A setting data output circuit (3) is configured to update setting data in synchronization with a frequency divided signal output from a dual modulus frequency divider on a last stage out of the dual modulus frequency dividers to which a non-significant reset signal is output from a reset circuit (6) which are included in a plurality of dual modulus frequency dividers (1-1 and 1-2) in a first frequency divider group (1). As a result, when a frequency dividing ratio of the dual modulus frequency divider on the last stage out of valid dual modulus frequency dividers contributing to frequency dividing operation is 3, it is possible to realize normal frequency dividing operation even in a case in which frequency dividing ratio setting data to decrease the number of valid dual modulus frequency dividers contributing to the frequency dividing operation is provided.

A counter signal counting at a frequency of a clock signal is generated. Among a plurality of different numeric ranges corresponding to a plurality of different thresholds, a threshold corresponding to a numeric range containing a frequency ratio is selected. In response to the counter signal reaching the selected threshold, a logic level of an output signal is switched.

There is disclosed configurable frequency-divider circuitry for generating a target signal of a frequency Fr/Di based on a reference signal of a frequency Fr, where Di is an integer divider ratio, the frequency-divider circuitry comprising: N divider stages organised into a ring, each stage configured to receive an input signal and generate an output signal, with the output signal of each successive stage in the ring being the input signal of the next stage in the ring, wherein: the ring of stages is controlled by the reference signal so that the output signals are governed by the reference signal; the target signal is one of the output signals or a signal derived therefrom; and at least one of the stages is a configurable stage, whose mode of operation is configurable based on a configuration signal to configure the value of Di.

Exemplary embodiments include an electronic frequency-divider circuit comprising a multi-phase generator circuit configured to: receive an oscillating input signal having a frequency f; determine an integer divide ratio Q based on a first control signal input; and based on the oscillating input signal, generate an N-phase output signal having a frequency f-divided-by-M, wherein M is an integer and adjacent phases of the N-phase output signal are separated by 360-divided-by-(M-times-Q) degrees. The divider circuit can also include a control circuit configured to receive a control input and, based on the control input: provide the first control signal to the multi-phase generator circuit; and select a particular phase of the N-phase output signal. Exemplary embodiments also include a phase-locked loop circuits, transceiver circuits, radio stations, and methods of frequency-dividing an oscillating signal.

There is disclosed configurable frequency-divider circuitry for generating a target signal of a frequency Fr/Di based on a reference signal of a frequency Fr, where Di is an integer divider ratio, the frequency-divider circuitry comprising: N divider stages organised into a ring, each stage configured to receive an input signal and generate an output signal, with the output signal of each successive stage in the ring being the input signal of the next stage in the ring, wherein: the ring of stages is controlled by the reference signal so that the output signals are governed by the reference signal; the target signal is one of the output signals or a signal derived therefrom; and at least one of the stages is a configurable stage, whose mode of operation is configurable based on a configuration signal to configure the value of Di.

A setting data output circuit (3) is configured to update setting data in synchronization with a frequency divided signal output from a dual modulus frequency divider on a last stage out of the dual modulus frequency dividers to which a non-significant reset signal is output from a reset circuit (6) which are included in a plurality of dual modulus frequency dividers (1-1 and 1-2) in a first frequency divider group (1). As a result, when a frequency dividing ratio of the dual modulus frequency divider on the last stage out of valid dual modulus frequency dividers contributing to frequency dividing operation is 3, it is possible to realize normal frequency dividing operation even in a case in which frequency dividing ratio setting data to decrease the number of valid dual modulus frequency dividers contributing to the frequency dividing operation is provided.

In accordance with an embodiment, a circuit includes an input clock terminal, an output clock terminal, a first input data terminal, and a set of input data terminals having a number of terminals. A divide-by-two block is coupled to the output clock terminal. A modular one-shot clock divider is coupled between the input clock terminal and the divide-by-two block. The modular one-shot clock divider is further coupled to the set of input data terminals. An intermediate clock generation block is coupled between the input clock terminal and the modular one-shot clock divider. The intermediate clock generation block includes a first digital logic block coupled between the input clock terminal and the modular one-shot clock divider. The first digital logic block is further coupled to the first input data terminal, and a clock-blocking block is coupled between the divide-by-two block and the first digital logic block.

A frequency divider circuit includes: a first frequency dividing circuit configured to divide a first clock signal to generate a first frequency-divided clock signal; a second frequency dividing circuit configured to divide a second clock signal having the same frequency as the first clock signal and having a first phase difference with respect to the first clock signal to generate a second frequency-divided clock signal; a detection circuit configured to detect a phase relationship between the first frequency-divided clock signal and the second frequency-divided clock signal; and a selection circuit configured to select and output one of the second frequency-divided clock signal and an inverted signal of the second frequency-divided clock signal which are generated by the second frequency dividing circuit, based on the phase relationship between the first frequency-divided clock signal and the second frequency-divided clock signal detected by the detection circuit

Exemplary embodiments include an electronic frequency-divider circuit comprising a multi-phase generator circuit configured to: receive an oscillating input signal having a frequency f; determine an integer divide ratio Q based on a first control signal input; and based on the oscillating input signal, generate an N-phase output signal having a frequency f-divided-by-M, wherein M is an integer and adjacent phases of the N-phase output signal are separated by 360-divided-by-(M-times-Q) degrees. The divider circuit can also include a control circuit configured to receive a control input and, based on the control input: provide the first control signal to the multi-phase generator circuit; and select a particular phase of the N-phase output signal. Exemplary embodiments also include a phase-locked loop circuits, transceiver circuits, radio stations, and methods of frequency-dividing an oscillating signal.

An electronic circuit arranged to receive an oscillating signal and output an output signal at a frequency having a frequency relation with the oscillating signal defined by a divide ratio is provided. The electronic circuit comprises a first frequency divider arranged to receive the oscillating signal and output N frequency divided signals of different phases, a second frequency divider arranged to receive one of the N signals and frequency divide the received signal by a value given by a first control signal provided to the second frequency divider, N latch circuits each being arranged to receive a respective one of the N signals at a clocking input of the respective latch circuit and to receive an output of the second frequency divider at an input of the respective latch circuit, a multiplexer circuit arranged to receive outputs of the N latch circuits and to output a signal, on which the output signal is based, selected from the received signals based on a second control signal provided to the multiplexer circuit, and a control circuit arranged to provide the first control signal and the second control signal based on the divide ratio. A phase-locked loop circuit, a transceiver circuit, a radio station, and a method of frequency dividing an oscillating signal are also provided.