Described is a circuit and architecture that combines phase interpolator (PI) mixer with duty cycle correction (DCC), to prevent cross contention between the tristate inverter pairs of the mixer. The control code for the p-type and n-type networks in the PI mixer are decoupled, and DCC mechanism are blended in the PI mixer code decoding scheme to enable a low latency phase interpolation and duty cycle correction. The circuit comprises a first mixer circuitry controllable by a first code; a second mixer circuitry controllable by a second code; a node coupled to outputs of the first and second mixers; and a keeper circuitry coupled to the node, wherein the first and second mixers are tri-stable mixers.

A method for duty cycle error detection and correction includes receiving, during a read operation performed on a memory cell, a first data strobe signal. The method also includes generating a second data strobe signal by phase delaying the first data strobe signal. The method also includes determining, based on the first data strobe signal and the second data strobe signal, whether a duty cycle corresponding to the first data strobe signal is distorted. The method also includes adjusting a clock signal based on a determination that the duty cycle is distorted.

A clock test system included in a computer system includes a clock generator circuit that generates multiple clock signals. A switch circuit selects different ones of the multiple clock signals during different time periods to generate an output clock signal. A measurement circuit measures a duty cycle of the output clock signals during the different time periods to generate multiple duty cycle measures. The measurement circuit uses the multiple duty cycle measurements to cancel a portion of duty cycle distortion in the output clock signal to determine an adjusted duty cycle value.

Disclosed herein is an apparatus that includes: a first input node supplied with a first clock signal; a first clock path configured to output a delayed first clock signal, the first clock path including first and second delay elements coupled in series; a second clock path configured to output additional delayed first clock signal, the second clock path including third and fourth delay elements coupled in series; a first mixer circuit configured to interpolate the delayed first clock signal and the additional delayed first clock signal to reproduce an adjusted clock signal as the first clock signal; and a control circuit configured to control delay amounts of the first, second, third, and fourth delay elements with first, second, third, and fourth codes different from one another.

An on-vehicle system comprises a Clock Extension Peripheral Interface (CXPI) bus and a device coupled to the CXPI bus as a slave node. The device comprises a transceiver configured to: generate a first signal by delaying an inverted signal of a transmission data signal; generate a second signal based on the transmission data signal, where the second signal has a low slew rate; selectively output the first signal or the second signal as a third signal, in response to a selector signal; and generate a clock signal in response to the third signal, where the clock signal is at a high level when the third signal is at a low level, and where the clock signal is at the low level when the third signal is at the high level.

Apparatuses and methods for setting a duty cycler adjuster for improving clock duty cycle are disclosed. The duty cycle adjuster may be adjusted by different amounts, at least one smaller than another. Determining when to use the smaller adjustment may be based on duty cycle results. A duty cycle monitor may have an offset. A duty cycle code for the duty cycle adjuster may be set to an intermediate value of a duty cycle monitor offset. The duty cycle monitor offset may be determined by identifying duty cycle codes for an upper and for a lower boundary of the duty cycle monitor offset.

A control circuit, a chip and a control method are disclosed. The control circuit includes: an adjustment signal generation unit configured to detect an electrical signal reflecting a power supplied to a load under control of a current value of a reference signal, generate a feedback signal and output an adjustment signal based on both the feedback signal and the reference signal; and a control unit coupled to the adjustment signal generation unit and configured to control the switching circuit on and off based on the adjustment signal. With the generated adjustment signal that reflects a change in an adjustment metric indicated in the reference signal, the control circuit and the driving system can be adapted in real time to the specifications of any AC power standard. Moreover, much more granular adjustments can be made in the power supplied to the load.

An integrated circuit having a transmitter is provided. The transmitter may include a serializer, a driver, and an associated calibration circuit. The calibration circuit may include a detector and a control circuit. The control circuit may output a first control signal for selectively configuring the serializer to inject test data and may also output a second control signal for selectively inverting the input polarity of the detector. The control circuit may configure the transmitter in at least four different modes by adjusting the first and second control signals. In each of the four modes, the control circuit may sweep a clock duty cycle correction (DCC) setting that controls only the serializer until the detector flips. Codes generated in this way may be used to compute calibrated settings that mitigates both clock and data duty cycle distortion for the transmitted data.

In various embodiments, a clock pulse generation circuit may include a combination circuit, a first set-reset (SR) latch, a second SR latch, and a pulse generator. The combination circuit may be configured to generate a set signal based on an external clock signal. The first SR latch may be configured to generate an internal clock signal based on the reset signal and the set signal. The second SR latch may be configured to generate the reset signal based on the external clock signal and a reset pulse signal. The pulse generator may be configured to generate the reset pulse signal based on the internal clock signal. As a result, the clock pulse generation circuit may be configured to prevent the set signal from being asserted when the reset signal is asserted.

A method and apparatus for dynamically monitoring, measuring, and adjusting a clock duty cycle of an operating storage device is disclosed. A storage device includes a measuring circuit comprising a plurality of flip flop registers coupled to a first input line, with each flip flop register having a first input and a second input. One or more delay taps are coupled to each flip flop register, and are disposed on a second input line. While the device operates, a clock signal is input directly into the first input of each flip flop register via the first input line. Simultaneously, the clock signal is input into the second input of each flip flop register through the one or more delay taps via the second input line. The flip flop registers are then read to determine the clock duty cycle of the device, and the clock frequency is adjusted as needed.