Abstract: Generating an output signal having a frequency of 1/(M+F) of the frequency of the input signal, wherein M represents an integer and F represents a non-zero fraction. Assuming F equals (Q/R) in one embodiment, wherein Q and R are integers, R intermediate signals phase shifted by equal degree (relative to the one with closest phase shift) in one clock period of the input signal are generated. A selection circuit may select one of the intermediate signals in one clock cycle, select the successive signals with increasing phase shift in Q clock cycles, and leave the intermediate signal with the same shift as in the previous clock cycle in the remaining ones of the M clock cycles. A counter counts a change of state in the output of the selection circuit, and generates a pulse representing an edge of the output signal at the time instance when counter counts M.

Abstract: A divider is provided. The divider includes a first flip-flop, a flip-flop array, a first NOT gate, a second NOT gate, and a circuit. The first flip-flop can be triggered by a frequency signal. The first NOT gate is coupled between a positive output terminal of the last second flip-flop and the first flip-flop. The second NOT gate is coupled between the positive output terminal of the last second flip-flop and the circuit. The first NOT gate and the second NOT gate are controlled by the mode control signal for enabling. If N is an odd number, the circuit includes a wire, and if N is an even number, the circuit includes a third NOT gate.

Abstract: A programmable integer and fractional frequency divider is provided. The programmable divider divides a frequency of an input signal by a first divisor to generate an output signal, and comprises a programmable integer frequency divider and a fractional number switch. The programmable integer frequency divider divides the frequency of the input signal by a second divisor to generate the output signal, wherein the second divisor is first or second integers depending on a divisor switching signal. The fractional number switch calculates a pulse count of the output signal, and generates the divisor switching signal to switch from the first to the second integer when the pulse count of the output signal equals to a predetermined pulse count determined by a fractional part of the first divisor, and receives a fractional divisor control signal to change the predetermined pulse count, thereby changing the fractional part of the first divisor.

Abstract: The present invention generates an output clock signal CLKreq having a frequency freq between the frequency fref/A of a divided clock signal CKL1 and the frequency fref/(A+1) of a divided clock signal CLK2. A clock divider circuit selectively generates divided clock signals CLK1, CLK2. A discrete value correction circuit controls the clock divider circuit so as to repeat C times the process of generating the clock signal CLK2 once and the clock signal CLK1 (Q?1) times and then to generate the clock signal CLK1 R times if C<D and so as to repeat D times the process of generating the clock signal CLK1 once and the clock signal CLK2 (Q?1) times and then to generate the clock signal CLK2 R times if C>D. A, B, and C are natural numbers satisfying freq=fref/(A+C/B). In D=B?C, Q is a quotient of B/C if C<D or a quotient of B/D if C>D.

Abstract: A frequency divider comprises a first differential input pair, a second differential input pair, a first capacitive element having first and second ends, a second capacitive element having first and second ends, and four current sourcing elements. The first differential input pair includes first and second transistors that receive a differential local oscillator signal. The second differential input pair includes first and second transistors that receive the differential local oscillator signal. The first capacitive element communicates with first terminals of the transistors of the first differential input pair. The second capacitive element communicates with first terminals of the transistors of the second differential input pair. The four current sourcing elements respectively communicate with the first terminals of the transistors of the first and second differential input pairs.

Abstract: A digital clock divider includes an adder and a clock division device configured to receive a first clock signal with a first frequency and to output a second clock signal having a lower frequency relative to the first frequency. The digital clock divider also includes a division value separation device and a feedback section. The division value separation device is configured to divide an addition value output from the adder into an integer value and a fractional value. The feedback section is configured to provide to the adder a feedback value, the feedback value comprising the fractional component or the fractional component modified by a processing device. The adder is configured to add the feedback value to an applied division value. The clock division device is controlled on the basis of the integer value.

