Author : Xiaopeng Wang
Publisher :
Page : 348 pages
File Size : 33,59 MB
Release : 2010
Category :
ISBN :
Author : Mike Wens
Publisher : Springer Science & Business Media
Page : 316 pages
File Size : 48,74 MB
Release : 2011-05-10
Category : Technology & Engineering
ISBN : 940071436X
CMOS DC-DC Converters aims to provide a comprehensive dissertation on the matter of monolithic inductive Direct-Current to Direct-Current (DC-DC) converters. For this purpose seven chapters are defined which will allow the designer to gain specific knowledge on the design and implementation of monolithic inductive DC-DC converters, starting from the very basics.
Author : Omar Al-Terkawi Hasib
Publisher :
Page : pages
File Size : 38,54 MB
Release : 2012
Category :
ISBN : 9780494802663
Author : Florian Neveu
Publisher :
Page : 218 pages
File Size : 24,58 MB
Release : 2020
Category :
ISBN :
Ultimate integration of power switch-mode converter relies on two research paths. One path experiments the development of switched-capacitor converters. This approach fits silicon integration but is still limited in term of power density. Inductive DC-DC architectures of converters suffer by the values and size of passive components. This limitation is addressed with an increase in frequency. Increase in switching losses in switches leads to consider advanced technological nodes. Consequently, the capability with respect to input voltage is then limited. Handling 3.3 V input voltage to deliver an output voltage in the range 0.6 V to 1.2 V appears a challenging specification for an inductive buck converter if the smallest footprint is targeted at +90 % efficiency. Smallest footprint is approached through a 3D assembly of passive components to the active silicon die. High switching frequency is also considered to shrink the values of passive components as much as possible. In the context of on-chip power supply, the silicon technology is dictated by the digital functions. Complementary Metal-Oxide- Semiconductor (CMOS) bulk C40 is selected as a study case for 3.3 V input voltage. 3.3 V Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) features poor figure of merits and 1.2 V standard core, regular devices are preferred. Moreover future integration as an on-chip power supply is more compatible. A three-MOSFET cascode arrangement is experimented and confronted experimentally to a standard buck arrangement in the same technology. The coupled-phase architecture enables to reduce the switching frequency to half the operating frequency of the passive devices. +100MHz is selected for operation of passive devices. CMOS bulk C40 offers Metal-Oxide-Metal (MOM) and MOS capacitors, in density too low to address the decoupling requirements. Capacitors have to be added externally to the silicon die but in a tight combination. Trench-cap technology is selected and capacitors are fabricated on a separate die that will act as an interposer to receive the silicon die as well as the inductors. The work delivers an object containing a one-phase buck converter with the silicon die flip-chipped on a capacitor interposer where a tiny inductor die is reported. The one-phase demonstrator is suitable for coupled-phase demonstration. Standard and cascode configurations are experimentally compared at 100 MHz and 200 MHz switching frequency. A design methodology is presented to cover a system-to-device approach. The active silicon die is the central design part as the capacitive interposer is fabricated by IPDiA and inductors are provided by Tyndall National Institute. The assembly of the converter sub-parts is achieved using an industrial process. The work details a large set of measurements to show the performances of the delivered DC/DC converters as well as its limitations. A 91.5% peak efficiency at 100MHz switching frequency has been demonstrated.
Author : Peter Renz
Publisher : Springer Nature
Page : 181 pages
File Size : 30,6 MB
Release : 2020-12-29
Category : Technology & Engineering
ISBN : 3030639444
This book provides a comprehensive, single-source on resonant switched-capacitor converters. It is written in the style of a handbook, with systematic guidelines, and includes implementation examples. The authors explore integrated hybrid resonant DCDC converters in order to achieve highly compact, energy efficient and cost-effective power management solutions in the growing fields of wearables and internet-of-things applications. They provide an introduction into hybrid converters as a new and promising converter class, which merges capacitive and inductive conversion concepts into one. Coverage ranges from fundamentals to implementation details, including topics such as power stage design, gate drive schemes, different control mechanisms for resonant operation and integrated passives. Introduces a new, multi-ratio resonant converter architecture, which enables lower switching frequencies and better passive component utilization; Discusses circuit block design for high efficiency of the power stage; Explores implementation details and concepts for integrated passives; Derives models, implements and compares to each other different control mechanisms.
