Abstract: A phase locked loop (PLL) based frequency sweep generator and methods for performing a frequency sweep are disclosed. In one implementation, the frequency sweep generator includes a circuit configured to generate a signal having a saw-tooth wave frequency ramp. The saw-tooth wave frequency ramp includes a rising portion and a resetting portion. The resetting portion has a shorter duration than the rising portion and includes a plurality of steps for decrementing the frequency of the signal.

Abstract: A phase locked loop (PLL) based frequency sweep generator and methods for performing a frequency sweep are disclosed. In one implementation, the frequency sweep generator includes a circuit configured to generate a signal having a saw-tooth wave frequency ramp. The saw-tooth wave frequency ramp includes a rising portion and a resetting portion. The resetting portion has a shorter duration than the rising portion and includes a plurality of steps for decrementing the frequency of the signal.

Abstract: A fractional-N synthesizer system including a plurality of fractional-N synthesizers all updated to simultaneously generate an output frequency from the same reference frequency, a phase locked loop having an output signal whose frequency is a fractional multiple of the input reference frequency; the phase locked loop including a frequency divider, an interpolator responsive to an input fraction to provide to the frequency divider an output which has a fractional value equal to on average, the input fraction; and a timeout circuit responsive to the reference frequency for generating an output a predetermined time after updating to initialize the interpolator in each synthesizer to the same start conditions for locking together the phase of the frequency outputs of all of the synthesizers at the updated frequency.

Abstract: A phase detection apparatus is described for use in a phase lock loop (PLL). The apparatus has a first input for a reference signal, a second input for a loop feedback signal and an output for the phase difference signal. Two D-type flips flops are provided, the first being clocked with the reference signal and the second with the loop feedback signal. The output of the second flip-flop is delayed relative to the first flip-flop, thereby effecting minimal overlap, when using the phase detection apparatus in a fractional- N phase lock loop, of the interpolator activity with that of the charge pump.

Abstract: An indirect variable frequency synthesiser for synthesising selectable frequencies from a reference frequency including a multi-divisor programmable frequency divider located in a feedback loop of the frequency synthesiser for dividing the feedback frequency in the feedback loop, the divider being responsive to a varying control signal applied thereto representative of a rational number of selectable value for selecting the divisor thereof for fractional division of the feedback frequency. A variable modulus interpolator converts a fractional part of the rational number of selectable value to a varying digital code representative of the fractional part of the rational number.

Abstract: A differential charge pump PLL synthesizer with adjustable tuning voltage range including a voltage controlled oscillator responsive to a tuning voltage to provide an output frequency. A phase detector circuit is responsive to a reference frequency and the sub-multiple of the output frequency for generating up and down pulses. A differential charge pump is responsive to the up and down pulses for generating positive and negative differential current pulses. A loop filter is responsive to the positive and negative differential current pulses for providing a differential voltage. A differential amplifier circuit is responsive to the differential voltage and a shift voltage applied at a voltage terminal for shifting the output voltage range of the differential amplifier circuit to provide a predetermined tuning voltage range.

Abstract: A fast lock phase lock loop (PLL) with minimal phase disturbance when switching from wide bandwidth mode to narrow bandwidth mode including a phase frequency detector, a charge pump, a loop filter and a voltage controlled oscillator, and a sequencer circuit for, at a first time, initiating an increase in the charge pump current to increase the loop gain to widen the loop bandwidth and initiating a decrease in the resistance in the loop filter to increase the phase margin of the PLL in the wide bandwidth mode; at a second time, initiating a reduction in the charge pump current to reduce the loop gain and bandwidth, and; at a third time, initiating an increase in the resistance in the loop filter to increase the phase margin of the PLL in the narrow bandwidth mode.

Abstract: A pulse width modulated common mode feedback technique for a differential charge pump includes averaging the output of a differential charge pump to determine the common mode voltage; generating from the pump up and pump down pulses a set of up source pulses and down source pulses and a set of up sink pulses and down sink pulses and adjusting, in response to a difference between a reference voltage and the common mode voltage, the width of at least one of the sets of source and sink pulses to match the reference common mode voltages.

Abstract: A gain compensation technique for a fractional-N phase lock loop includes locking a reference signal with the N divider feedback signal in a phase lock loop including a phase detector, charge pump, loop filter and voltage control oscillator with an N divider in its feedback loop; driving the N divider with a sigma delta modulator including at least one integrator to obtain a predetermined fractional-N feedback signal; and commanding a scaling in phase lock loop gain by a predetermined factor and synchronously inversely scaling by that factor the contents of at least one of the integrators.

Abstract: A charge pump system for a fast locking phase lock loop includes a set n of charge pump units; and a control logic circuit for enabling the set of n charge pump units to produce up and down charge pulses with a nominal charge pump mismatch in a wide bandwidth mode; and in a narrow bandwidth mode enabling at least a subset of the n charge pump units sequentially to produce an average charge pump mismatch in narrow bandwidth mode that matches the nominal charge pump mismatch in the wide bandwidth mode.

Abstract: A chopped charge pump with matching up and down pulses including a first pair of current sources, a second pair of current sources, and a switching circuit for switching on in a first phase one of each pair to provide up current pulses and the other of each pair to provide down current pulses and switching on in a second phase the other of each pair to provide up current pulses and the one of each pair to provide down current pulses to offset error in the current response of the pairs of current sources.