A Four-stage Power and Area Efficient OTA with 30 × (400pf – 12nf) Capacitive Load Drive Range

Multistage operational transconductance amplifier (OTA) has been a major research focus as a solution to high DC Gain high Gain Bandwidth and wide voltage swing requirement on sub-micron devices. These system requirements, in addition to ultra-large capacitive load drivability (nF-range load capacitor), are useful in applications including LCD drivers, low dropout (LDO) linear regulators, headphone drivers, etc. The major drawback of multistage OTAs is the stability concerns since each added stage introduces low frequency poles. Numerous compensation schemes for three stage OTAs have been proposed in the past decade with only a few four stage OTA in literature. The proposed design is a four stage OTA which uses an active zero block (AZB) to provide left half plane (LHP) zero to help with phase degradation. AZB is embedded in the second stage ensuring reuse of existing block hence providing area and power savings. This design also uses single miller capacitor in the outer loop which ensures improved speed performance with minimal area overhead. A very reliable slew helper is implemented in this design to help with the large signal performance. The slew helper is only operational in the events slewing and does not affect the small signal performance. The proposed design achieves a DC gain of 114 dB, GBW > 1.77MHz and PM > 46.9⁰ for capacitive load ranging from 400pF–12nF (30x) which is the highest recorded range in literature for these type of compensation. It does this by consuming a total power of 143.5µW and an area of 0.007mm^2

Performance enhancement in the desing of amplifier and amplifier-less circuits in modern CMOS technologies.

In the context of nowadays CMOS technology downscaling and the increasing demand of high performance electronics by industry and consumers, analog design has become a major challenge. On the one hand, beyond others, amplifiers have traditionally been a key cell for many analog systems whose overall performance strongly depends on those of the amplifier. Consequently, still today, achieving high performance amplifiers is essential. On the other hand, due to the increasing difficulty in achieving high performance amplifiers in downscaled modern technologies, a different research line that replaces the amplifier by other more easily achievable cells appears: the so called amplifier-less techniques. This thesis explores and contributes to both philosophies. Specifically, a lowvoltage differential input pair is proposed, with which three multistage amplifiers in the state of art are designed, analysed and tested. Moreover, a structure for the implementation of differential switched capacitor circuits, specially suitable for comparator-based circuits, that features lower distortion and less noise than the classical differential structures is proposed, an, as a proof of concept, implemented in a ΔΣ modulator

Strategies for enhancing DC gain and settling performance of amplifiers

The operational amplifier (op amp) is one of the most widely used and important building blocks in analog circuit design. High gain and high speed are two important properties of op amps because they determine the settling behavior of the op amps. As supply voltages decrease, the realization of high gain amplifiers with large Gain-Bandwidth-Products (GBW) has become challenging. The major focus in this dissertation is on the negative output impedance gain enhancement technique. The negative impedance gain enhancement technique offers potential for achieving very high gain and energy-efficient fast settling and is low-voltage compatible. Misconceptions that have limited the practical adoption of this gain enhancement technique are discussed. A new negative conductance gain enhancement technique was proposed. The proposed circuit generates a negative conductance with matching requirements for achieving very high DC gain that are less stringent than those for existing -g m gain enhancement schemes. The proposed circuit has potential for precise digital control of a very large DC gain. A prototype fully differential CMOS operational amplifier was designed and fabricated based on the proposed gain enhancement technique. Experimental results which showed a DC gain of 85dB and an output swing of 876mVp-p validated the fundamental performance characteristics of this technique. In a separate section, a new amplifier architecture with bandpass feedforward compensation is presented. It is shown that a bandpass feedforward path can be used to substantially extend the unity-gain-frequency of an operational amplifier. Simulation results predict significant improvements in rise time and settling performance and show that the bandpass compensation scheme is reasonably robust. In the final section, a new technique for asynchronous data recovery based upon using a delay line in the incoming data path is introduced. The proposed data recovery system is well suited for tight tolerance channels and coding systems supporting standards that limit the maximum number of consecutive 0\u27s and 1\u27s in a data stream. This system does not require clock recovery, suffers no loss of data during acquisition, has a reduced sensitivity to jitter in the incoming data and does not exhibit jitter enhancement associated with VCO tracking in a PLL

Power-Efficient and High-Performance Cicruit Techniques for On-Chip Voltage Regulation and Low-Voltage Filtering

