A 2.4GHz sub-harmonically injection-locked PLL with self-calibrated injection timing

A low-phase-noise integer-N phase-locked loop (PLL) is attractive in many applications, such as clock generation and analog-to-digital conversion. The sub-harmonically injection-locked technique, sub-sampling technique, and the multiplying delay-locked loop (MDLL) can significantly improve the phase noise of an integer-N PLL. In the sub-harmonically injection-locked technique, to inject a low-frequency reference clock into a high-frequency voltage-controlled oscillator (VCO), the injection timing should be tightly controlled. If the injection timing varies due to process variation, it may cause a large reference spur or even cause the PLL to fails to lock. A sub-harmonically injection-locked PLL (SILPLL) adopts a sub-sampling phase-detector (PD) to automatically align the phase between the injection pulse and a VCO. However, a sub-sampling PD has a small capture range and a low bandwidth. The high-frequency non-linear effects of a sub-sampling PD may degrade the accuracy and limit the maximum speed of a VCO. In addition, a frequency-locked loop is needed for a sub-sampling PD. A delay line is manually adjusted to achieve the correct injection timing. However, the delay line is sensitive to process variations. Thus, the injection timing should be calibrated.

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