Author : Chong-Min Kyung
Publisher : Springer Science & Business Media
Page : 295 pages
File Size : 22,81 MB
Release : 2011-06-17
Category : Science
ISBN : 9400716796
Power consumption becomes the most important design goal in a wide range of electronic systems. There are two driving forces towards this trend: continuing device scaling and ever increasing demand of higher computing power. First, device scaling continues to satisfy Moore’s law via a conventional way of scaling (More Moore) and a new way of exploiting the vertical integration (More than Moore). Second, mobile and IT convergence requires more computing power on the silicon chip than ever. Cell phones are now evolving towards mobile PC. PCs and data centers are becoming commodities in house and a must in industry. Both supply enabled by device scaling and demand triggered by the convergence trend realize more computation on chip (via multi-core, integration of diverse functionalities on mobile SoCs, etc.) and finally more power consumption incurring power-related issues and constraints. Energy-Aware System Design: Algorithms and Architectures provides state-of-the-art ideas for low power design methods from circuit, architecture to software level and offers design case studies in three fast growing areas of mobile storage, biomedical and security. Important topics and features: - Describes very recent advanced issues and methods for energy-aware design at each design level from circuit and architecture to algorithm level, and also covering important blocks including low power main memory subsystem and on-chip network at architecture level - Explains efficient power conversion and delivery which is becoming important as heterogeneous power sources are adopted for digital and non-digital parts - Investigates 3D die stacking emphasizing temperature awareness for better perspective on energy efficiency - Presents three practical energy-aware design case studies; novel storage device (e.g., solid state disk), biomedical electronics (e.g., cochlear and retina implants), and wireless surveillance camera systems. Researchers and engineers in the field of hardware and software design will find this book an excellent starting point to catch up with the state-of-the-art ideas of low power design.
Author : Sakshi Arora
Publisher :
Page : pages
File Size : 35,65 MB
Release : 2013
Category :
ISBN :
In order to achieve high power density in battery-powered systems, as well as accommodate the reduced breakdown voltages in scaled CMOS technologies, systems-on-a-chip (SoCs) typically employ one or more supply voltages generated using dc-dc converters. Dc-dc converters are commonly implemented as inductive switching converters because of their high efficiency. However, inductive converters typically have a large footprint that is dominated by the size of bulky off-chip inductors and capacitors. In order to reduce the size of an inductive converter, its switching frequency can be increased by orders of magnitude above the existing practice. However, the use of a high switching frequency leads to increased switching power losses that in turn decrease the power conversion efficiency. To address this challenge, techniques for designing a high-efficiency buck converter while using miniaturized external components are investigated in this research. Design techniques, such as using a high switching frequency that is tunable with the load current and the segmentation and cascoding of power transistors are employed to achieve high power efficiency across a wide range of load currents. While in SoC applications multiple voltages are typically derived from battery by connecting converters in parallel, this work introduces a cascaded, dual-output buck converter topology. Cascading buck converters reduces the input supply voltage of the second converter, thus reducing the switching and ripple-conduction losses that severely affect the efficiency of buck converters using small inductors and operating at high switching frequencies. The use of high-frequency, cascaded conversion presents two significant challenges to the design of the controller for a buck converter. First is the need for adjustability of the switching frequency with varying load currents, and second is the possibility of cross regulation between the outputs of the converter. A digital constant-off-time controller is proposed to address these challenges. The controller enables tuning of the converter's switching frequency. The controller has a fast transient response and good line regulation that help to suppress cross regulation between the two outputs of the buck converter. To demonstrate the proposed multiple-output, cascaded, high-frequency converter, an experimental prototype has been integrated in a 90-nm CMOS technology. This prototype provides two output voltages using a cascade of two buck converters, each employing a small output capacitor on the order of 100 picofarads and a small inductor on the order of nanohenries, thereby reducing the overall size of the converter compared to conventional alternatives.
