A novel architecture to implement quadrature voltage-controlled oscillators (QVCOs), based on the coupled phase-locked loop (CPLL) technique, is presented. The proposed solution allows to overcome the trade-off between low phase noise and small quadrature error, typical of conventional QVCOs. Both figure-of-merit (FoM) can then be optimized simultaneously. Within the CPLL bandwidth, the QVCO phase noise is even improved by 3 dB with respect to the phase noise of the stan-dalone free-running oscillators in the loop. Prototypes realized in a 28 nm bulk CMOS technology operate from 24 to 29.2 GHz (a 20% tuning range) and show a -134 dBc/Hz phase noise at 10 MHz offset from the 24 GHz carrier. The measured average quadrature error across the tuning range is 0.9?. The QVCO dissipates 60 mW; its FoM is -184 dBc/Hz. The QVCO core area amounts to 0.2 mm(2).
Analysis and Design of Coupled PLL-Based CMOS VCOs
Iesurum, A;Bevilacqua, A
2024
Abstract
A novel architecture to implement quadrature voltage-controlled oscillators (QVCOs), based on the coupled phase-locked loop (CPLL) technique, is presented. The proposed solution allows to overcome the trade-off between low phase noise and small quadrature error, typical of conventional QVCOs. Both figure-of-merit (FoM) can then be optimized simultaneously. Within the CPLL bandwidth, the QVCO phase noise is even improved by 3 dB with respect to the phase noise of the stan-dalone free-running oscillators in the loop. Prototypes realized in a 28 nm bulk CMOS technology operate from 24 to 29.2 GHz (a 20% tuning range) and show a -134 dBc/Hz phase noise at 10 MHz offset from the 24 GHz carrier. The measured average quadrature error across the tuning range is 0.9?. The QVCO dissipates 60 mW; its FoM is -184 dBc/Hz. The QVCO core area amounts to 0.2 mm(2).Pubblicazioni consigliate
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