The device for accurate measurement of time intervals comprises a first comparator (1) to the input of which a first signal (STA) is fed and the output of which is connected to the first of the inputs of the combiner (3), to the second input of which the output of a second comparator (2) is connected, to the input of which a second signal (STO) is fed. The output of the combiner (3) is connected to the input of an analogue filter (4), the output of which is connected to the input of an analogue-to-digital converter (5), the output of which is connected to the input of a control and signal processing circuit (6), to the second input of which a reference clock signal (REF) is further fed, which is simultaneously fed to another input of the analogue-to-digital converter (5) and the output of the control and signal processing circuit (6) is a data output (DAT) of time intervals.

A time-to-digital converter (TDC) includes a count logic and a digital core. The count logic generates a first sequence of counts representing a first sequence of edges of a first periodic signal, and a second sequence of counts representing a second sequence of edges of a second periodic signal. The digital core generates a sequence of outputs representing the phase differences between the first periodic signal and the second periodic signal from the first sequence of counts and the second sequence of counts. Each output is generated from a pair of successive edges of the first direction of one of the periodic signals and an individual one of the other periodic signal occurring between the pair, and the output is set equal to the minimum of difference of the individual one with the first value of the pair and the individual one with the second value of the pair.

A method of a wearable device displaying icons is provided. The method includes displaying a plurality of circular icons comprising a first circular icon located in a center area of a touch display in a first size and a second circular icon located outside of the center area of the touch display in a second size smaller than the first size, and based on a direction of a touch input received on the touch display, moving the plurality of circular icons such that the first circular icon is moved to a first position located outside of the center area of the touch display and the second circular icon is moved from a second position located outside the center area of the touch display to the center area of the touch display and enlarged in size from the second size to the first size.

A method of a wearable device displaying icons is provided. The method includes displaying a plurality of circular icons comprising a first circular icon located in a center area of a touch display in a first size and a second circular icon located outside of the center area of the touch display in a second size smaller than the first size, and based on a direction of a touch input received on the touch display, moving the plurality of circular icons such that the first circular icon is moved to a first position located outside of the center area of the touch display and the second circular icon is moved from a second position located outside the center area of the touch display to the center area of the touch display and enlarged in size from the second size to the first size.

Technologies are provided for time-to-digital conversion without reliance on a clocking signal. Some embodiments of the technologies include a clockless TDC apparatus that can map continuous pulse-widths to binary bits represented via an iterative chaotic map (e.g., tent map, Bernoulli shift map, or similar). The clockless TDC apparatus can convert separated pulses to a single asynchronous digital pulse that turns on when a sensor detects a first pulse and turns off when the sensor detects a second pulse. The asynchronous digital pulse can be iteratively stretched and folded in time according to the chaotic map. The clockless TDC can generate a binary sequence that represents symbolic dynamics of the chaotic map. The process can be implemented by using an iterative time delay component until a precision of the binary output is either satisfied or overwhelmed by noise or other structural fluctuations of the TDC apparatus.

A real-time clock device includes a resonator, a clock signal generation circuit, a time-counting circuit, a terminal, and a time-to-digital conversion circuit. The clock signal generation circuit outputs a time-counting clock signal based on an oscillation clock signal. The time-counting circuit generates time-counting data based on the time-counting clock signal. An external signal is input to the terminal. The time-to-digital conversion circuit measures a time difference between a transition timing of a first signal based on the external signal and a transition timing of a second signal based on the oscillation clock signal or the time-counting clock signal with a resolution higher than a time-counting resolution of the time-counting circuit, and obtains time difference information corresponding to the time difference.

A digital phase-locked loop (DPLL) may include a time-to-digital converter (TDC) to provide a phase error signal, a frequency-divider to perform frequency division on an output signal to generate a frequency-divided output signal, a delta-sigma-modulator (DSM) to provide a test signal that represents a quantization error of the DSM, and a digital-to-time converter (DTC) to at least partially remove the quantization error from the frequency-divided output signal based on the test signal to generate the feedback signal. The DPLL may include a circuit to cause the DTC to provide a percentage of the quantization error such that the percentage of the quantization error is in the phase error signal, and a TDC calibration component to calibrate the TDC by applying a gain adjustment factor to the TDC. The gain adjustment factor may be based on the test signal and the phase error signal including the percentage of the quantization error.

Provided is a server device with which it is possible to suitably discern whether a user uses an elevator. The server device comprises a first generation unit, a second generation unit, and an output unit. The first generation unit analyzes image data obtained from at least one or more camera devices and generates elevator information pertaining to the usage state of an elevator The second generation unit generates, on the basis of at least the generated elevator information, during-movement reference information that is referred to when the user moves. The output unit outputs the generated during-movement reference information to signage.

Provided is a server device with which it is possible to suitably discern whether a user uses an elevator. The server device comprises a first generation unit, a second generation unit, and an output unit. The first generation unit analyzes image data obtained from at least one or more camera devices and generates elevator information pertaining to the usage state of an elevator The second generation unit generates, on the basis of at least the generated elevator information, during-movement reference information that is referred to when the user moves. The output unit outputs the generated during-movement reference information to signage.

An electronic device including: a positioning module that performs positioning by receiving radio waves from navigation satellites; a movement distance detection sensor that detects movement distance; and a processor that activates the positioning module and, if positioning with the positioning module has not succeeded after a first prescribed period of time has elapsed, suspends the positioning module, wherein if the processor detects that the movement distance detected by the movement distance detection sensor starting from when the positioning module was suspended is greater than or equal to a prescribed distance, the processor reactivates the positioning module.