A system for reducing clock jitter may include first jitter reducing circuitry. The first jitter reducing circuitry may be arranged between an input clock signal node carrying an input clock signal and an output clock signal node carrying an output clock signal. The first jitter reducing circuitry may include a first intermediate input clock signal node and a first intermediate output clock signal node. The first jitter reducing circuitry may include a first clock delay circuit, which may be configured to: (1) delay a first intermediate input clock signal received on the first intermediate input clock signal node by an odd integer multiple of one half of a period, and (2) invert the first intermediate input clock signal. The first jitter reducing circuitry may also include a first connection, which may be from the first intermediate output clock signal node to the first intermediate input clock signal node.

An apparatus is provided which comprises: an oscillator circuit to generate a clock signal and transmit the clock signal over a signal line; a ground reference plane associated with the signal line; and one or more patterns formed in the ground reference plane, wherein the one or more patterns in the ground reference plane is to filter out noise from the clock signal transmitted over the signal line.

An oscillation signal generation circuit includes an oscillator and a calibration circuit. The oscillator includes a reference signal source circuit that has a reference signal source outputting a reference signal and converts the output reference signal into a control voltage, a filter that includes a variable resistance and a capacitance and removes noise in the control voltage, a transistor that converts the control voltage which has passed through the filter into a control current and outputs the control current, a core circuit that is driven by the control current and generates an output signal, and an output terminal that outputs the generated output signal. The calibration circuit is connected to the output terminal of the oscillator, detects whether or not the generated output signal is oscillating, and adjusts the current value of the control current by controlling the resistance value of the variable resistance in accordance with the detection result.

Differing from conventional oscillator circuit does not include temperature compensation function, the present invention particularly constitutes a gain stage, a current mirror unit, a clamping current supplying unit, a noise inhibiting unit, a compensation unit, and a reference signal generating unit to a novel oscillator circuit having temperature compensation function. A variety of experimental data have proved that, based on the normal operation of the compensation unit and the reference signal generating unit, the oscillator frequency of the oscillator circuit of the present invention almost be kept at same level even if the ambient temperature continuously increases. Therefore, because the frequency drift due to temperature variation would not occur in the oscillator circuit of the present invention, the novel oscillator circuit is potential oscillator to replace the conventional oscillators applied in analog-to-digital convertors or time-to-digital convertors.

An apparatus is provided which comprises: a crystal having an input and an output; a first interconnect line having first and second ends, wherein the first end is coupled to the input; a second interconnect line having first and second ends, wherein the first end is coupled to the output; a first capacitor coupled to the input and ground; and a second capacitor coupled to the second end of the second interconnect line. An apparatus is provided which comprises: a high pass filter; a pair of AC coupling capacitors coupled to the high pass filter; a low pass filter coupled to the pair of AC coupling capacitors; and an analog to digital converter (ADC) coupled to the low pass filter.

Techniques pertaining to designs of integrated circuits having on-chip inductors with low common mode coupling effect are described. According to one aspect of the present invention, an integrated circuit is designed to have a first circuit operating at a first frequency and including a first inductor, and a second circuit including a second inductor and provided to process an input signal. The second circuit includes a second inductor and is provided to process an input signal. The second inductor includes a first terminal, a second terminal, an intermediate terminal, and an intermediate node, wherein a first wire is formed between the first terminal and the intermediate node, a second wire is formed between the intermediate node and the second terminal, and an intermediate tap is coupled between the intermediate node and the intermediate terminal, the first wire and the second wire forming a coil with one or more turns, and the first terminal, the second terminal and the intermediate terminal of the second inductor being located on one side of the coil and adjacent to each other.

A detector includes a frequency multiplier and a transceiving node. The frequency multiplier includes a first terminal, a second terminal and an output terminal. The first terminal is used to receive a first injection signal having a first frequency. The output terminal is used to output an output signal. The second terminal is used to receive a second injection signal having a second frequency. The frequency multiplier is used to output the output signal at a frequency substantially equal to a multiple of the first frequency by injection locking and pull the output signal to the second frequency by injection pulling. The transceiving node is coupled to the output terminal and the second terminal of the frequency multiplier. The transceiving node is used to transmit the output signal, and receive a received signal having a third frequency. The received signal is used to update the second injection signal.

A voltage setting circuit includes a frequency comparator that compares the oscillation frequencies of a first distributed voltage-controlled oscillator and a second distributed voltage-controlled oscillator and a frequency determination circuit that determines the levels of the oscillation frequencies of the first distributed voltage-controlled oscillator and the second distributed voltage-controlled oscillator. The bias to be supplied to the first distributed voltage-controlled oscillator and the bias to be supplied to the second distributed voltage-controlled oscillator are determined in accordance with a result of the determination. The bias at a time when the levels of the oscillation frequencies are reversed is determined to be the optimum bias, and the optimum bias is supplied to the core circuit.

A circuit device includes an A/D conversion unit, a processing unit that performs a temperature compensation process of an oscillation frequency based on temperature detection data and outputs frequency control data of the oscillation frequency, a D/A conversion unit, and an oscillation circuit. The D/A conversion unit (area DAC) is disposed on a first direction DR1 side of the A/D conversion unit (area ADC). When a direction crossing the first direction DR1 is defined as a second direction DR2, the processing unit (area DSPL) is disposed on the second direction DR2 side of the A/D conversion unit and the D/A conversion unit. When a direction opposite to the second direction DR2 is defined as a third direction DR3, the oscillation circuit (area OSC) is disposed on the third direction DR3 side or the first direction DR1 side of the D/A conversion unit.

One embodiment described is an apparatus that includes an active device structured in a semiconductor body. The semiconductor body may include a gate terminal to receive a switched bias signal, and a bulk terminal to receive a forward body-bias signal. A first circuit portion may be coupled to the gate terminal to provide the switched bias signal, and a second circuit portion may be coupled to the bulk terminal to provide the forward body-bias signal.