Abstract: The present invention discloses a rate multiplication method for counting a sequence of original pulse signals and outputting a target pulse signal. In this method a comparison data and original pulse signal sequence is received. The original pulse signal sequence is counted in order to obtain a pulse count. Comparing the pulse count and the comparison data. If the pulse count is equal to the comparison data, a corresponding original pulse signal is outputted as the target pulse signal. Reset and recount the pulse count, and obtain which repeatedly. In this present invention the pulse count and the pulse interval between the target pulse signals can be determined freely according to a rate.

Abstract: A divide-by-n process is effected via a scale-by-four/n process followed by a divide-by-four process. A quadrature input clock facilitates a scale-by-four/n process, via a clock-phase selection process. By incorporating a terminal divide-by-four process, quadrature output signals are easily provided. A divide-by-three quadrature divider effects the scale-by-4/n process via a selection of every third quadrature clock phase, and the quadrature output of the divide-by-four process provides the control signals to effect this every-third clock phase selection.

Abstract: Circuits and methods and for dividing a frequency of an input signal by an integer divider value. The circuit generally comprises (a) a first frequency divider, including a first plurality of serially connected delay elements receiving the input signal and a first configurable feedback network, (b) a second frequency divider, including a second plurality of serially connected delay elements receiving an inverse of the input signal and a second configurable feedback network (c) configurable logic configured to select and/or combine outputs of the first and second frequency dividers and to produce a frequency divided output signal, and (d) a programmable circuit configured to selectably configure the first and second configurable feedback networks and the configurable logic. The present invention advantageously provides for a frequency divider structure that can be easily programmed to provide any integer divide ratio with a 50% duty cycle.

Abstract: A divide-by-N/(N+0.5) frequency divider is disclosed. Two pairs of flip-flops are respectively triggered by an input clock and an inverted input clock, and a frequency-dividing selector is used to select one output of the two pairs of flip-flops as frequency-divided output signal. Two latches are respectively triggered by the input clock and the inverted input clock, and a modulus selector is used to select one output of the two latches. A modulus logic circuit determines being in either N frequency-dividing mode or (N+0.5) frequency-dividing mode based on a modulus control signal. A frequency-dividing logic circuit receives output of the modulus logic circuit and an inverted frequency-divided output signal to swallow half the input clock per output cycle in the (N+0.5) frequency-dividing mode, therefore obtaining division resolution of half the input clock.

Abstract: A divide-by-N/(N+0.5) frequency divider is disclosed. Two pairs of flip-flops are respectively triggered by an input clock and an inverted input clock, and a frequency-dividing selector is used to select one output of the two pairs of flip-flops as frequency-divided output signal. Two latches are respectively triggered by the input clock and the inverted input clock, and a modulus selector is used to select one output of the two latches. A modulus logic circuit determines being in either N frequency-dividing mode or (N+0.5) frequency-dividing mode based on a modulus control signal. A frequency-dividing logic circuit receives output of the modulus logic circuit and an inverted frequency-divided output signal to swallow half the input clock per output cycle in the (N+0.5) frequency-dividing mode, therefore obtaining division resolution of half the input clock.

Abstract: Circuits and methods are provided for implementing programmable sub-integer N frequency dividers for use in, e.g., frequency synthesizer applications, providing glitch free outputs signals with minimal fractional spurs. Phase-rotating sub-integer N frequency dividers are programmable to provide multi-modulus division with a wide range of arbitrary sub-integer division ratios.

Abstract: A programmable integer and fractional frequency divider is provided. The programmable divider divides a frequency of an input signal by a first divisor to generate an output signal, and comprises a programmable integer frequency divider and a fractional number switch. The programmable integer frequency divider divides the frequency of the input signal by a second divisor to generate the output signal, wherein the second divisor is first or second integers depending on a divisor switching signal. The fractional number switch calculates a pulse count of the output signal, and generates the divisor switching signal to switch from the first to the second integer when the pulse count of the output signal equals to a predetermined pulse count determined by a fractional part of the first divisor, and receives a fractional divisor control signal to change the predetermined pulse count, thereby changing the fractional part of the first divisor.

Abstract: This invention adds a non-linear sweep accumulator to the conventional sigma-delta fractional-N divider to produce a N.F value that is a polynomial function of time. This allows any non-linear sweep profiles to be approximated.

