A four-phase (or multi-phase) generation circuit, related method of operation, and transceivers or other systems utilizing such a circuit, are disclosed herein. In one example embodiment, the circuit includes two input ports respectively configured to receive positive and negative differential input signals, and four output ports respectively configured to output first, second, third and fourth output signals, respectively, the second, third, and fourth output signals being respectively phase-shifted relative to the first output signal by or substantially by 90, 180, and 270 degrees. Also, the circuit includes four SR latches respectively including output terminals that are respectively coupled to the respective output ports. Further, the circuit includes two tunable delay circuits respectively coupled at least indirectly between the input ports and latches, and two comparison circuits configured to output respective feedback signals. The latches receive two delayed input signals provided by the delay circuits based upon the feedback signals.

A level shifter includes a control circuit and a bias circuit. The control circuit receives a bias voltage, a first signal associated with a first voltage domain, and supply voltages associated with a second voltage domain, and outputs a second signal that is associated with the second voltage domain. The bias circuit generates the bias voltage that is indicative of the duty cycle of the second signal, and provides the bias voltage to the control circuit to control the duty cycle of the second signal. The duty cycle of the second signal is controlled such that a difference between a duty cycle of the first signal and an inverse of the duty cycle of the second signal is less than a tolerance limit.

Routines and methods disclosed herein can increase a power efficiency of a prosthetic hand without drastically reducing the speed at which it operates. A prosthesis can implement an acceleration profile, which can reduce an energy consumption of a motor, or an amount of electrical and/or mechanical noise produced by a motor, as the motor transitions from an idle state to a non-idle state. A prosthesis can implement a deceleration profile, which can reduce the energy consumption of the motor, or an amount of electrical and/or mechanical noise produced by a motor, as the motor transitions from a non-idle state to an idle state.

Apparatuses and methods for phase interpolating clock signals and for providing duty cycle corrected clock signals are described. An example apparatus includes a clock generator circuit configured to provide first and second clock signals responsive to an input clock signal. A duty phase interpolator circuit may be coupled to the clock generator circuit and configured to provide a first and second duty cycle corrected interpolated clock signals. A duty cycle adjuster circuit may be coupled to the duty phase interpolator circuit and configured to receive the first and second duty cycle corrected interpolated clock signals and provide a duty cycle corrected clock signal responsive thereto. A duty cycle detector may be coupled to the duty cycle adjuster circuit and configured to detect duty cycle error of the duty cycle corrected clock signal and provide the adjustment signals to correct the duty cycle error.

A single-ended-to-differential converter for driving an LVDS (Low Voltage Differential Signaling) driving circuit includes a first converting circuit, a second converting circuit, and a controller. The first converting circuit converts an input signal into a first output signal. The first converting circuit has a tunable delay time. The second converting circuit converts the input signal into a second output signal. The second converting circuit has a fixed delay time. The controller generates a first control signal and a second control signal according to the first output signal and the second output signal, so as to adjust the tunable delay time of the first converting circuit.

A circuit for measuring clock jitter includes: an internal signal generator configured to generate an internal clock signal and a single pulse signal, respectively synchronized with an input clock signal; a plurality of delay units being connected in series with each other and configured to generate respective delayed clock signals; a plurality of latch circuits configured to latch the single pulse signal in synchronization with the respective delayed clock signals, and output sampling signals; and a count sub-circuit configured to output a count value resulting from counting a number of active sampling signals of the sampling signals.

The signal generator includes the following: an oscillation generation circuit, configured to generate an initial oscillation signal based on an oscillation control signal; a duty cycle correction circuit, connected to an output end of the oscillation generation circuit and configured to adjust a duty cycle of the initial oscillation signal based on a duty cycle control signal, to generate an adjusted oscillation signal; an output interface, connected to an output end of the duty cycle correction circuit and configured to output the adjusted oscillation signal to an external test system; and an amplitude adjustment circuit, connected to the output end of the duty cycle correction circuit and configured to adjust an amplitude of the adjusted oscillation signal based on an amplitude control signal, to generate a test signal.

Examples of clock generators with very low duty cycle distortion (DCD) are provided. A clock source and driver generate a main clock signal and a complementary clock signal that are input to a chopper circuit, which also receives complementary chopper control signals from a non-overlapping generator circuit. The chopper circuit is controlled to pass the main clock signal as a first output signal when the chopper circuit is in a first state, and pass the complementary clock signal as a second output signal when the chopper circuit is in a third state. In a second state, which occurs during each of the falling edges of the main clock signal, the chopper circuit holds the previous state, and does not transmit the falling edges of the main clock signal. The rising edges of the main clock signal is used to derive the rising and falling edges of the output signals.

One embodiment of a duty-cycle corrector phase shift (DCCPS) circuit includes a voltage-controlled delay line circuit, a duty-cycle correct circuit, an error amplifier circuit, and DC sampler circuits. Another embodiment of a duty-cycle corrector phase shift circuit includes a digital-controlled delay line circuit, a duty-cycle correct circuit, DC sampler circuits, a comparator circuit, a counter circuit, a control circuit, and a lock detector circuit. In some instances, the DCCPS circuit provides a clock signal with a duty-cycle of approximately fifty percent (50%) and a given phase shift between an input clock signal and the output clock signal.

A duty cycle correction circuit comprises a buffer stage which outputs a digital output signal having a duty cycle. At least one buffer of the buffer stage is configured to exhibit a controllable tripping threshold. A control loop circuit comprises a sensing circuit including a switched capacitor that is reset to a reference potential and time-integrates the digital output signal. A comparator is configured to compare the potential at a terminal of the capacitor with the reference potential. A register stores a correction value determined by the comparator to adjust the tripping threshold of the at least one buffer.