Voltage-controlled oscillator

About: Voltage-controlled oscillator is a research topic. Over the lifetime, 23896 publications have been published within this topic receiving 231875 citations. The topic is also known as: VCO.

A 6.3-9-GHz CMOS fast settling PLL for MB-OFDM UWB applications

Abstract: A CMOS phase-locked loop (PLL) which synthesizes frequencies between 6.336 and 8.976 GHz in steps of 528 MHz and settles in approximately 150 ns is presented. The proposed PLL can be employed as a building block for a frequency synthesizer which generates a seven-band hopping carrier for multiband orthogonal frequency division multiplexing (MB-OFDM) ultrawideband (UWB) radio. To achieve fast loop settling, integer-N architecture that operates with 528-MHz reference frequency is implemented and a wideband active-loop filter is integrated. An improved phase-frequency detector (PFD) is proposed for faster loop settling. To reduce reference sidebands, a feedback circuit using replica bias is implemented in the charge pump. I/Q carriers are generated by two cross-coupled LC VCOs. The output current of the charge pump is controlled to compensate for the VCO gain nonlinearity and a programmable frequency divider (12/spl les/N/spl les/17) that reliably operates at 9 GHz is designed. Fabricated in 0.18-/spl mu/m CMOS technology, the PLL consumes 32 mA from a 1.8-V supply and achieves phase noise of -109.6dBc/Hz at 1-MHz offset and spurs of -52 dBc.

A Single-Event-Hardened Phase-Locked Loop Fabricated in 130 nm CMOS

Abstract: A radiation-hardened-by-design phase-locked loop (PLL)-designed and fabricated in 130 nm CMOS-is shown to mitigate single-event transients (SETs). Two-photon-absorption (TPA) laser tests were used to characterize the error signatures of the PLL and to perform single-event upset (SEU) mapping of the PLL sub-components. Results show that a custom, voltage-based charge pump reduces the error response of the PLL over conventional designs by more than two orders of magnitude as measured by the number of erroneous PLL clock pulses following a single-event. Additionally, SEU mapping indicates a 99% reduction in the vulnerable area of the radiation-hardened-by-design (RHBD) charge pump over a conventional design. Furthermore, the TPA experiments highlight the importance of the voltage-controlled oscillator in the overall SET response of the PLL implementing the RHBD charge pump.

Single chip RF tag oscillator circuit synchronized by base station modulation frequency

Abstract: A Radio Frequency (RF) transponder (tag), method, and system, whereby the tag has a low current tag oscillator, the oscillation frequency of the tag oscillator set by RF signal from a base station.

64 GHz and 100 GHz VCOs in 90 nm CMOS using optimum pumping method

Abstract: A method to optimally pump energy from the transistors to the passive network is presented for the design of integrated 64 GHz and 100 GHz VCOs in 90 nm CMOS. The VCOs use an on-die distributed network, draw /spl sim/25 mA from a 1 V supply and produce oscillations with 0.4 Vp-p amplitudes. Phase noise is <-110 dBc/Hz at 10 MHz offset, and VCO gain is 2 GHz/V.

Clock recovery circuit

Abstract: A clock recovery circuit that can be used for recovering a clock signal from a data stream having a high data rate. The clock recovery circuit has a phase interpolator and non-linear digital to analog converters. These circuits are used to interpolate between the phases produced by a voltage controlled oscillator. A determination to advance or hinder a currently selected phase can be made using an up/down detector, a divider, and control logic. The divider can divide not only the up and down pulses produced by the up/down detector, but also the clock frequency. By dividing the clock frequency, the control logic can be designed using CMOS logic circuits.