0.3–4.3 GHz Frequency-Accurate Fractional- Frequency Synthesizer With Integrated VCO and Nested Mixed-Radix Digital - Modulator-Based

Abstract

If the modulus of the digital delta-sigma modulator (DΔΣM) in a fractional- frequency synthesizer is a power of two, then the output frequency is constrained to be a rational multiple of the phase detector frequency , where the denominator of the rational multiplier is a power of two. If the required output frequency is not related to in this way, one is forced to approx- imate the ratio by using a small programmable modulus D ΔΣMo r a very large power-of-two modulus. Both of these solutions involve additional hardware. Furthermore, the programmable modulus solution can suffer from spurs, while the large power of two lacks accuracy. This paper presents a new solution, based on mixed- radix algebra, where the required ratio is formed by combining two different moduli. The programmable modulus solves the ac- curacy problem, while the large power-of-two modulus minimizes the spur content. In addition, the phase detector can be clocked at high speed. This paper explains the theoretical foundations of the method, elaborates a design methodology, and presents measured results for an 0.18 µm SiGe BiCMOS prototype.