative of the position of the mobile apparatus (SP) with respect to the vehicle (V).