This dissertation focuses on two projects. The first one is a power supply rejection (PSR) enhanced with fast settling time (TS) bulk-driven feedforward (BDFF) capacitor-less (CL) low-dropout (LDO) regulator. The second project is a high bandwidth (BW) power adjustable low-voltage (LV) active-RC 4th -order Butterworth low pass filter (LPF). As technology improves, faster and more accurate LDOs with high PSR are going to be required for future on-chip applications and systems.The proposed BDFF CL-LDO will accomplish an improved PSR without degrading TS. This would be achieved by injecting supply noise through the pass device’s bulk terminal in order to cancel the supply noise at the output. The supply injection will be achieved by creating a feedforward path, which compared to feedback paths, that doesn’t degrade stability and therefore allows for faster dynamic performance. A high gain control loop would be used to maintain a high accuracy and dc performance, such as line/load regulation. The proposed CL-LDO will target a PSR better than – 90 dB at low frequencies and – 60 dB at 1 MHz for 50 mA of load current (IvL). The CL-LDO will target a loop gain higher than 90 dB, leading to an improved line and load regulation, and unity-gain frequency (UGF) higher than 20 MHz, which will allow a TS faster than 500 ns. The CL-LDO is going to be fabricated in a CMOS 130 nm technology; consume a quiescent current (IQ) of less than 50 μA; for a dropout voltage of 200 mV and an IvL of 50 mA. As technology scales down, speed and performance requirements increase for on-chip communication systems that reflect the current demand for high speed data-oriented applications. However, in small technologies, it becomes harder to achieve high gain and high speed at the same time because the supply voltage (VvDvD) decreases leaving no room for conventional high gain CMOS structures. The proposed active-RC LPF will accomplish a LV high BW operation that would allow such disadvantages to be overcome. The LPF will be implemented using an active RC structure that allows for the high linearity such communication systems demand. In addition, built-in BW and power configurability would address the demands for increased flexibility usually required in such systems. The proposed LV LPF will target a configurable cut-off frequency (ƒо) of 20/40/80/160 MHz with tuning capabilities and power adjustability for each ƒо. The filter will be fabricated in a CMOS 130 nm technology. The filter characteristics are as following: 4th -order, active-RC, LPF, Butterworth response, VDD = 0.6 V, THD higher than 40 dB and a third-order input intercept point (IIP3) higher than 10 dBm

A novel Digital OTA topology with 66-dB DC Gain and 12.3-kHz Bandwidth

The paper introduces an enhanced digital OTA topology which allows increasing the DC gain thanks to the adoption of an inverter-based output stage. Moreover, a new equivalent small-signal model is proposed which allows to simplify the circuit analysis and paves the way to new frequency compensation strategies. Designed using a 28-nm standard CMOS technology and working at 0.3-V power supply, post-layout simulations show a 66-dB gain and a 12.3-kHz gain bandwidth product while driving a 250-pF capacitive load. As compared to other ultra-low-voltage OTAs in literature, an increase of small and large signal performance, respect to area occupation, equal to 4.6X and 1.5X, respectively, is obtained

High-speed Time-interleaved Digital-to-Analog Converter (TI-DAC) for Self-Interference Cancellation Applications

Nowadays, the need for higher data-rate is constantly growing to enhance the quality of the daily communication services. The full-duplex (FD) communication is exemplary method doubling the data-rate compared to half-duplex one. However, part of the strong output signal of the transmitter interferes to the receiver-side because they share the same antenna with limited attenuation and, as a result, the receiver’s performance is corrupted. Hence, it is critical to remove the leakage signal from the receiver’s path by designing another block called self-interference cancellation (SIC). The main goal of this dissertation is to develop the SIC block embedded in the current-mode FD receivers. To this end, the regenerated cancellation current signal is fed to the inputs of the base-band filter and after the mixer of a (direct-conversion) current-mode FD receiver. Since the pattern of the transmitter (the digital signal generated by DSP) is known, a high-speed digital-to-Analog converter (DAC) with medium-resolution can perfectly suppress main part of the leakage on the receiver path. A capacitive DAC (CDAC) is chosen among the available solutions because it is compatible with advanced CMOS technology for high-speed application and the medium-resolution designs. Although the main application of the design is to perform the cancellation, it can also be employed as a stand-alone DAC in the Analog (I/Q) transmitter. The SIC circuitry includes a trans-impedance amplifier (TIA), two DACs, high-speed digital circuits, and built-in-self-test section (BIST). According to the available specification for full-duplex communication system, the resolution and working frequency of the CDAC are calculated (designed) equal to 10-bit (3 binary+ 2 binary + 5 thermometric) and 1GHz, respectively. In order to relax the design of the TIA (settling time of the DAC), the CDAC implements using 2-way time-interleaved (TI) manner (the effective SIC frequency equals 2GHz) without using any calibration technique. The CDAC is also developed with the split-capacitor technique to lower the negative effects of the conventional binary-weighted DAC. By adding one extra capacitor on the left-side of the split-capacitor, LSB-side, the value of the split-capacitor can be chosen as an integer value of the unit capacitor. As a result, it largely enhances the linearity of the CADC and cancellation performance. If the block works as a stand-alone DAC with non-TI mode, the digital input code representing a Sinus waveform with an amplitude 1dB less than full-scale and output frequency around 10.74MHz, chosen by coherent sampling rule, then the ENOB, SINAD, SFDR, and output signal are 9.4-bit, 58.2 dB, 68.4dBc, and -9dBV. The simulated value of the |DNL| (static linearity) is also less than 0.7. The similar simulation was done in the SIC mode while the capacitive-array woks in the TI mode and cancellation current is set to the full-scale. Hence, the amount of cancelling the SI signal at the output of the TIA, SNDR, SFDR, SNDRequ. equals 51.3dB, 15.1 dB, 24dBc, 66.4 dB. The designed SIC cannot work as a closed-loop design. The layout was optimally drawn in order to minimize non-linearity, the power-consumption of the decoders, and reduce the complexity of the DAC. By distributing the thermometric cells across the array and using symmetrical switching scheme, the DAC is less subjected to the linear and gradient effect of the oxide. Based on the post-layout simulation results, the deviation of the design after drawing the layout is studied. To compare the results of the schematic and post-layout designs, the exact conditions of simulation above (schematic simulations) are used. When the block works as a stand-alone CDAC, the ENOB, SINAD, SFDR are 8.5-bit, 52.6 dB, 61.3 dBc. The simulated value of the |DNL| (static linearity) is also limited to 1.3. Likewise, the SI signal at the output of the TIA, SNDR, SFDR, SNDRequ. are equal to 44dB, 11.7 dB, 19 dBc, 55.7 dB