Abstract: An information handling system including a divider circuit is disclosed that divides an input clock signal by a non integer value to generate an output clock signal. The resultant output clock signal exhibits a 50/50 duty cycle in one embodiment. The disclosed divider methodology permits the design of advanced circuit functions, such as double data rate memory operations, without the need for additional clock signal sources.

Abstract: A clock divider includes a first state storage unit, a second state storage unit a first control signal generating unit a state update unit and an output unit. The first state storage unit receives an update signal to perform transition of a first state value in synchronization with a clock signal. The second state storage unit performs transition of a second state value in synchronization with a first state signal corresponding to the first state value. The first control signal generating unit generates a first control signal for determining a first state transition path based on a first division ratio control signal. The state update unit generates the update signal based on the first control signal and the first state signal. The output unit selectively output the first state signal or a second state signal corresponding to the second state value.

Abstract: Frequency division methods and circuits are provided for producing an output clock signal with a frequency related to the frequency of an input clock signal by a predetermined factor. The method and circuit rely on the input clock signal and on feedback from the output signal to produce an intermediate signal. The frequency of the intermediate signal is divided to produce the output clock signal. The method and circuit may be implemented using few circuit components. In an exemplary embodiment, the method and circuit may be used to produce an output clock signal with a frequency that is two-and-a-half times lower than the frequency of the input clock signal.

Abstract: Generating an output signal having a frequency of 1/(M+F) of the frequency of the input signal, wherein M represents an integer and F represents a non-zero fraction. Assuming F equals (Q/R) in one embodiment, wherein Q and R are integers, R intermediate signals phase shifted by equal degree (relative to the one with closest phase shift) in one clock period of the input signal are generated. A selection circuit may select one of the intermediate signals in one clock cycle, select the successive signals with increasing phase shift in Q clock cycles, and leave the intermediate signal with the same shift as in the previous clock cycle in the remaining ones of the M clock cycles. A counter counts a change of state in the output of the selection circuit, and generates a pulse representing an edge of the output signal at the time instance when counter counts M.

Abstract: Within a mobile communication device (for example, a cellular telephone), there is a local oscillator. The local oscillator includes a novel frequency divider that includes a novel configurable multi-modulus divider (CMMD). The frequency divider is configurable into a selectable one of multiple configurations involving different mixes of synchronous and asynchronous circuitry. In each configuration, the frequency divider produces an amount of noise and consumes an amount of power. Power consumption is loosely inversely related to noise produced in that the modes with the highest power consumption produce the least amount of noise, and vice versa. The mobile communication device is operable in one of multiple different communication standards (for example, GSM, CDMA1X and WCDMA). The different communication standards impose different noise requirements on the frequency divider.

Abstract: A method for dividing a plurality of multiphase signals comprising performing resetable divider stages to the plurality of multiphase signals forming a plurality of divided multiphase signals having a monotonic increasing phase with equal spacing and an ideal duty cycle of 50% through a plurality of resetable dividers, wherein the plurality of divided multiphase signals have no phase ambiguity; and producing a plurality of periodic reset signals to the plurality of resetable dividers to enable the plurality of resetable dividers to divide the plurality of multiphase signals in a timely correct sequence to form the divided multiphase signal through a reset signal generator, the plurality of periodic reset signals being produced by a combinational network of the reset signal generator, the combination network is configured for generating a number of pulses based on the plurality of multiphase signals and performing a plurality of decimation stages and wherein the periodic reset signals are generated solely in r

Abstract: A method for locally generating a ratio clock on a chip includes generating a global clock signal having a global clock cycle. A centralized state machine includes a counter going through a complete cycle in response to a non-integer number of global clock cycles, the state machine generating a control signal in response to the counter. The control signal is provided to staging latches, the staging latches generating a clock high signal and a clock low signal. Local pass gates generate an (n+0.5)-to-1 clock signal in response to the global clock signal, the clock high signal and the clock low signal.

