A transceiver is configured to: pair with a mobile device; and transmit a predetermined signal from an antenna to the mobile device. A zone module is configured to: receive a signal from the mobile device in response to the predetermined signal; and based on the signal, select a zone within which the mobile device is present from a group consisting of: a first zone that is defined by a first radius from the antenna; a second zone that excludes the first zone and that is defined by a second radius from the antenna, where the second radius is greater than the first radius; and a third zone that is radially outward of the second zone and that excludes the first and second zones.

Disclosed is an Ethernet-based vehicle control system and method. The Ethernet-based vehicle control system (method) according to the present invention comprises: a router for connecting a vehicle internal network and a vehicle external network; a vehicle electronic element connected to and communicating with the router; and a third-party module newly mounted on a vehicle to control the vehicle electronic element, wherein the vehicle electronic element includes a Remote Keyless Entry (RKE) module, and the third-party module may piggyback on a signal input into the RKE module by a remote controller through the vehicle external network. According to the present invention, since a third-party module can be freely installed and replaced based on Ethernet, various services related to a vehicle may be realized through a vehicle external network.

A remote control system for a marine vessel includes at least one fob and a configuration control system configured to detect available devices on the marine vessel to be controlled remotely for the marine vessel, generate a list of available functions for at least one user-selectable fob command based on the detected available devices, present the list of available functions to the user via a fob configuration user interface such that the user can select one or more functions in the list of available functions, identify a system command associated with each selected function so as to configure a set of system commands based on the user-selected functions, and store the user-configured set of system commands in association with the fob identification and the selected fob command. The system further includes a helm transceiver module to effectuate activation/deactivation of the available devices based on the user-configured set of system commands.

A portable device is configured to establish a Bluetooth low energy (BLE) communication connection with a vehicle and to communicate with at least one sensor in the vehicle using impulse radio (IR) ultra-wide band (UWB) communication after establishment of the BLE communication connection with the vehicle is completed. A location of the portable device is determined by the vehicle based on ranging using IR UWB communication performed by the at least one sensor.

The invention concerns an automatic access and starting system for a motor vehicle, comprising an on-board access management system and at least one identifier (3) such as an electronic key, the access management system being configured to detect and authenticate the identifier (3) when it is close to the vehicle (1), the identifier (3) being configured to emit an authentication signal in response to an interrogation signal emitted by the management and access system, the identifier (3) comprising a memory for storing an instruction relative to a command issued by the carrier of the identifier (3) if this command is issued during the phase of detection and authentication by the on-board system, the instruction being stored temporarily in order for the identifier to be able to emit a signal related to the command when the detection and authentication phase is complete.

A portable electronic device to be used as a keyless device of a vehicle includes a controlling circuit which includes a physiological feature detection module and a processing circuit. The physiological feature detection module is used for detecting a physiological feature of a person. The processing circuit is coupled to the physiological feature detection module and used for determining whether the person is an authorized user of the vehicle according to the detected physiological feature of the person, and for opening a car door of the vehicle or starting the vehicle when the person is identified by the processing circuit as the authorized user.

A remote control system for a marine vessel includes at least one fob communicating with a helm transceiver module on the vessel. The fob has at least two user inputs, each associated with a different user-selectable fob command, wherein the fob is configured to wirelessly transmit a fob identification and a selected fob command in response to user selection of a user input. The helm transceiver module is configured to store unique fob identifications for permitted fobs and a set of system commands for each user-selectable fob command for each fob identification, wherein the set of system commands are configurable by a user. Upon receipt of the fob identification and the selected fob command, the helm transceiver module verifies that the fob identification is associated with one of the permitted fobs and identifies the user-configured set of system commands associated with the selected fob command and the fob identification. The helm transceiver module then communicates instructions via a vessel network based on the set of system commands to activate or deactivate devices on the marine vessel.

A vehicle control apparatus includes a first vehicle communication unit performing communication with a mobile terminal, a first distance measuring unit measuring, with first precision, a vehicle-terminal distance being a distance between a vehicle and the mobile terminal, a terminal position information obtaining unit obtaining terminal position information transmitted from the mobile terminal, a second distance measuring unit measuring the vehicle-terminal distance with second precision being measurement precision lower than the first precision based on the terminal position information, and a high-precision distance measurement determining unit determining whether the first distance measuring unit is caused to measure the vehicle-terminal distance or not based on the vehicle-terminal distance measured by the second distance measuring unit.

Systems and methods for vehicle passive entry/passive start (PEPS) are provided. A communication gateway in a vehicle establishes a Bluetooth low energy (BLE) or an impulse radio ultra-wide band (IR UWB) communication connection with a portable device that includes a wireless charging apparatus. A low-frequency transmitter transmits a ping request to the wireless charging apparatus. The portable device transmits a response to the ping request over the communication connection to the communication gateway. The communication gateway authenticates the portable device based on information included in the received response. A passive entry/passive start (PEPS) system performs a vehicle function in response to the portable device being authenticated, including unlocking a door of the vehicle, unlocking a trunk of the vehicle, allowing a wireless charging station of the vehicle to charge the portable device, or allowing the vehicle to be started.

Disclosed is an electronic device including a communication circuit and a processor. The processor may be configured to communicate with an external electronic device based on a specified protocol, using the communication circuit, to receive first information at least including type information of the external electronic device based on the specified protocol, using the communication circuit, and to determine a positioning master for measuring a distance between the electronic device and the external electronic device based at least on the first information among the electronic device and the external electronic device. Other various embodiments as understood from the specification are also possible.