Abstract: To detect whether a closed-loop's voltage is out of range, a voltage detector includes first and second transistors that deliver first and second currents respectively to first and second high impedance nodes. The voltage detector further includes third and fourth transistors that draw third and fourth currents respectively from the first and second nodes. The first and second currents are scaled replicas of a current flowing through a current source of a voltage-to-current converter that converts the close-loop's voltage to a current and supplies a first voltage to the first and second transistors. The third and fourth currents are scaled replicas of a different current flowing through a current mirror of the voltage-to-current converter and that supplies a second voltage to the third and fourth transistors.

Abstract: A differential output driver includes an output block, a replication block, and a feedback control block. Each of the output and replication blocks further includes a preamplifier and a source-follower stage. The preamplifier of the output block receives a differential input voltage and generates a first differential voltage. The source-follower stage of the output block receives the first differential voltage and generates a differential output voltage. The preamplifier of the replication block receives first and second supply voltages and generates a second differential voltage. The source-follower stage of the output block receives the second differential voltage and generates a third differential voltage. The feedback control block receives the third differential voltage and generates a differential control voltage applied to the output block. The generated differential output voltage stays within predefined limits, such as those defined by the LvPECL standard.

Abstract: A duty cycle control circuit that consumes lower power and smaller silicon area, and is less susceptible to noise or jitter. In one embodiment, the invention includes a divide-by-two circuit that is edge triggered and generates a signal at its output with half the frequency of the input signal but with a 50% duty cycle. The divide-by-two circuit is followed by a frequency restore circuit that restores the original frequency of the input signal but with its duty cycle regulated at about 50%, or any other desired level.

Abstract: The present invention is directed to providing a phase detector capable of establishing phase-locked-loop operation in a highly accurate and reliable manner. For example, exemplary embodiments detect a phase difference between at least two input signals to phase lock the input signals to one another. Exemplary embodiments include two phase detectors each of which receives the two input signals (e.g., three-state phase detectors), and each of which is forced to operate outside of its dead-band region by introducing predetermined phase delays for its inputs. Each of the two phase detectors detects a phase difference between its respective inputs. The two phase differences are then combined to produce a composite output signal formed as a net charge proportional to the net phase difference detected by the two phase detectors.

Abstract: A power supply self adjusted circuit that can sense a power supply voltage and detect whether the power supply is of a first value (e.g., 5V) or a second value (e.g., 3.3 V). In the case of a modem system, the power supply self adjusted circuit then adjusts the modem system accordingly. Hence, using this circuit, a modem or other signal processing circuit can be designed to work for both 5V and 3.3V power supply systems, for example. Futhermore, the power supply self adjusted circuit enables a modem system to automatically adjust itself when the power supply is switched from 5V to 3.3V or vice versa, without any manual intervention from the user. This capability is important for increasingly-popular PC Card- modems.

Abstract: A pro-capture circuit for a phase locked loop detects when the phase locked loop is operating outside of its operating range, and then forces the phase locked loop back into the proper range. The principle of detection is general and may be adapted to work in distinct phase locked loop designs. More particularly, the pro-capture circuit is used in a phase locked loop having a normal operating range in which an output signal of the phase locked loop varies between a minimum normal value and a maximum normal value. The pro-capture circuit includes circuitry for sensing when the output signal is outside the normal operating range and circuitry for forcing the output signal to reenter the normal operating range.

Abstract: A virtual sensing system includes a sensing network that is external to a standard cell for sensing a reference current in the standard cell and for generating a scaled current without breaking the reference current path and without inserting any sensing device in series with the reference current. The reference current can be used, for example, for duplication and/or scaling.