Abstract: Embodiments of the present invention provide for a core stage in an application-specific integrated circuit core which drives both a clock pulse signal and a clock pulse negative/complement signal concurrently, thereby resulting in perfectly aligned signals. The core stage can include a pulse generator, a clock distribution circuit, and a set of latches.

Abstract: Embodiments of the present invention provide for a core stage in an application-specific integrated circuit core which drives both a clock pulse signal and a clock pulse negative/complement signal concurrently, thereby resulting in perfectly aligned signals. The core stage can include a pulse generator, a clock distribution circuit, and a set of latches.

Abstract: Some embodiments provide a voltage-level shifter circuit comprising a cross-coupled transistor pull-up network that includes a plurality of diode-connected transistors configured to cause the state of the cross-coupled transistor network to switch at a low current through a pull-down network coupled thereto, such as a current corresponding to near-threshold voltage or sub-threshold voltage operation of the pull-down network.

Abstract: Some embodiments provide a voltage-level shifter circuit comprising a cross-coupled transistor pull-up network that includes a plurality of diode-connected transistors configured to cause the state of the cross-coupled transistor network to switch at a low current through a pull-down network coupled thereto, such as a current corresponding to near-threshold voltage or sub-threshold voltage operation of the pull-down network.

Abstract: An inductance enhanced rotary traveling wave oscillator is disclosed. Portions of the transmission line conductors are increased in length and run in parallel. Because the currents in these portions travel in the same direction, the inductance of these inductors is increased. By controlling the length of the transmission line conductors in these areas compared to the lengths in which the currents travel in opposite directions, the overall impedance of the oscillator can be increased. Increased impedance leads to lower power, higher Q, and lower phase noise for the oscillator. Additionally, the folded nature of the transmission line conductors permits a longer length of transmission line conductors to be routed in a smaller area. The folded nature also permits placement of the devices to take into account their switching delays. A folded circular version of the oscillator is possible, leading to improved access to phase taps on the oscillator.

Abstract: An inductance enhanced rotary traveling wave oscillator is disclosed. Portions of the transmission line conductors are increased in length and run in parallel. Because the currents in these portions travel in the same direction, the inductance of these inductors is increased. By controlling the length of the transmission line conductors in these areas compared to the lengths in which the currents travel in opposite directions, the overall impedance of the oscillator can be increased. Increased impedance leads to lower power, higher Q, and lower phase noise for the oscillator. Additionally, the folded nature of the transmission line conductors permits a longer length of transmission line conductors to be routed in a smaller area. The folded nature also permits placement of the devices to take into account their switching delays. A folded circular version of the oscillator is possible, leading to improved access to phase taps on the oscillator.