Abstract: An inductor and method of operating the inductor by combining primary and secondary coils with passive coupling, active parallel, or active cross-coupling structures. The first includes at least one passive coupling structure having at least one coupling coil arranged between a primary coil and at least one of the secondary coils and/or between two of the secondary coils. The second includes an active coupling structure arranged between a primary coil and at least one secondary coil and/or between at least two of the secondary coils, to selectively parallel couple the primary coil and one of the secondary coils and/or at least two of the secondary coils. The third includes an active coupling structure to selectively cross couple a primary coil and at least one of the secondary coils and/or to selectively cross couple at least two of the secondary coils.

Abstract: A continuously tunable inductor with an inductive-capacitive (LC) voltage controlled oscillator (VCO) having a primary coil. The inductor includes a separate isolated secondary coil, a set of transistors composing a closed loop with the secondary coil, a magnetic coupling between the primary coil of the LC VCO and the secondary coil, an electrical coupling between the LC VCO and the set of transistors composing a closed loop with the secondary coil, and means for electric current injection into the closed loop. Such an inductor can be tuned by modulating a mutual inductance, which is magnetically and electrically coupled with the LC VCO by injection of an electric current (I0).

Abstract: An inductor including a primary coil coaxially arranged and operated in parallel with isolated secondary coils each including at least one loop winding with two open-circuited ports. At least one phase shifting device is arranged between open-circuited ports of at least one secondary coil. A method to operate an inductor by combining primary and secondary coils with phase shifting devices to get a wide tuning range is also provided. The method includes the step of phase shifting open-circuited ports of at least one secondary coil.

Abstract: A current mode logic (CML) delay cell with linear rail-to-rail tuning range and constant output swing. The CML delay cell can include a tuning voltage input on a first and second transistor, contributing to a CML delay cell load, and a bias voltage input on a third transistor, as a current source I0, and a compensation circuit having switching point optimized inverters having a first plurality of transistors having a transconductance ?pN and a second plurality of transistors having a transconductance ?nN, wherein respective ratios of ?nN/?pN determine an inverter switching point of respective switching point optimized inverters, the first and second plurality of transistors having gates coupled to the tuning voltage input of the CML delay cell, wherein the switching point optimized inverters are followed by weighted tail current sources M0N that supply additional currents to the current source I0 at a drain node of the third transistor.

Abstract: Apparatuses and methods comprise a phase shifter, an adjustable capacitance configured to adjust a phase shift of said phase shifter, an arbitrary waveform generator configured to adjust the adjustable capacitance, and a pulse pattern generator coupled to the phase shifter, the phase shifter is configured to control the pulse pattern generator. In one aspect, an adjustable capacitance is at least one varactor diode. In another, a pair of varactor diodes are separated by ?/4 lines, an input and an output of the adjustable capacitance is AC-coupled, and the arbitrary waveform generator is configured to adjust the adjustable capacitance through a gaussian noise signal input to the pair of varactor diodes. A deterministic jitter generator may be coupled to the pulse pattern generator. An open-circuited stub line may be input to the pattern generator, a deterministic jitter content number adjustable varying stub line length.

Abstract: A phase-locked-loop (PLL) circuit, that includes: a differential phase-frequency detector, a charge pump and at least one logical gate disposed therebetween for providing cancellation of pulses of a substantially equivalent value output by the detector to the charge pump; wherein the at least one logical gate receives the detector output signals and generates control signals for the charge pump such that the pulses of substantially equivalent value are eliminated.

Abstract: A shifter circuit includes a pair of feed forward sections and a pair of feedback sections. The sections are arranged and coupled to form a balanced symmetrical topology. The feed forward sections each include inverter pairs of PMOS and NMOS devices. The feedback sections each include a pair of cross-coupled devices. A pair of output nodes are operatively positioned between the pair of feedback sections. A method for using the circuit to generate output signals at respective output ports is also disclosed.

