A system, apparatus and method utilize a micro electronic device implanted in a person or group of persons, or wearable thereby, to manage a variety of activities. Such micro devices may also be embedded in, incorporated into, or otherwise attached to articles, devices, structures or things to track, manage or monitor such articles, devices, structures or things for geo-location or other tracking, monitoring or management services. The microelectronic devices may be used for geo-location services for agencies responsible for monitoring such person's whereabouts with respect to branches and agencies such judicial and law enforcement agencies. Lastly, the microelectronic devices may be implanted in or worn or carried by humans for using biometric sensors or transducers to authenticate and transmit vital signs and other health information to clinic or other facility personnel. The micro electronic devices may be communicatively connected to a mobile device and the micro electronic devices utilize features of the mobile device such as user interface services, programming services, data processing and storage services, telecommunication services, location services, sensor/transducer services, camera services, clock services, and/or temperature, weather and other services. This also enables tracking, monitoring, inventorying, and management of people and things for medical, legal, business, governmental and various other purposes.

A vehicle control system includes a terminal device and a vehicle. The terminal device includes a first verification unit that verifies whether the terminal devices matches the vehicle through wireless communication when the terminal device enters an area in which wireless communication between the terminal device and the vehicle is available, and an operation instruction unit that receives an instruction to execute a predetermined operation of the vehicle from the user and the first verification unit has verified that the terminal device matches the vehicle, and transmits a signal according to the instruction to the vehicle, and the vehicle includes a second verification unit that communicates with the first identification unit and verify whether with the vehicle matches the terminal device, and an operation controller that receives the signal from the operation instruction unit and executes the predetermined operation according to the signal.

A vehicle control system includes a terminal device and a vehicle. The terminal device includes a first verification unit that verifies whether the terminal devices matches the vehicle through wireless communication when the terminal device enters an area in which wireless communication between the terminal device and the vehicle is available, and an operation instruction unit that receives an instruction to execute a predetermined operation of the vehicle from the user and the first verification unit has verified that the terminal device matches the vehicle, and transmits a signal according to the instruction to the vehicle, and the vehicle includes a second verification unit that communicates with the first identification unit and verify whether with the vehicle matches the terminal device, and an operation controller that receives the signal from the operation instruction unit and executes the predetermined operation according to the signal.

An opening-closing control device of the present disclosure includes: a first electrode unit and a second electrode unit that perform communication with an authenticated communication device; an authentication processor that performs authentication processing on the authenticated communication device on a basis of a result of the communication with the authenticated communication device; an opening-closing operation unit that performs an operation on a lockable opening-closing unit; an operation detector that detects an operation state of the opening-closing operation unit; and a controller that locks or unlocks the opening-closing unit on a basis of a result of the authentication processing and a result of detection of the operation state.

Techniques are described for user authentication based on a signal that is transmitted through an individual's body, and detected using device(s) in physical contact with the individual. A signal, such as an electrical signal or a vibrational signal, may be transmitted from a first device and received by a second device that is in physical contact with the individual. The received signal may be employed to determine a body signature for the individual. The body signature may identify the individual among a population of individuals, given the particular alterations to the propagating signal caused by the individual's physiology. Accordingly, the body signature may be employed as a form of biometric data that is useable to authenticate the individual to access a secure area, log in to a device or an application, or for other purposes.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for capacitive through-body communication. In one aspect, a method includes capturing, from capacitive through-body communication with an on-body device worn by an individual, a biometric template comprising identification data associated with the individual, comparing the captured identification data of the captured biometric template with reference identification data of a stored biometric template associated with the individual, determining that the captured identification data matches the reference identification data of the stored biometric template; and authenticating identification of the individual.

Systems and methods are provided for providing access to secure-access facilities based on pairing of the secure-access facilities with a user device such as a wearable device. A pairable secure-access facility may be a public storage facility or device such as a locker that includes communications circuitry for pairing with the user device. Once paired with the user device, the locker may operate a locking mechanism to lock the locker when the user device is away from the locker and to unlock the locker when the user device is in the vicinity of the locker. The locker may include a beacon for detecting and pairing with the user devices. Pairing the user device and the locker may include entering a locker identifier into the user device to ensure that the intended user device is paired with the intended locker.

A user obtains authentication credentials using a portable device, such as a smart phone. While standing on a smart floor in a facility, the portable device transmits the authentication credentials to the smart floor. The body of the user electromagnetically couples to electrodes in a touch sensor of the portable device and one or more antennas of the smart floor, acting as a signal path for signals between the mobile device and the smart floor. For example, one or more of the voltage applied to the electrodes, timing of when voltage is applied, and so forth, may be used to produce a particular electromagnetic signal that conveys the authentication credentials. The authenticated user may now be tracked in the facility using the smart floor.

A communication device (10) comprises a conductor (11), a transceiver (12) coupled to the conductor (11) and a data processing unit (13) that is coupled to the transceiver (12). The communication device (10) is configured to determine a strength signal (ST) depending on a receiver signal (SR) received via the conductor (11) and to determine a proximity signal (SP) depending on a proximity of a body to the communication device (10). The data processing unit (13) is configured to generate a disable signal (STO) depending on at least a value of the strength signal (ST) and on at least a value of the proximity signal (SP).

A system, apparatus and method utilize a micro electronic device implanted in a person or group of persons, or wearable thereby, to manage a variety of activities, including checking out a product or service from a market, such as a micro-market. The method includes the steps of providing a RF microdevice having an electronic identification code and attaching the microdevice to the user. A checkout system is provided including an RF reader and a processor. The user brings the microdevice near the reader, whereby the reader communicates with the microdevice via RF signals, and the RF reader signals the processor to corroborate the identification code. If the processor corroborates the identification code, the processor signals that a successful product or service checkout has occurred. If the processor does not corroborate the identification code, a checkout is not confirmed.