Comparative analysis of analog LDO design

The presented research analyses different topologies of low dropout (LDO) regulator, mostly focusing on different frequency compensation schemes and power supply rejection analysis. This thesis discusses different analog LDO topologies and analyzes how they achieve stability using small signal analysis and related equations. The power supply rejection (PSR) of a different error amplifier and pass device has been analyzed and concluded that a Type-B amplifier with n-channel metal oxide semiconductor field effect transistor (MOSFET) output stage or a Type-A amplifier with p channel MOSFET (PMOS) output stage yields the best PSR. Digital LDO regulator topologies have also been discussed. The digital LDO regulator is intriguing due to its low power and synthesizability, but it suffers from coarse voltage regulation and poor PSR compared to the analog LDO regulator

A Case Study in CMOS Design Scaling for Analog Applications: The Ringamp LDO

As CMOS process nodes scale to smaller feature sizes, process optimizations are made to achieve improvements in digital circuit performance, such as increasing speed and memory, while decreasing power consumption. Unfortunately for analog design, these optimizations usually come at the expense of poorer transistor performance, such as reduced small signal output resistance and increased channel length modulation. The ring amplifier has been proposed as a digital solution to the analog scaling problem, by configuring digital inverters to function as analog amplifiers through deadzone biasing. As digital inverters naturally scale, the ring amplifier is a promising area of exploration for analog design. This work presents a ring amplifier scaling study by demonstration of scaling an output capacitor-less, ring amplifier based low-dropout voltage regulator designed in a standard 180 nm CMOS process down to a standard 90 nm CMOS process

Power Supply Rejection Improvement Techniques In Low Drop-Out Voltage Regulators

Low drop out (LDO) voltage regulators are widely used for post regulating the switching ripples generated by the switched mode power supplies (SMPS). Due to demand for portable applications, industry is pushing for complete system on chip power management solutions. Hence, the switching frequencies of the SMPS are increasing to allow higher level of integration. Therefore, the subsequent post-regulator LDO must have good power supply rejection (PSR) up to switching frequencies of SMPS. Unfortunately, the conventional LDOs have poor PSR at high frequencies. The objective of this research is to develop novel LDO regulators that can achieve good high frequency PSR performance. In this thesis, two PSR improvement methods are presented. The first method proposes a novel power supply noise-cancelling scheme to improve the PSR of an external-capacitor LDO. The proposed power supply noise-cancelling scheme is designed using adaptive power consumption, thereby not degrading the power efficiency of the LDO. The second method proposes a feed forward ripple cancellation technique to improve the PSR of capacitor-less LDO; also a dynamically powered transient improvement scheme has been proposed. The feed forward ripple cancellation is designed by reusing the load transient improvement block, thus achieving the improvement in PSR with no additional power consumption. Both the projects have been designed in TSMC 0.18 μm technology. The first method achieves a PSR of 66 dB up to 1 MHz where as the second method achieves a 55 dB PSR up to 1 MHz

Modularizing the LDO to optimize performance based on application design constraints

This thesis aims to construct a modular low-dropout regulator that gives designers more freedom in building a highly efficient regulator that meets application demands. This modular design is able to separate DC regulation and high-frequency supply rejection while not compromising on either of the two. Flexibility is a key requirement during both design and post-design. The proposed regulator is able to achieve all the required goals with full spectrum power supply rejection. By splitting the pass device, this design is able to achieve the best of both internal pole dominant and external pole dominant linear regulators