Abstract: A method and apparatus for varactor bank switching for a voltage controlled oscillator is disclosed. Varactor bank switching involves generating a negative bias voltage signal as a control signal for a varactor bank switch in an off-state, the varactor bank switch comprising a pass-gate circuit including switching transistors. Generating the negative bias voltage signal includes employing an active rectifier circuit running at the speed of an oscillation signal, the negative bias voltage signal maintaining the gate-source voltage of the pass-gate circuit below a threshold voltage to prevent said switching transistors from becoming conductive in an off-state.

Abstract: A phase locked loop (PLL) which includes a phase frequency detector coupled with a time to digital converter capable of comparing a reference signal with an oscillator signal and generating a digital value representing the phase difference between the reference signal and the oscillator signal. The PLL further includes a state machine for phase acquisition that is capable of generating a control value depending on the digital value, and a controllable oscillator that is capable of generating the oscillator signal depending on the control value.

Abstract: A current mode logic (CML) delay cell with linear rail-to-rail tuning range and constant output swing. The CML delay cell can include a tuning voltage input on a first and second transistor, contributing to a CML delay cell load, and a bias voltage input on a third transistor, as a current source I0, and a compensation circuit having switching point optimized inverters having a first plurality of transistors having a transconductance ?pN and a second plurality of transistors having a transconductance ?nN, wherein respective ratios of ?nN/?pN determine an inverter switching point of respective switching point optimized inverters, the first and second plurality of transistors having gates coupled to the tuning voltage input of the CML delay cell, wherein the switching point optimized inverters are followed by weighted tail current sources M0N that supply additional currents to the current source I0 at a drain node of the third transistor.

Abstract: A signal generator device for generating at least one periodic signal for use in a data eye scan system. The signal generator comprises a clock input, at least one output and at least one signal generator coupled with the clock input and with the output. The signal generator is at least one token ring with a predetermined number of positions and is operable to propagate at least one token in the ring by moving the token from its current position to a following position dependent on a clock signal from the clock input. The signal generator further comprises a predetermined number of signal value units that each represent a respective predetermined signal value of a predetermined signal waveform and are operable to provide the signal value at an output of the signal generator dependent on a current position of the at least one token in the token ring.

Abstract: A current mode logic (CML) delay cell with linear rail-to-rail tuning range and constant output swing. The CML delay cell can include a tuning voltage input on a first and second transistor, contributing to a CML delay cell load, and a bias voltage input on a third transistor, as a current source I0, and a compensation circuit having switching point optimized inverters having a first plurality of transistors having a transconductance ?pN and a second plurality of transistors having a transconductance ?nN, wherein respective ratios of ?nN/?pN determine an inverter switching point of respective switching point optimized inverters, the first and second plurality of transistors having gates coupled to the tuning voltage input of the CML delay cell, wherein the switching point optimized inverters are followed by weighted tail current sources M0N that supply additional currents to the current source I0 at a drain node of the third transistor.

Abstract: A phase locked loop (PLL) which includes a phase frequency detector coupled with a time to digital converter capable of comparing a reference signal with an oscillator signal and generating a digital value representing the phase difference between the reference signal and the oscillator signal. The PLL further includes a state machine for phase acquisition that is capable of generating a control value depending on the digital value, and a controllable oscillator that is capable of generating the oscillator signal depending on the control value.

Abstract: Apparatuses and methods comprise a phase shifter, an adjustable capacitance configured to adjust a phase shift of said phase shifter, an arbitrary waveform generator configured to adjust the adjustable capacitance, and a pulse pattern generator coupled to the phase shifter, the phase shifter is configured to control the pulse pattern generator. In one aspect, an adjustable capacitance is at least one varactor diode. In another, a pair of varactor diodes are separated by ?/4 lines, an input and an output of the adjustable capacitance is AC-coupled, and the arbitrary waveform generator is configured to adjust the adjustable capacitance through a gaussian noise signal input to the pair of varactor diodes. A deterministic jitter generator may be coupled to the pulse pattern generator. An open-circuited stub line may be input to the pattern generator, a deterministic jitter content number adjustable varying stub line length.

