Apparatuses and methods for providing voltages to conductive lines between which clock signal lines are disposed are disclosed. Voltages provided to the conductive lines may provide voltage conditions for clock signals on the clock signal lines that are relatively the same for at least some of the clock edges of the clock signals. Having the same voltage conditions may mitigate variations in timing/phase between the clock signals due to different voltage influences when a clock signal transitions from a low clock level to a high clock level.

Aspects of this disclosure relate to adjusting a phase of a clock signal provided to a device based on a feedback signal from the device. The feedback signal can provide phase information associated with the device and/or other information associated with the device, such as temperature information. A feedback signal processor can compute a phase control signal based on the feedback signal. The phase control signal can be used to adjust the phase of the clock signal. By adjusting the phase of one or more clock signals, several devices, such as data converters, can be synchronized.

A clock distribution network and method of distributing a clock signal is disclosed. In one embodiment, a clock distribution network is coupled to at least a first circuit. The clock distribution network includes a clock source configured to generate a differential clock signal and provide it to a current mode logic (CML) driver. The CML driver is configured to transmit the clock signal over a differential signal path. A CML receiver is coupled to receive the clock signal via the differential signal path.

A multi-phase clock generator circuit includes a phase reference generator circuit configured to generate a phase reference signal in response to a phase selection signal and a peak ramp signal. A phase error correction circuit is configured to provide an error signal based on a synchronization clock signal and a multi-phase clock signal. The error signal is applied to the phase reference signal to correct for phase errors in the multi-phase clock signal. A comparator is configured to compare a ramp signal and the phase reference signal to produce the multi-phase clock signal.

A duty cycle conversion circuit portion comprises N inverters, wherein N is an integer greater than two. The duty cycle conversion circuit is arranged to receive N input signals each having a duty cycle between 1/N and 2/N. Each of the N input signals is applied to a respective input terminal of one of the N inverters such that each inverter receives a different input signal. Each of the N input signals is applied to a respective power terminal of one of the N inverters such that each inverter is powered by a different input signal. Each inverter receives different input signal at its respective input terminal to the input signal applied to its respective power terminal.

A circuit for estimating a time difference between a first signal and a second signal, the circuit comprising: a first signal line for receiving the first signal; a delay unit configured to receive the second signal and delay the second signal so as to provide a plurality of delayed versions of the second signal, each delayed version being delayed by a different amount of delay to the other delayed versions; a comparison unit configured to compare each of the delayed versions of the second signal with the first signal so as to identify which of the delayed versions of the second signal is the closest temporally matching signal to the first signal; and a difference estimator configured to estimate the time difference between the first and second signals in dependence on the identified delayed version.

Aspects of the disclosure include an apparatus that has a first clock generator and a second clock generator. The first clock generator is configured to drive a first circuit, causing the first circuit to (i) receive a signal corresponding to an audio input, and (ii) determine whether an energy level of the signal exceeds a predetermined threshold. The second clock generator is activated when the first circuit determines that the energy level of the signal exceeds the predetermined threshold. The second clock generator is configured to drive a second circuit, causing the second circuit to determine whether the signal matches a predetermined pattern. A third circuit is activated when the second circuit determines that the signal matches the predetermined pattern.

A circuit for providing a fractional divider/multiplier using harmonic recombination may include a power amplifier, an oscillator coupled to the power amplifier, and a divider coupled to the oscillator. In one or more implementations, the divider is configured to generate one or more phases of a harmonic from the oscillator to reduce signal interference from the power amplifier. In one or more implementations, the divider includes a divide-by-M divider, where M is a positive integer, and an array of transconductance cells coupled to the output of the divide-by-M divider. In one or more implementations, the divider includes an inductor or a filter coupled to the output of the array of transconductance cells. In one or more implementations, the oscillator includes a logical gate and a resistor-capacitor circuit coupled in series feedback with a multi-stage ring oscillator. The oscillator may include a divider coupled to the multi-stage ring oscillator.

Apparatuses and methods for providing multiphase clock signals are described. An example apparatus includes first, second, third and fourth clocked inverters, first and second clock terminals, and first and second latch circuits. An input node and an output node of the first clocked inverter is coupled respectively to an output node of the fourth clocked inverter and an input node of the second clocked inverter. An input node and an output node of the third clocked inverter is coupled to an output node of the second clocked inverter and an input node of the fourth clocked inverter. The first and second clock terminals are supplied respectively with first and second clock signals. The first latch is coupled between the output nodes of the first and third clocked inverters, and the second latch circuit is coupled between the output nodes of the second and fourth clocked inverters.

A passable latch circuit and variable delay chains built with one or more passable latch circuits are disclosed. The passable latch circuit has a dynamic latch including a first P-transistor, a first N-transistor, a second P-transistor, a second N-transistor and a clock input circuitry. The passable latch circuit further includes a control switch connected between the gates of the second P-transistor and the second N-transistor. The control switch has an on state and an off state, and the passable latch circuit is configured to have different delays by controlling the state of the control switch.