Author : Deshang Sha
Publisher : Springer
Page : 326 pages
File Size : 46,63 MB
Release : 2018-05-17
Category : Technology & Engineering
ISBN : 9811302596
Written by experts, this book is based on recent research findings in high-frequency isolated bidirectional DC-DC converters with wide voltage range. It presents advanced power control methods and new isolated bidirectional DC-DC topologies to improve the performance of isolated bidirectional converters. Providing valuable insights, advanced methods and practical design guides on the DC-DC conversion that can be considered in applications such as microgrid, bidirectional EV chargers, and solid state transformers, it is a valuable resource for researchers, scientists, and engineers in the field of isolated bidirectional DC-DC converters.
Author : Seyedmohammad Mousavi
Publisher :
Page : 129 pages
File Size : 48,39 MB
Release : 2020
Category : DC-to-DC converters
ISBN :
Power Electronics converters used in different applications such as photovoltaic systems and electric vehicles require low size and high-efficiency converters with a step-down or step-up voltage ratio depends on their applications. Resonant switched-capacitor converters (R-SCC) are an alternative to inductor-based converters, known as buck or boost converters. These topologies reduce the size of the power converters, and their resonant operation reduces the switching losses of switching devices (higher efficiency) and mitigates the high spike-current over switching components during switching instants. In addition, DC sources are integrated into the power system through voltage-source converters (VSC). For this application, there is a need for a controller to regulate the output power and voltage of VSCs. This dissertation studies different operating modes of a multi-stage R-SCC for step-down and step-up voltage ratios. It also proposes a systematic method to calculate the output characteristics of the proposed resonant converters. In addition, a voltage controller is proposed to regulate the output voltage of the resonant converter while there is a variation in input voltage or load. It also evaluates the performance of a controller for a VSC in the VSCbased power system. All studies are verified by simulation and experimental results.
Author : Hongwei Jia
Publisher :
Page : 112 pages
File Size : 28,99 MB
Release : 2010
Category : DC-to-DC converters
ISBN :
A monolithically integrated smart rectifier has been presented first in this work. The smart rectifier, which integrates a power MOSFET, gate driver and control circuitry, operates in a self-synchronized fashion based on its drain-source voltage, and does not need external control input. The analysis, simulation, and design considerations are described in detail. A 5V, 5-[micrometers] CMOS process was used to fabricate the prototype. Experimental results show that the proposed rectifier functions as expected in the design. Since no dead-time control needs to be used to switch the sync-FET and ctrl-FET, it is expected that the body diode losses can be reduced substantially, compared to the conventional synchronous rectifier. The proposed self-synchronized rectifier (SSR) can be operated at high frequencies and maintains high efficiency over a wide load range. As an example of the smart rectifier's application in isolated DC-DC converter, a synchronous flyback converter with SSR is analyzed, designed and tested. Experimental results show that the operating frequency could be as high as 4MHz and the efficiency could be improved by more than 10% compared to that when a hyper fast diode rectifier is used. Based on a new current-source gate driver scheme, an integrated gate driver for buck converter is also developed in this work by using a 0.35[micrometer] CMOS process with optional high voltage (50V) power MOSFET. The integrated gate driver consists both the current-source driver for high-side power MOSFET and low-power driver for low-side power MOSFET. Compared with the conventional gate driver circuit, the current-source gate driver can recovery some gate charging energy and reduce switching loss. So the current-source driver (CSD) can be used to improve the efficiency performance in high frequency power converters. This work also presents a new implementation of a power supply in package (PSiP) 5MHz buck converter, which is different from all the prior-of-art PSiP solutions by using a high-Q bondwire inductor. The high-Q bondwire inductor can be manufactured by applying ferrite epoxy to the common bondwire during standard IC packaging process, so the new implementation of PSiP is expected to be a cost-effective way of power supply integration.
