Abstract
This paper presents a 12-bit 2.4 GS/s analog-to-digital converter (ADC) employing four time-interleaved (TI) pipelined channels with a novel on-chip timing mismatch calibration in 40 nm CMOS process. TI architecture can increase the effective sampling rate of ADC but the dynamic performance of TI-ADC system is seriously degraded by offset, gain, and timing mismatches among the channels. Timing mismatch is the most challenging barrier among these mismatches due to the difficulty and complexity of its detection and correction. An automatic wideband timing mismatch detection algorithm is proposed for achieving a wide frequency range of timing mismatch detection without complex calculations. By adopting the proposed mismatch-free variable delay line (VDL), the full-scale traversal timing mismatch correction accomplishes an accurate result without missing codes. Measurement results show that the spurious free dynamic range (SFDR) of the prototype ADC is improved from 55.2 dB to 72.8 dB after calibration at 2.4 GS/s with a 141 MHz input signal. It can achieve an SFDR above 60 dB across the entire first Nyquist band based on the timing mismatch calibration and retiming technology. The prototype ADC chip occupies an area of 3 mm × 3 mm and it consumes 420 mW from a 1.8 V supply.
Highlights
Driven by the rapid development of the information society, the need for systems such as high-speed digital oscilloscopes, optical communications, future mobile communication systems, and direct sampling receivers is growing fast
It mainly consists of two modules: estimation that is based on difference and correlation (EBDC), and the automatic determination of convergence direction (ADCD)
The analog-to-digital converter (ADC) prototype is manufactured in a 40nm CMOS process
Summary
Driven by the rapid development of the information society, the need for systems such as high-speed digital oscilloscopes, optical communications, future mobile communication systems, and direct sampling receivers is growing fast. Compared to foreground calibration, background calibration is preferred as it doesn’t need the specified input signal and can operate in real time without interrupting the ADC conversion process [7,17]. It can track possible drifts in timing mismatch due to temperature or voltage variations. Compared with using high-speed FIR filters, ADC that is calibrated under this method does not suffer from the high power and large area consumption, and the additional jitter is acceptable relative to the original clock jitter and the overall performance requirements of the system. ADC, with the experimental results in Sections 4 and 5 concludes this work
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