A 32.768kHz-reference (REF) phase-locked loop (PLL) can help eliminate the high-frequency crystal oscillator in a wireless system-on-chip (SoC), which would significantly reduce the cost and improve power efficiency [1–3]. With the conventional $1{\times}-\text{sampling}$ PLL, the loop bandwidth of the PLL is limited to 1/10 of the REF frequency $(\mathrm{f}_{\text{REF}})$. To break the limitation of the narrow bandwidth and poor jitter caused by low $\mathrm{f}_{\text{REF}}$, the reference-oversampling PLL (OSPLL) was studied [3]. However, different from the high $\mathrm{f}_{\text{REF}}$ [4], [5], the 32kHz-REF PLL severely suffers from jitter transferred from voltage noise (mainly from a comparator) from a slow signal slope, which degrades the total jitter performance. To overcome the above issues, a nonuniform OSPLL is proposed with a 32kHz REF to realize a 2.4GHz output with a fractional-N operation. The proposed DAC-and-DTC-assisted nonuniform OSPLL works with a proposed gain-boosted phase detector (PD) and an adaptive loop-gain calibration. It realizes a 200kHz loop bandwidth, 4.95ps rms jitter with 3.8mW power consumption in a 65nm CMOS technology.