A signal generation circuit includes: a clock module, configured to generate a clock signal based on a flag signal; a control module, configured to generate a control signal according to number of transitions of the clock signal within a fixed time; and a generation module, respectively connected to the clock module and the control module, and configured to receive the clock signal, the control signal, and the flag signal, and to generate a target signal. When the flag signal changes from a first level to a second level, the target signal changes from a third level to a fourth level. After being maintained at the fourth level for a target duration, the target signal changes from the fourth level to the third level. The generation module is further configured to determine the target duration according to the clock signal and the control signal.

A division factor generator of a feedback divider block in a fractional-N phase locked loop (PLL). The division factor generator is enabled to operate with larger values of division factors without increased complexity of an internal modulator core implemented, for example, as a delta-sigma modulator (DSM) having a signal transfer function (STF), wherein the STF always generates only an integer value as an output in response to an integer value received as input.

A division factor generator of a feedback divider block in a fractional-N phase locked loop (PLL). The division factor generator is enabled to operate with larger values of division factors without increased complexity of an internal modulator core implemented, for example, as a delta-sigma modulator (DSM) having a signal transfer function (STF), wherein the STF always generates only an integer value as an output in response to an integer value received as input.

A charge pump has a first branch that includes a first node connected between a first pull-up switch and a first pull-down switch and a second branch that includes a second node connected between a second pull-up switch and a second pull-down switch. The second branch is connected in parallel with the first branch. The charge pump has a voltage equalization circuit to equalize a first voltage at the first node and a second voltage at the second node. A third branch includes a third node that is connected between a third pull-up switch and a third pull-down switch. The third node is connected to the second node. The third pull-up switch and the first pull-up switch are controlled by a common pull-up signal. The third pull-down switch and the first pull-down switch are controlled by a common pull-down signal.

A charge pump has a first branch that includes a first node connected between a first pull-up switch and a first pull-down switch and a second branch that includes a second node connected between a second pull-up switch and a second pull-down switch. The second branch is connected in parallel with the first branch. The charge pump has a voltage equalization circuit to equalize a first voltage at the first node and a second voltage at the second node. A third branch includes a third node that is connected between a third pull-up switch and a third pull-down switch. The third node is connected to the second node. The third pull-up switch and the first pull-up switch are controlled by a common pull-up signal. The third pull-down switch and the first pull-down switch are controlled by a common pull-down signal.

The technology of this application relates to a phase-locked loop circuit that includes a phase frequency detector, a first voltage control module, a second voltage control module, a third voltage control module, a voltage-controlled oscillator, and a frequency divider. A first output end of the phase frequency detector is connected to a first input end of the first voltage control module and a first input end of the second voltage control module, a second output end of the phase frequency detector is connected to a second input end of the first voltage control module and a second input end of the second voltage control module, an output end of the first voltage control module.

In an embodiment a timing system includes a master timing device including a master oscillator stage configured to receive a reference signal and to generate a first main clock signal frequency-locked with the reference signal, a master timing stage including a master counter configured to update value with a timing that depends on the first main clock signal, the master timing stage configured to generate a first local clock signal of a pulsed type, a timing of pulses of the first local clock signal being controllable by the master counter and a master synchronization stage configured to generate a synchronization signal synchronous with the first local clock signal, wherein the synchronization signal includes a corresponding pulse for each group of consecutive pulses of the first local clock signal formed by a number (N) of pulses, and a slave timing device including a slave oscillator stage configured to receive the reference signal and to generate a second main clock signal frequency-locked with the reference signal, a slave timing stage and a slave synchronization stage.

In an embodiment a timing system includes a master timing device including a master oscillator stage configured to receive a reference signal and to generate a first main clock signal frequency-locked with the reference signal, a master timing stage including a master counter configured to update value with a timing that depends on the first main clock signal, the master timing stage configured to generate a first local clock signal of a pulsed type, a timing of pulses of the first local clock signal being controllable by the master counter and a master synchronization stage configured to generate a synchronization signal synchronous with the first local clock signal, wherein the synchronization signal includes a corresponding pulse for each group of consecutive pulses of the first local clock signal formed by a number (N) of pulses, and a slave timing device including a slave oscillator stage configured to receive the reference signal and to generate a second main clock signal frequency-locked with the reference signal, a slave timing stage and a slave synchronization stage.

An electronic device includes a dock dividing circuit configured to generate sampling clocks, alignment clocks and output clocks by dividing a frequency of a write clock; and a data alignment circuit configured to, in a first operation mode, receive input data having any one level among a first level to a fourth level and generate alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks, and to, in a second operation mode, receive the input data having any one level of the first level and the fourth level and generate the alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks.

A semiconductor integrated circuit includes a first oscillator configured to generate a first signal with a first frequency based on a control signal and output the first signal to a path. The semiconductor integrated circuit includes a control signal generation circuit operatively coupled to the first oscillator via the path, and configured to receive the first signal from the first oscillator via the path and generate the control signal. The semiconductor integrated circuit includes a second oscillator configured to generate a second signal with a second frequency based on the control signal and output the second signal to an output terminal outside the path.