A 200MS/s, 11 bit SAR-assisted pipeline ADC with bias-enhanced ring amplifier

“…In addition, the signal can be rapidly amplified through slew-based charging rather than the RC-based charging used in conventional op-amps, and power consumption is very low. The values of the parameters listed in Table 1 confirm that, using a ring amplifier, a pipeline structure can be advantageous in terms of power and speed without additional circuits [10][11][12][13]. However, even if a ring amplifier is used, if a pipeline-SAR ADC tries to implement even higher resolution, each stage requires further fine quantization, and the comparator design can be an issue.…”

“…An op-amp/operational trans-conductance amplifier (OTA) with a high open-loop gain is used in most pipelined structures because of its tolerance to filter mismatch. Among the various structures available, a gain-boosting, cascode-type op-amp is often used conventionally, as shown in Figure 4a [7,13,22,23]. However, it accounts for most of…”

A Pipelined Noise-Shaping SAR ADC Using Ring Amplifier

“…In addition, the signal can be rapidly amplified through slew-based charging rather than the RC-based charging used in conventional op-amps, and power consumption is very low. The values of the parameters listed in Table 1 confirm that, using a ring amplifier, a pipeline structure can be advantageous in terms of power and speed without additional circuits [10][11][12][13]. However, even if a ring amplifier is used, if a pipeline-SAR ADC tries to implement even higher resolution, each stage requires further fine quantization, and the comparator design can be an issue.…”

“…An op-amp/operational trans-conductance amplifier (OTA) with a high open-loop gain is used in most pipelined structures because of its tolerance to filter mismatch. Among the various structures available, a gain-boosting, cascode-type op-amp is often used conventionally, as shown in Figure 4a [7,13,22,23]. However, it accounts for most of…”

A Pipelined Noise-Shaping SAR ADC Using Ring Amplifier

“…More importantly, ringamps are more suitable for fine CMOS processes and have application scenarios in various types of ADCs due to the versatility of their structures. In the last decade, many ringamp-based ADC works [24,[29][30][31][32][33][34][35][36][37][38][39] have appeared. Essentially, there are two different directions of the application, one for high resolution (signal-to-noise-and-distortion-ratio (SNDR) ≥ 70 dB) and the other for high speed (sampling rate fs ≥ 500 MHz), such as the dual-deadzone RAMP-based two-step SAR ADC [34], which achieves the highest SNDR for a ringampbased high-resolution ADC, while [33] used a dead zone degeneration technique to realize the fastest sampling rate (fs = 1 GHz) for single-channel implementation.…”

“…The self-biased ringamp [30] is replaced by a resistor R DZ inserted in the second stage to separate the signal without additional bias capacitors, enabling the transition of the ringamp from oscillation to amplification, due to the nature of the ringamp, which originates from a ring oscillator. The bias-enhanced ringamp is originally proposed in [31] by inserting a resistor R BE in the first stage and cross-coupling the top and bottom nodes of the resistors to the second stage. Due to the increase in the overdrive voltage of the second stage transistors, bias-enhanced ringamp can achieve larger bandwidth.…”

A 2.5-GS/s Four-Way-Interleaved Ringamp-Based Pipelined-SAR ADC with Digital Background Calibration in 28-nm CMOS

“…In [2], a dynamic dead-zone implemented with a resistor was presented, which was used in [4] to create a fully differential RA. In [5], a second-stage bias-enhanced RA showed improved performance, and in [6], the bias-enhancing technique was used in conjunction with a degenerated deadzone to improve the linearity and bandwidth of the RA.…”

34.3 fJ/conv.-step 8-MHz Bandwidth Fourth-Order Pseudo-Differential Ring-Amplifier-Based Continuous-Time Delta–Sigma ADC in 65 nm