A time correction method is a method performed using wireless communication between an electronic apparatus that includes a first wireless communication unit, and an electronic timepiece that includes a second wireless communication unit. The time correction method includes the electronic timepiece starting wireless reception, the electronic apparatus generating an advertising signal including time data held by the electronic apparatus and starting transmission of the advertising signal, and the electronic timepiece receiving the advertising signal. The electronic timepiece updates time data held by the electronic timepiece based on the time data included in the received advertising signal.

In one embodiment, a sensor unit to be utilized in an autonomous driving vehicle (ADV) includes a sensor interface coupled to a number of sensors mounted on a number of locations of an autonomous driving vehicle (ADV). The sensor unit includes a host interface to be coupled to a host system, where the host system is configured to perceive a driving environment surrounding the ADV based on sensor data obtained from the sensors and to plan a path to autonomously drive the ADV. The sensor unit includes a time synchronization hub device coupled to the sensor interface. The time synchronization hub device includes one or more TX and/or RX timestamp generators coupled to a time source, where the TX/RX timestamp generators generate TX/RX timestamps based on a time obtained from the time source to provide the TX/RX timestamps to one or more of the sensors.

In one embodiment, a sensor unit to be utilized in an autonomous driving vehicle (ADV) includes a sensor interface coupled to a number of sensors mounted on a number of locations of an autonomous driving vehicle (ADV). The sensor unit includes a host interface to be coupled to a host system, where the host system is configured to perceive a driving environment surrounding the ADV based on sensor data obtained from the sensors and to plan a path to autonomously drive the ADV. The sensor unit includes a time synchronization hub device coupled to the sensor interface. The time synchronization hub device includes one or more TX and/or RX timestamp generators coupled to a time source, where the TX/RX timestamp generators generate TX/RX timestamps based on a time obtained from the time source to provide the TX/RX timestamps to one or more of the sensors.

A timepiece includes a clock circuit, a signal receiver configured to receive signals including time information, a processor configured to control a changing operation of changing a current time measured by the clock circuit based on the time information obtained from the signal receiver and controls a presenting operation of whether or not the changing operation is successful. The processor controls the changing operation based on a first flag indicating whether or not the signal receiver successfully receives the time information. The processor controls the presenting operation based on a second flag indicating whether or not the changing operation is successful within a predetermined period of time.

A timepiece includes a clock circuit, a signal receiver configured to receive signals including time information, a processor configured to control a changing operation of changing a current time measured by the clock circuit based on the time information obtained from the signal receiver and controls a presenting operation of whether or not the changing operation is successful. The processor controls the changing operation based on a first flag indicating whether or not the signal receiver successfully receives the time information. The processor controls the presenting operation based on a second flag indicating whether or not the changing operation is successful within a predetermined period of time.

In one embodiment, a sensor unit to be utilized in an autonomous driving vehicle (ADV) includes a sensor interface coupled to a number of sensors mounted on a number of locations of an autonomous driving vehicle (ADV). The sensor unit includes a host interface to be coupled to a host system, where the host system is configured to perceive a driving environment surrounding the ADV based on sensor data obtained from the sensors and to plan a path to autonomously drive the ADV. The sensor unit includes a time synchronization hub device coupled to the sensor interface. The time synchronization hub device includes one or more TX and/or RX timestamp generators coupled to a time source, where the TX/RX timestamp generators generate TX/RX timestamps based on a time obtained from the time source to provide the TX/RX timestamps to one or more of the sensors.

In one embodiment, a sensor unit to be utilized in an autonomous driving vehicle (ADV) includes a sensor interface coupled to a number of sensors mounted on a number of locations of an autonomous driving vehicle (ADV). The sensor unit includes a host interface to be coupled to a host system, where the host system is configured to perceive a driving environment surrounding the ADV based on sensor data obtained from the sensors and to plan a path to autonomously drive the ADV. The sensor unit includes a time synchronization hub device coupled to the sensor interface. The time synchronization hub device includes one or more TX and/or RX timestamp generators coupled to a time source, where the TX/RX timestamp generators generate TX/RX timestamps based on a time obtained from the time source to provide the TX/RX timestamps to one or more of the sensors.

An automatic regular time service method for a pointer type intelligent clock includes the following steps: a clock is connected to a mobile intelligent terminal by a wireless communication module to obtain a standard time; when the clock is not connected to the mobile intelligent terminal, an MCU module calls an internal error correction parameter list regularly by means of a command signal to obtain a correction time; and a movement controls pointers to rotate to synchronize the time to the standard time or correction time. A time service system for a pointer type intelligent clock is also disclosed. The method and the system solve the timekeeping error problem of a clock caused by a crystal oscillator error of a quartz movement, and can perform an automatic time service even if the clock is not connected to the network.

An automatic regular time service method for a pointer type intelligent clock includes the following steps: a clock is connected to a mobile intelligent terminal by a wireless communication module to obtain a standard time; when the clock is not connected to the mobile intelligent terminal, an MCU module calls an internal error correction parameter list regularly by means of a command signal to obtain a correction time; and a movement controls pointers to rotate to synchronize the time to the standard time or correction time. A time service system for a pointer type intelligent clock is also disclosed. The method and the system solve the timekeeping error problem of a clock caused by a crystal oscillator error of a quartz movement, and can perform an automatic time service even if the clock is not connected to the network.

Electrochemical indicators are configured to indicate a variable such as time and/or a temperature excursion. In some embodiments, the electrochemical indicators comprise an anode layer and a cathode layer which contact an electrolyte to activate each indicator. In some embodiments, the electrochemical indicator comprises an electrically isolated RFID chip and an RFID antenna which are placed in electrical communication in response to the external variable. The completed RFID tag may then be read by an RFID reader. A completed RFID tag may also be incorporated within the electrochemical indicators comprising an anode layer and a cathode layer and where the RFID tag is unshielded and becomes readable as the indicator expires.