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.

An unnecessary circuit operation in a clock enabler circuit accompanying toggling of a clock signal is suppressed. A state holding unit performs a holding operation of a state as to whether or not to output an output clock signal according to an internal clock signal. A clock signal output unit controls output of the output clock signal according to the state held in the state holding unit. A control unit supplies, to the state holding unit, the internal clock signal and a value of the state that are necessary for the holding operation in the state holding unit on a basis of a clock signal and a clock enable signal from an outside.

An apparatus for in-phase and quadrature phase (“IQ”) generation comprises a CMOS clock distributor for providing a clock input. A first IQ divider circuit is configured for receiving the clock input and dividing the clock input into in-phase and quadrature phase (IQ) output. A clock processing circuit is configured for processing the clock input. A second IQ divider circuit is configured for receiving the processed clock input and dividing the processed clock input into in-phase and quadrature phase (IQ) output. A multiplexer circuit is coupled to the first IQ divider circuit and the second IQ divider circuit for selecting the IQ output from the first IQ divider circuit or the second IQ divider circuit.

A quadrature clock generator that takes advantage of the inherently low delay of a shunt-series inductively peaked clock buffer to generate quadrature clocks with the high jitter performance using just one additional stage in Q path compared to I path. The generator includes a delay cell that uses shunt-series peaking and uses a resistive DAC in series with the shunt inductor to provide a large delay range with good jitter characteristics. The resistive DAC can be placed near a real or a virtual ground to minimize capacitive loading on the signal path. This delay cell can provide greater than 2× delay tuning range and is suitable for clocks at high frequencies. This delay cell can also be used as a ring oscillator with large frequency tuning range. A low voltage differential signaling termination switch control that uses feed forward mechanism to control termination impedance of device in a receiver.

An apparatus for in-phase and quadrature phase (“IQ”) generation comprises a CMOS clock distributor for providing a clock input. A first IQ divider circuit is configured for receiving the clock input and dividing the clock input into in-phase and quadrature phase (IQ) output. A clock processing circuit is configured for processing the clock input. A second IQ divider circuit is configured for receiving the processed clock input and dividing the processed clock input into in-phase and quadrature phase (IQ) output. A multiplexer circuit is coupled to the first IQ divider circuit and the second IQ divider circuit for selecting the IQ output from the first IQ divider circuit or the second IQ divider circuit.

A repeater circuit includes at least a first input, and output, and a repeater. The first input for receiving a single-ended data signal from an embedded universal serial bus (eUSB) host. The output provides a differential data signal in a differential universal serial bus (USB) format. The repeater is coupled between the first input and output for converting the single-ended data signal to a differential data signal, the repeater includes an adaptive delay element operable for both sides of the differential data signal to delay one, but not both, of a rising edge and a falling edge of the differential data signal in order to meet a crossover specification for the USB format.

A frequency multiplier system includes a first frequency multiplier circuit to generate a first signal having a first frequency. The first frequency multiplier circuit includes a first post-divider circuit to divide the first frequency of the first signal to a first output frequency within a bounded first range of frequencies, and a first programmable frequency transition controller to control a transitioning frequency relationship between the first signal having the first frequency and a target signal having a desired target frequency. The system includes a second frequency multiplier circuit to generate a second signal having a second frequency. The second frequency multiplier circuit includes a second post-divider circuit configured to divide the second frequency of the second signal to a second output frequency within a bounded second range of frequencies, and a second programmable frequency transition controller to control a transitioning frequency relationship between the second signal having the second frequency and the target signal having the desired target frequency. A multi-transition controller is coupled to both the first frequency multiplier circuit and the second frequency multiplier circuit to, upon a desired change from the first output frequency to the target output frequency, select one of the first output frequency or the second output frequency as a system output frequency.

Circuitry and methods of operating the same to delay a signal by a precise and variable amount. One embodiment is directed to a high speed delay line used in automated test equipment. The inventors have recognized and appreciated that an input signal having high data rate may be split into parallel split signals having lower data rates that are delayed in respective parallel delay paths before being combined to generate a delayed signal. One advantage of delaying a signal in such a fashion is to provide high delay line timing accuracy at high data speeds, while using a compact circuit design using circuitry components of lower bandwidth with reduced power consumption, for example by using complementary metal-oxide-semiconductor (CMOS). A further advantage is that a high speed delay line may be constructed from multiple lower data rate parallel delay lines that are modular, simplifying circuit design.

Certain aspects of the present disclosure provide a local oscillator (LO) for wireless communication. In some examples, the LO is configured to generate an LO signal by inverting, by a first inverter, a first signal to generate a second signal having a first frequency, the first signal being an oscillating signal. In some examples, the LO is configured to control, using a third signal having a second frequency, a first switch receiving the second signal. In some examples, the LO is configured to control, using a fourth signal having the second frequency, a second switch receiving the second signal, wherein the fourth signal is a complement of the third signal and wherein the second frequency is one-half the first frequency.

A signal generator and a method which provides a source signal with a coherent phase at arbitrary times is presented. There is provided a signal generator for generating a source signal based on a reference signal. The signal generator has a phase setting circuit with a memory circuit operable between a plurality of states. The memory circuit has a phase setting input adapted to receive a phase setting value to set the memory circuit to a known state. The signal generator is adapted to load the phase setting value at a specific time to control a phase of the source signal.