Abstract: A current mode logic (CML) delay cell with linear rail-to-rail tuning range and constant output swing. The CML delay cell can include a tuning voltage input on a first and second transistor, contributing to a CML delay cell load, and a bias voltage input on a third transistor, as a current source I0, and a compensation circuit having switching point optimized inverters having a first plurality of transistors having a transconductance ?pN and a second plurality of transistors having a transconductance ?nN, wherein respective ratios of ?nN/?pN determine an inverter switching point of respective switching point optimized inverters, the first and second plurality of transistors having gates coupled to the tuning voltage input of the CML delay cell, wherein the switching point optimized inverters are followed by weighted tail current sources M0N that supply additional currents to the current source I0 at a drain node of the third transistor.

Abstract: A method for dividing a plurality of multiphase signals comprising performing resetable divider stages to the plurality of multiphase signals forming a plurality of divided multiphase signals having a monotonic increasing phase with equal spacing and an ideal duty cycle of 50% through a plurality of resetable dividers, wherein the plurality of divided multiphase signals have no phase ambiguity; and producing a plurality of periodic reset signals to the plurality of resetable dividers to enable the plurality of resetable dividers to divide the plurality of multiphase signals in a timely correct sequence to form the divided multiphase signal through a reset signal generator, the plurality of periodic reset signals being produced by a combinational network of the reset signal generator, the combination network is configured for generating a number of pulses based on the plurality of multiphase signals and performing a plurality of decimation stages and wherein the periodic reset signals are generated solely in r

Abstract: A high speed, low jitter phase locked loop (PLL) with feed forward phase frequency detection is disclosed. The phase frequency detector can include a phase difference sensor providing an output signal indicating a phase difference duration between a rising edge of a reference signal and a rising edge of a feedback signal. The apparatus can also include a lead lag sensor to provide an out put signal indicating when the reference signal leads the feedback signal. In addition, a steering logic module can be coupled to the output of the phase difference sensor and the lead lag sensor and the steering logic module can steer the phase difference duration signal to a first output when the reference signal leads the feedback signal, and can steer the phase difference signal to a second output when the reference signal lags the feedback signal.

Abstract: A multi-Gigahertz, low jitter phase locked loop (PLL) with adjustable gain is disclosed. In one embodiment, properties of a fVCO signal of a PLL can be acquired. Properties can include the occurrences of different types of jitter on the fVCO signal and the lock status of the PLL. A gain control module can control at least a portion of the PLL based on an analysis of the acquired properties. For example, when the loop is locked or when there is loop filter leakage, the gain of a charge pump in the PLL can be reduced. When a charge pump mismatch is detected based on the acquired properties, additional control signals can be provided to the charge pump to correct the mismatch.

Abstract: A multiphase divider includes a plurality of resetable dividers configured for performing resetable divider stages to a plurality of multiphase signals forming a plurality of divided multiphase signals having a monotonic increasing phase with equal spacing and an ideal duty cycle of 50%, wherein the plurality of divided multiphase signals have no phase ambiguity; and a reset signal generator configured for producing a plurality of periodic reset signals to the plurality of resetable dividers to enable the plurality of resetable dividers to divide the plurality of multiphase signals in a timely correct sequence to form the divided multiphase signal, the plurality of periodic reset signals being produced by a combinational network of the reset signal generator, the combinational network is configured for generating a number of pulses based on the plurality of multiphase signals and performing decimation stages to reduce the number of pulses within the pulse traces.

Abstract: The method for determining jitter of a signal in a serial link according to the invention comprising the following steps: First, a section of the signal transmitted via a transmission channel is sampled at different sampling times. The total number of edges in the section is determined. The neighboring sample values are analyzed and from that a statistical value is formed. From the statistical value and the total number of edges a figure of merit is determined. Finally, by means of a look-up table or a jitter-versus-figure of merit curve, the total jitter corresponding to the figure of merit is derived.