Abstract: The present invention relates to frequency dividers. The frequency divider comprises an input, a counter, a first comparator, an interconnect, and an output. The counter has a counter reset port and is configured to receive a clock signal from the input and to produce a sum signal. The first comparator is configured to receive the sum signal, to compare the sum signal to a first integer, and to produce a first comparison signal. The interconnect is configured to convey the first comparison signal from the first comparator to the counter reset port. The output coupled to the first comparator. The clock signal has a periodic waveform. The sum signal represents a first sum, which equals a number of waveforms of the clock signal received by the counter after the counter has been reset. In a first embodiment, the first integer is selectable from a set of at least three consecutive integers. In a second embodiment, a frequency of the clock signal is at least 1.5 gigahertz.

Abstract: A method and apparatus for dividing the frequency of an input clock signal by an odd integer is disclosed. The output of two asymmetrical clock dividers may be combined to produce a divided clock signal having a symmetrical waveform. Finite state machines may be used as asymmetrical clock dividers having desired duty cycles and relative turn-on and turn-off times to produce signals that combine to form a symmetrical divided clock signal. Alternatively, the output of an asymmetrical clock divider may be delayed by one input clock signal half-cycle and combined with the original asymmetrical signal to form a symmetrical divided clock signal.

Abstract: A signal converter is comprised of a plurality of counters (“macro-counters”). In turn, each of the macro-counters is comprised of a plurality of single-bit counters (“micro-counters”) that are adapted to receive configuration data in the form of bit fields. The configuration data is comprised of data corresponding to a plurality of coefficients and of data for grouping the micro-counters into the macro-counters. The coefficients are derived from an input signal/output signal ratio of the converter, and control the manner by which the macro-counters generate the output signal. Thus the converter can be programmed by an end-user in the field.

Abstract: A multiphase divider includes a plurality of resetable dividers configured for performing resetable divider stages to a plurality of multiphase signals forming a plurality of divided multiphase signals having a monotonic increasing phase with equal spacing and an ideal duty cycle of 50%, wherein the plurality of divided multiphase signals have no phase ambiguity; and a reset signal generator configured for producing a plurality of periodic reset signals to the plurality of resetable dividers to enable the plurality of resetable dividers to divide the plurality of multiphase signals in a timely correct sequence to form the divided multiphase signal, the plurality of periodic reset signals being produced by a combinational network of the reset signal generator, the combinational network is configured for generating a number of pulses based on the plurality of multiphase signals and performing decimation stages to reduce the number of pulses within the pulse traces.

Abstract: A programmable frequency divider for dividing the frequency of a source signal according to a selectable divisor which is obtained based on a plurality of divisor signals and outputting a result signal having a divided frequency includes at least one cell of a first type. The cells of the first type are cascaded with each other. The programmable frequency divider synchronously resets all of the cells of the first type according to a reset signal in order to selectively switch each cell of the first type to perform a divide-by-two or divide-by-three operation according to a corresponding divisor signal. The last cell of the first type outputs the result signal having the divided frequency.

Abstract: Disclosed is an apparatus for multiple-divisor prescaler, which includes an odd/even core divider, a divisor control logic unit, an odd number inserted mechanism, and an n-order divided-by-2 divider with changeable trigger edges. This invention uses a clock toggle mechanism to vary the trigger edges of each divided-by-2 divider in the n-order divider, and associates the odd/even core divider to realize the multiple-divisor prescaler apparatus. Thereby, it achieves the purpose of being divided by 30/31. In addition, it increases the divisor range up to 2n?1+2 and 2n+1 through the use of the clock toggle mechanism.

Abstract: A system providing a phase or frequency modulated signal is provided. In general, the system includes a phase locked loop (PLL) having a fractional-N divider in a reference path of the PLL operating to divide a reference frequency based on a pre-distorted modulation signal. Pre-distortion circuitry operates to provide the pre-distorted modulation signal by pre-distorting a modulation signal such that a convolution, or cascade, of the pre-distortion and a transfer function of the PLL results in a substantially flat frequency response for a range of modulation rates greater than a bandwidth of the PLL.

