A Low-Power Multichannel Time-to-Digital Converter Using All-Digital Nested Delay-Locked Loops With 50-ps Resolution and High Throughput for LiDAR Sensors

Abstract

This article presents a low-power, all-digital multichannel time-to-digital converter (TDC) for light detection and ranging (LiDAR) sensors. The proposed TDC architecture measures the time interval through a coarse counter, middle, and fine delay line-based interpolation technique (the Nutt method). Automatic calibration by middle and fine all-digital delay-locked loops (ADDLLs) is provided to ensure the stability of the generated time slots. Charge pump, loop filter, and voltage-controlled delay line inside the conventional analog delay-locked loops (DLLs) are replaced by an accumulator (ACC) and digitally controlled delay line (DCDL). This makes the design particularly compact, low power, and suitable for multichannel applications. The presented architecture can generate information for amplitude variation (walk error) compensation. This information is generated by measuring the pulsewidth and position of three successive STOP pulses inside each channel within a single-shot measurement. A low-jitter injection-locked frequency multiplier (ILFM) generates a 625-MHz internal clock signal out of 25-MHz external reference oscillator, which shrinks the number of delay elements to cover one period of the reference clock and improves the precision of the TDC. Operation at higher frequency provides high throughput and short conversion time (less than 3 ns). The three-level TDC offers 13.1- $\mu \text{s}$ maximum input range and 50-ps resolution. The measured DNL and INL of the TDC circuit are 0.47 and 0.71 LSB, respectively. The TDC circuit is implemented in a 180-nm standard CMOS process with a die size of 1.5 mm $\times1.5$ mm. The total power consumption of the multichannel TDC is 87.6 mW.