Provided is a radio-controlled timepiece that can reduce overall power consumption. The radio-controlled timepiece 1 has a receiver circuit 12 that executes during a specific time limit a reception process to acquire multiple time data from the standard time signals at different times; storage 22 that stores multiple time data; a timekeeper 23 that keeps an internal time; a time setting adjuster 24 that corrects the internal time based on coherent time data when the number of coherent time data, which is time data that is mutually coherent, in the multiple time data reaches a threshold; and a reception controller 21 that extends the time limit when the number of coherent time data is less than the threshold when a specific time that is shorter than the time limit has past since the reception process started.

Systems, methods, and devices of the various embodiments may provide for synchronizing clocks across a distributed network of nodes. Various embodiments include an autonomous distributed fault-tolerant local positioning system, a fault-tolerant GPS-independent autonomous distributed local positioning system, for static and/or mobile objects, and/or solutions for providing highly-accurate geo-location data for static and/or mobile objects in dynamic environments. Various embodiments enable faulty Echo message recovery using trilateration from locally time-stamped events obtained from other nodes in a distributed network of nodes. Using the faulty Echo message recovery techniques, in addition to clock synchronization various embodiments may enable object detection and location.

Provided are a timepiece movement and a timepiece allowing mounting of a wireless communication device in the timepiece and capable of avoiding generation of restrictions to the design of the timepiece. A movement is arranged on the inner side of a timepiece case having a case back, and drives indicator hands. The movement uses an electric wave from the outside as a power source and is equipped with an RFID tag communicating with an external reader.

A method for transmitting data from an electronic device to an electronic watch is provided, including emitting a first sequence of light signals with a first light source of the device at a light-intensity level among at least four light-intensity levels, the emitted first sequence corresponding to a code of data to be transmitted; emitting a second sequence of light signals at two light-intensity levels corresponding to clock phases, simultaneously to the emitted first sequence, with a second light source of the device; detecting successive light-intensity levels with a first phototransistor of a watch, to reconstitute a sequence of data; detecting a succession of the two light-intensity levels with a second phototransistor of the watch, to reconstitute the clock phases, the first and the second sequences emitted at two distinct wavelengths; and decoding the sequence of data by a sequence of the clock phases to reconstitute the data.

A method for transmitting data from an electronic device to an electronic watch, including the following steps: emitting a sequence of light signals with a light source of the electronic device, each signal having a light-intensity level belonging to a set of at least four light-intensity levels, said sequence corresponding to a code of the data to be transmitted; detecting successive light-intensity levels with a phototransistor of the watch, so as to reconstitute the sequence; and decoding the sequence in order to reconstitute the data, the set of at least four intensity levels being divided into a first portion and a second portion, one light signal in two of the sequence having a light-intensity level belonging to the first portion, the other signals having a light-intensity level belonging to the second portion.

This disclosure describes systems and methods for using a primary device, communicatively coupled to a remote system, to configure or re-configure a secondary device in the same environment as the primary device. In some instances, the primary device may communicatively couple to the secondary device via a short-range wireless connection and to the remote system via a wireless area network (WAN), a wired connection, or the like. Thus, the primary device may act as an intermediary between the secondary device and the remote system for configuring the secondary device.

A satellite radio wave receiving device includes: a receiver that receives a satellite radio wave to identify a reception signal; and a processor that acquires primary date and time information from the identified reception signal and outputs a date and time notifying signal indicating date and time based on the primary date and time information to an outside of the satellite radio wave receiving device. The date and time notifying signal includes at least a timing notifying signal indicating a predetermined timing. The processor determines the predetermined timing without consideration of a timing of a second synchronization point which is a leading edge of every second in the date and time based on the primary date and time information, and outputs the timing notifying signal at the predetermined timing.

The present invention relates to an electronic watch allowing data to be received, comprising: An electrical energy source A control member arranged to be supplied with power by the electrical energy source A receiver module comprising: An optical sensor capable of detecting a sequence of light pulses modulated by data, and of converting said sequence into a digital signal An energy storage element arranged to store electrical energy generated by the optical sensor A demodulator arranged to be supplied with power by the energy storage element, capable of extracting the data from the digital signal Transmission means capable of transmitting the extracted data to the control member

Systems, methods, and devices of the various embodiments may provide for synchronizing clocks across a distributed network of nodes. Various embodiments include an autonomous distributed fault-tolerant local positioning system, a fault-tolerant GPS-independent autonomous distributed local positioning system, for static and/or mobile objects, and/or solutions for providing highly-accurate geo-location data for static and/or mobile objects in dynamic environments. Various embodiments enable faulty Echo message recovery using trilateration from locally time-stamped events obtained from other nodes in a distributed network of nodes. Using the faulty Echo message recovery techniques, in addition to clock synchronization various embodiments may enable object detection and location.

The invention relates to a method for transmitting data from an electronic device to an electronic watch, including the following steps: emitting a sequence of light signals with a light source of the electronic device, each signal having a light-intensity level belonging to a set of at least four light-intensity levels, said sequence corresponding to a code of the data to be transmitted; emitting a sequence of light signals at two intensity levels corresponding to clock phases, simultaneously to the step of emitting the sequence of light signals corresponding to the data to be transmitted, with a second light source of the electronic device; detecting successive light-intensity levels with a phototransistor of the watch, so as to reconstitute the sequence of data; detecting a succession of the two light-intensity levels with a second phototransistor of the watch, so as to reconstitute the clock, the two sequences of light signals being emitted at two distinct wavelengths; and decoding the sequence of data by means of the sequence of clock phases, in order to reconstitute the data.