Abstract: A clock multiplication circuit simple in configuration, easy to adjust the characteristics thereof, and capable of shortening lockup time. The circuit delivers an output clock signal at a frequency that is a multiple of the frequency of a reference clock signal as inputted. A counter counts the number of rising edges of the output clock signal existing during a High level period of the reference clock signal, delivering a count value CN. A subtracter subtracts the count value from a reference value BN, delivering a difference value DN. An adder adds the difference value to a preceding integrated value, calculating a new integrated value. A DA converter delivers the analog control voltage corresponding to the integrated value. A VCO delivers the output clock signal at a frequency corresponding to the analog control voltage. The frequency of the output clock signal is controlled such that DN=BN?CN=0.

Abstract: A clock frequency divider circuit and method of dividing a clock frequency are provided. The clock frequency divider circuit includes a first flip-flop circuit, a second flip-flop circuit, a third flip-flop circuit, a first logic control unit and a second logic control unit, wherein the first flip-flop circuit has two clock input terminals connected to the second and third flip-flop circuits respectively and two control signal input terminals connected to the first and second logic control units respectively. The second and third flip-flop circuits count rising edges and falling edges of an input frequency under control of the first and second flip-flop circuits and accordingly, symmetric output signals are output from the first flip-flop circuit.

Abstract: Disclosed is a Dual-Modulus Prescaler (DMP) dividing an input signal into an output signal, comprising: a synchronous counter, including a D-Flip-Flop (DFF), a first NOR-Flip-Flop and a second NOR-Flip-Flop, receiving the input signal, the division ratio thereof being based on an intermediate signal; a control logic, controlling the division ratio of the synchronous counter and selecting the output frequency based on first and second control signals, and outputting the intermediate signal to the synchronous counter; and an asynchronous counter, coupled to the control logic and the synchronous counter, having a chain of five DFFs.

Abstract: A method for forming clock pulses of a second clock cycle (AT, TT) from clock pulses of a specified first clock cycle (ET) in a bus system having at least one user, a first number (E) of the clock pulses of the first clock cycle being determined or specified in a specifiable time interval and a second number (A) of the clock pulses of the second clock cycle being determined or specified in the specifiable time interval, in which an intermediate value (R) of the number of clock pulses is specified in the specifiable time interval, and the intermediate value (R) is compared to a value (C) which is formed from the first number (E) of clock pulses and the second number (A) of clock pulses and from the comparison a truth value (TRUE, FALSE) is yielded, and a clock pulse of the second clock cycle (AT, TT) is generated as a function of the truth value (TRUE, FALSE).

Abstract: An (N?1)/N prescaler is provided, where N is an S power of 2. The prescaler uses only S flip-flops. The (N?1)/N prescaler receives a clock input from a high frequency oscillator, and provides an output line to a counter. The (N?1)/N prescaler receives a divide-by-(N?1) signal from the counter, and responsive to the divide signal, causes the prescaler to divide by a factor of (N?1); otherwise, the prescaler divides by a factor of N.

Abstract: The present invention relates to a fractional divider system for a low-power timer with reduced timing error at wake-up. The fractional divider system includes a fractional divider circuit operable to produce an output signal. The fractional divider system also includes a high speed crystal oscillator connected to the fractional divider circuit operable to start on wake-up from the low power mode, and a high speed clock divider circuit connected to the high speed crystal oscillator circuit. The high speed crystal oscillator circuit is configured to sample the output signal and a current state of the total timing error from the fractional divider circuit. The sampled output signal is employed to trigger the high speed clock divider circuit and the sampled current state of the total timing error preloads the high speed clock divider circuit, which is operable to synchronize a first pulse of the output signal to the ideal clock timing to an accuracy within 1.5 periods of the high speed clock.