Low-Power Slew-Rate Boosting Based 12-Bit Pipeline ADC Utilizing Forecasting Technique in the Sub-ADCS

The dissertation presents architecture and circuit solutions to improve the power efficiency of high-speed 12-bit pipelined ADCs in advanced CMOS technologies. First, the 4.5bit algorithmic pipelined front-end stage is proposed. It is shown that the algorithmic pipelined ADC requires a simpler sub-ADC and shows lower sensitivity to the Multiplying DAC (MDAC) errors and smaller area and power dissipation in comparison to the conventional multi-bit per stage pipelined ADC. Also, it is shown that the algorithmic pipelined architecture is more tolerant to capacitive mismatch for the same input-referred thermal noise than the conventional multi-bit per stage architecture. To take full advantage of these properties, a modified residue curve for the pipelined ADC is proposed. This concept introduces better linearity compared with the conventional residue curve of the pipelined ADC; this approach is particularly attractive for the digitization of signals with large peak to average ratio such as OFDM coded signals. Moreover, the minimum total required transconductance for the different architectures of the 12-bit pipelined ADC are computed. This helps the pipelined ADC designers to find the most power-efficient architecture between different topologies based on the same input-referred thermal noise. By employing this calculation, the most power efficient architecture for realizing the 12-bit pipelined ADC is selected. Then, a technique for slew-rate (SR) boosting in switched-capacitor circuits is proposed in the order to be utilized in the proposed 12-bit pipelined ADC. This technique makes use of a class-B auxiliary amplifier that generates a compensating current only when high slew-rate is demanded by large input signal. The proposed architecture employs simple circuitry to detect the need of injecting current at the output load by implementing a Pre-Amp followed by a class-B amplifier, embedded with a pre-defined hysteresis, in parallel with the main amplifier to boost its slew phase. The proposed solution requires small static power since it does not need high dc-current at the output stage of the main amplifier. The proposed technique is suitable for high-speed low-power multi-bit/stage pipelined ADC applications. Both transistor-level simulations and experimental results in TSMC 40nm technology reduces the slew-time for more than 45% and shorts the 1% settling time by 28% when used in a 4.5bit/stage pipelined ADC; power consumption increases by 20%. In addition, the technique of inactivating and disconnecting of the sub-ADC’s comparators by forecasting the sign of the sampled input voltage is proposed in the order to reduce the dynamic power consumption of the sub-ADCs in the proposed 12-bit pipelined ADC. This technique reduces the total dynamic power consumption more than 46%. The implemented 12-bit pipelined ADC achieves an SNDR/SFDR of 65.9/82.3 dB at low input frequencies and a 64.1/75.5 dB near Nyquist frequency while running at 500 MS/s. The pipelined ADC prototype occupies an active area of 0.9 mm^2 and consumes 18.16 mW from a 1.1 V supply, resulting in a figure of merit (FOM) of 22.4 and a 27.7 fJ/conversion-step at low-frequency and Nyquist frequency, respectively