A positive feedback-based op-amp gain enhancement technique for high precision applications

A power-efficient, voltage gain enhancement technique for op-amps has been described. The proposed technique is robust against Process, Voltage, and Temperature (PVT) variations. It exploits a positive feedback-based gain enhancement technique without any latch-up issue, as opposed to previously proposed conductance cancellation techniques. In the proposed technique, four additional transconductance-stages (gm stages) are used to boost the gain of the main gm stage. The additional gm stages do not significantly increase the power dissipation. A prototype was designed in 65nm CMOS technology. It results in 81dB voltage gain, which is 21dB higher than the existing gainboosting technique. The proposed opamp works with as low a power supply as 0.8V, without compromising the performance, whereas the traditional gain-enhancement techniques start losing gain below a 1.1V supply. The circuit draws a total static current of 295μA and occupies 5000μm2 of silicon area

Slew-rate enhancement and trojan state avoiding for fully-differential operational amplifier

Operational amplifiers are fundamental building blocks in modern analog and mixed-signal systems such as data converters, switched-capacitor circuits, and filters. The fully-differential structure is extensively used in these applications because of its improved dynamic performance with respect to such aspects as signal-to-noise ratio (SNR) and total harmonic distortion (THD) when compared to its single-ended counterpart. In some of these applications, the fully-differential amplifier is required to have fast transient settling time without slew-rate limitations. Power consumption also must be taken into consideration because low power consumption can significantly reduce a battery\u27s weight and size, and extend its life-time. A Class A amplifier is a difficult configuration in which to conciliate all these requirements, since its fixed bias current can limit its maximum output current. To simultaneously meet both slew-rate and power consumption requirements, several slew-rate enhancement (SRE) techniques have been proposed in the literature, but all of them are either incompatible with the low voltage operation or exhibit either degradation in linearity or increase in circuit complexity. This thesis presents a simple SRE technique, efficient in both power and area usage, improve the slew rate while overcoming the drawbacks of state-of-the-art SRE techniques. In this work, several existing SRE techniques are discussed, and their advantages and disadvantages are identified. The proposed SRE technique is based on excess transient detection and feedback. A transient signal can be detected at the internal nodes of amplifier. Once the detected transient signal is found to be larger than a pre-defined turn-on value, the excess transient signal can be instantaneously amplified to turn on a dynamic current source and feed it back to the amplifier for current boosting. This pre-defined turn-on voltage results in a SRE circuit being solidly off during quiescent state. Small-signal performance and linearity of the original amplifier can be thus well preserved. Thanks to this excess transient feedback concept, the implementation is much simpler than that of previously reported methods, and the static power overhead is also very small. Using the proposed SRE method, a fully-differential folded-cascode two-stage op-amp has been designed and fabricated using IBM 130nm process. This amplifier is designed to validate the proposed method of improving an amplifier\u27s input-stage slew-rate. If the tail current doubles during slewing, the simulation result indicates that, at all corners, with temperature from 0°C to 60°C the average slew-rate can be enhanced by a factor of 2.6 and the 1% settling time after a large input step is reduced by 30% compared to the vales without using SRE. Any further increment in the tail transient current can further increase the internal slew rate and eventually make it equal to the output-stage slew-rate. It is well-known that self-stabilized circuits, such as current, voltage and frequency references, are vulnerable to a problem of multiple operating points; this is also known as the start-up problem. An op-amp can suffer from the same problem when performance enhancement feedback is being used. In particular, a slew rate enhancement circuit (SRE) can be used to provide performance enhancement in low-power high-speed op-amp design. For such circuits, a systematic method for detecting and removal of Trojan states is presented. Using a design example and simulation results, it is demonstrated that the proposed method can effectively remove a Trojan state in an op-amp without degrading the improved slew-rate

Performance enhancement techniques for operational amplifiers

Operational amplifiers (op amps) are one of the most fundamental and widely used building blocks for analog and mixed-signal circuits and systems. As transistors’ feature size scales down in the deep submicron process, the short channel effects, high leakage current and reduced supply voltages make the design of op amps more challenging. In this dissertation, we present several methods to improve op amps’ DC gain, slew rate, power efficiency and current utilization efficiency (CUE). A basic requirement for an op amp is high DC gain especially for high precision applications. We introduce a method to robustly improve op amps’ DC gain with negligible power and area overhead. The new DC gain enhancement method can be implemented based on the source degeneration circuit (SDC) or the flipped voltage attenuator (FVA). Compared to the FVA-based technique, the SDC-based technique is more suitable for those CMOS processes whose transistors’ threshold voltages are too low for the transistors in the FVA to work in weak or strong inversion regions. Otherwise, the FVA-based technique is recommended as this technique is more robust to devices’ random mismatch. A prototype op amp with the FVA-based technique is designed and fabricated in the IBM130nm process. The measurement and simulation results of the prototype verify that the technique largely enhances an op amp’s DC and is very robust over process, voltage and temperature variations. Another important op amp requirement is high slew rate. In this regard, we introduce a method that greatly improves an op amp’s slew rate while still preserving its small signal performance by a well-defined turn-on condition. The performance of the introduced method is discussed in comparison with an existing adaptive biasing method that was widely used to enhance slew rate. The introduced method excels in several aspects. First, unlike the adaptive biasing method which degrades an op amp’ linearity, the introduced method is able to enhance linearity. Second, the proposed method improves an op amp’s slew rate by 2320% (vs. 780% by the adaptive method) with the power and area overhead of 2% and 1.2% (vs. 15% and 35% by the adaptive method). In addition, the proposed method improves the op amp’s total harmonic distortion (THD) by 6dB but the adaptive method degrades the THD by 12dB. The ability to drive large capacitive loads is becoming critical for op amps in emerging applications such as liquid crystal display drivers. In this regard, we introduce a power efficient design of op amps that can drive large capacitive loads. The proposed method decouples the large and small signal performance, eliminates current waste in the preamp stages’ load circuits, and is not sensitive to devices’ random mismatches. Compared to the state-of-the-art methods, our design prototype in a CMOS 180nm process shows largely improved small and large signal figure of merits, equivalent to largely improved power efficiency for given small and large signal performance specifications. Folded cascode amplifier (FCA) is a commonly used architecture for designing op amps, but a significant portion of supply current is wasted in the cascode stage. This not only reduces the current utilization efficiency (CUE), defined as the ratio of an FCA’s tail current to its total supply current, but also degrades the FCA’s gain, noise and offset. In this regard, we introduce a method to dramatically reduce a FCA’s cascode stage current without degrading the FCA’s settling performance. Compared to the existing methods, the proposed method effectively improves not only the CUE but also the settling performance of op amps. Lastly, a prototype FCA, with the proposed performance enhancement techniques of gain, slew rate and CUE, is designed to demonstrate the compatibility of these techniques