Abstract: A method and device of frequency division with a division ratio: comprising: an input divider with a division ratio NPs receiving the frequency Fe at input and delivering a signal to an insertion/substitution divider, the insertion/substitution divider having an input of variation of the division ratio, delivering a command frame to the input divider and generating an end-of-count signal, the insertion/substitution divider being adapted to the insertion of one or more input divider cycles and/or the substitution of an input divider cycle in the command frame.

Abstract: A fast latch including: a NAND stage adapted to receive a clock signal and a data input signal; a clocked inverter stage, a first input of the clocked inverter stage coupled to the output of the NAND stage and a second input of the clocked inverter stage coupled to the clock signal; a first inverter stage, a first input of the first inverter stage coupled to an output of the clocked inverter and a second input of the first inverter stage coupled to a reset signal; and a second inverter stage, having an output, an input of the second inverter stage coupled to an output of the first inverter stage. The fast latch is suitable for use in frequency divider circuits also described. A homologue of frequency dividers using the fast latch, a unique 3/4 divider and a 2 divider not using the fast latch are also disclosed.

Abstract: A frequency synthesizer includes a circuit which selectively outputs multiple output signals having different respective periods to drive the average period of a combined output signal to substantially equal a desired period.

Abstract: A clock synthesizer for dividing a source clock by N.R including a logic circuit, a delay line, a select circuit, an accumulator, and a clock divider circuit. The logic circuit divides N.R by 2M to get NNEW.RNEW in which NNEW is zero and RNEW is at least 0.5. The delay line receives a first clock and has multiple delay taps, where the first clock is based on the source clock. The select circuit selects the delay taps based on a tap select value and provides a delayed clock. The accumulator adds RNEW for each cycle of the delayed clock and performs a modulo function on a sum value to generate the tap select value. The clock divider circuit transitions an output clock based on selected transitions of the delayed clock, which is achieved by dividing the first clock or the delayed clock by 2M?1.

Abstract: The present invention provides for state correction. A first value in a state circuit is received from a flip flop. The received value is transmitted to a second flip flop. The received value within the second flip flop is altered if an error condition arises. The received value is transmitted to a third flip flop. In one aspect, the received value transmitted to the third flip flop comprises an unaltered received value. In another aspect, the received value transmitted to the third flip flop comprises transmitting an altered received value. This allows for an incorrect state within the state machine to change to a correct state after a few clock pulses.

Abstract: A dual-modulus prescaler circuit for a frequency synthesizer comprises a plurality of asynchronous dividers-by-two connected in series, a phase selector unit (11) between two dividers-by-two (10, 12) and a control unit (13) for supplying control signals (S0, S1, S2) to the selector unit as a function of a selected mode. Said selector unit receives four signals phase shifted by 90° in relation to each other from a master-slave first divider and supplies a selected one of the four phase shifted signals. The control signals (S0, S1, S2) are supplied to the selector unit for selecting one of the four phase shifted signals (F2) at the output in a particular division period. As a function of the control signals supplied by the control unit (13) in one selected of the modes, the selector unit effects phase switching in each division period between two phase shifted signals selected by each branch. The second phase shifted signal i in phase lead of 90° in relation to the first phase shifted signal.

Abstract: A divider is disclosed herein. The divider includes a sequence of divide stages programmably coupled to provide a variety of divide ratios. The divider also includes one or more multiplexers to feedback the output of a divide stage to the input of a divide stage earlier in the sequence of divide stages. The divider may also include duty cycle correction circuitry and self correction logic to correct abnormal logic states. The divide stages can operate in synchronism with each other. Multiplexer functionality, self correction circuitry functionality, and divide stage functionality may be implemented in a combination latch circuit.

Abstract: An MN counter with analog interpolation (“MNA counter”) includes an MN counter, a multiplier, a delay generator, and a current generator. The MN counter receives an input clock signal and M and N values, accumulates M for each input clock cycle using a modulo-N accumulator, and provides an accumulator value and a counter signal with the desired frequency. The multiplier multiplies the accumulator value with an inverse of M and provides an L-bit control signal. The current generator implements a current locked loop that provides a reference current for the delay generator. The delay generator is implemented with a differential design, receives the counter signal and the L-bit control signal, compares a differential signal generated based on the counter and control signals, and provides the output clock signal. The leading edges of the output clock signal have variable delay determined by the L-bit control signal and the reference current.

Abstract: A frequency-divided reference frequency clock is provided as a reference input to a phase comparator. An oscillation frequency signal of a controllable oscillator, having a frequency associated with another reference frequency clock, is frequency divided by a frequency division factor switching type comparison-input frequency division circuit. The resultant frequency-divided clock is provided as a comparison input to the phase comparator. The frequency division factor of the comparison-input frequency division circuit is switched from one to another based on a frequency division factor control signal to generate an oscillation frequency signal having a predetermined frequency ratio relative to another reference frequency clock. Thus, three reference frequency clocks of 27 MHz, 33.8688 MHz, and 36.864 MHz in accord with the MPEG format are obtained with a sufficient S/N ratio.

Abstract: A frequency divider device includes a divider input and a phase count and select section. The phase count and select section includes at least two phase count and select inputs each communicatively connected to the divider input (for receiving each at least one phase shifted signal having a phase difference with respect to the other phase shifted signal); a signal generator section (for generating an output signal); a switch device; an inverter device; a counter device; and, a switch actuator device.

Abstract: The present invention provides for state correction. A first flip flop coupled to a second flip flop. A state correction circuit coupled to the output of the second flip flop. A third flip flop is coupled to the output of the state correction circuit. A fourth flip flop is coupled to the output of the third flip flop.

Abstract: A phase-locked loop circuit has a fractional-frequency-interval phase frequency detector, a charge pump, an oscillator, and a divider. The fractional-frequency-interval phase frequency detector has a phase frequency detector unit that is utilized as or comprises a plurality of phase frequency detector units. The divider is responsive to the oscillator and provides divider values for dividing an oscillator frequency by the divider values to provide a feedback frequency of a feedback loop signal of the phase-locked loop circuit. A reference input frequency is input as a first input into the phase frequency detector unit. The feedback frequency is input and selectively delayed as second inputs into the phase frequency detector unit so that the second inputs are aligned for input according to the reference input frequency and an oscillator frequency is, in effect, responsive to the phase frequency detector units and allowed to be divided by a fractional-integer divider value.

Abstract: A phase matched clock divider includes a first feed-through flip-flop that receives a first input clock signal, and in response, provides a first output clock signal having the same frequency. The first feed-through flip-flop is enabled and disabled in response to a first reset signal. A plurality of series-connected flip-flops each receives the first input clock signal, and in response, provides a divided output clock signal. Each of the series-connected flip-flops is enabled and disabled in response to a second reset signal. The first and second release signals asynchronously disable the associated flip-flops in response to a third reset signal. The first release signal synchronously enables the first feed-through flip-flop in response to the third reset signal and a release clock signal. The second release signal enables the series-connected flip-flops in response to the third reset signal and a release control signal.

Abstract: A gateless digital circuit and method for generating a second clock with a frequency of N/M of the frequency of a first clock, wherein N and M are integers, N?M/2. The gateless digital circuit having a modulo M function, a register and a adder operable connected to generate the second clock, where both N and M are independently selectable.

Abstract: A frequency divider and related frequency divider designing method for forming a target clock by dividing an original clock by n.5 are disclosed. The method includes the following steps: (a) determining a frequency-dividing ratio of n.5*2, (b) generating a first triggering phase and a second triggering phase relating to the original clock by determining the frequency-dividing ratio, (c) selecting a positive frequency dividing circuit or a negative frequency dividing circuit and an initial value setting manner for the selected positive or negative frequency dividing circuits, and (d) generating the target clock according to the first and second target clocks.

Abstract: The present invention relates to a structure of a delta-sigma fractional type divider. The divider structure adds an external input value and an output value of a delta-sigma modulator to modulate a value of a swallow counter. Therefore, the present invention can provide a delta-sigma fractional type divider the structure is simple and that can obtain an effect of a structure of a delta sigma mode while having a wide-band frequency mixing capability.