ANALYSIS OF POWER EFFICIENCY FOR FOUR-PHASE POSITIVE CHARGE PUMPS

Similar documents
CHARGE pump circuits are widely applied to flash memories

V DD. M 1 M 2 V i2. V o2 R 1 R 2 C C

Fully Integrated Dickson Charge Pumps with Optimized Power Efficiency

Polytech Montpellier MEA4 M2 EEA Systèmes Microélectroniques. Analog IC Design

An Improved Logical Effort Model and Framework Applied to Optimal Sizing of Circuits Operating in Multiple Supply Voltage Regimes

Power Dissipation. Where Does Power Go in CMOS?

EE115C Winter 2017 Digital Electronic Circuits. Lecture 6: Power Consumption

CARNEGIE MELLON UNIVERSITY DEPARTMENT OF ELECTRICAL AND COMPUTER ENGINEERING DIGITAL INTEGRATED CIRCUITS FALL 2002

5.0 CMOS Inverter. W.Kucewicz VLSICirciuit Design 1

Heap Charge Pump Optimisation by a Tapered Architecture

EE 435 Lecture 13. Cascaded Amplifiers. -- Two-Stage Op Amp Design

PI3CH400 4-Bit Bus Switch, Enable Low 1.8V/2.5V/3.3V, High-Bandwidth, Hot Plug

Analysis and Design of Analog Integrated Circuits Lecture 7. Differential Amplifiers

Dynamic operation 20

EE 466/586 VLSI Design. Partha Pande School of EECS Washington State University

EE 435 Lecture 44. Switched-Capacitor Amplifiers Other Integrated Filters

Low Power CMOS Dr. Lynn Fuller Webpage:

CMOS Digital Integrated Circuits Lec 13 Semiconductor Memories

Integrated Circuits & Systems

Lab 4: Frequency Response of CG and CD Amplifiers.

Lecture 6 Power Zhuo Feng. Z. Feng MTU EE4800 CMOS Digital IC Design & Analysis 2010

Power Consumption in CMOS CONCORDIA VLSI DESIGN LAB

Digital Integrated Circuits A Design Perspective. Semiconductor. Memories. Memories

ECE321 Electronics I

EE141Microelettronica. CMOS Logic

MOSFET and CMOS Gate. Copy Right by Wentai Liu

System on a Chip. Prof. Dr. Michael Kraft

PART. Maxim Integrated Products 1

Design of Analog Integrated Circuits

Switched-Capacitor Circuits David Johns and Ken Martin University of Toronto

Chapter 13 Small-Signal Modeling and Linear Amplification

THE INVERTER. Inverter

Chapter 2 CMOS Transistor Theory. Jin-Fu Li Department of Electrical Engineering National Central University Jungli, Taiwan

MOS Transistor I-V Characteristics and Parasitics

MOS Transistor Theory

Objective and Outline. Acknowledgement. Objective: Power Components. Outline: 1) Acknowledgements. Section 4: Power Components

Compact, Dual-Output Charge Pump

EECS 141: FALL 05 MIDTERM 1

Where Does Power Go in CMOS?

Semiconductor Memories

ECE-343 Test 2: Mar 21, :00-8:00, Closed Book. Name : SOLUTION

EECE488: Analog CMOS Integrated Circuit Design. Introduction and Background

Lecture 320 Improved Open-Loop Comparators and Latches (3/28/10) Page 320-1

Switched-Capacitor Voltage Doublers

! Charge Leakage/Charge Sharing. " Domino Logic Design Considerations. ! Logic Comparisons. ! Memory. " Classification. " ROM Memories.

Lecture 2: CMOS technology. Energy-aware computing

Electric-Energy Generation Using Variable-Capacitive Resonator for Power-Free LSI: Efficiency Analysis and Fundamental Experiment

Advanced Current Mirrors and Opamps

ESE570 Spring University of Pennsylvania Department of Electrical and System Engineering Digital Integrated Cicruits AND VLSI Fundamentals

EECS 427 Lecture 11: Power and Energy Reading: EECS 427 F09 Lecture Reminders

COMBINATIONAL LOGIC. Combinational Logic

ECE 438: Digital Integrated Circuits Assignment #4 Solution The Inverter

Lecture 4: CMOS Transistor Theory

A Novel LUT Using Quaternary Logic

EE 435. Lecture 18. Two-Stage Op Amp with LHP Zero Loop Gain - Breaking the Loop

Is quantum capacitance in graphene a potential hurdle for device scaling?

PURPOSE: See suggested breadboard configuration on following page!

ELEN0037 Microelectronic IC Design. Prof. Dr. Michael Kraft

MODELING A METAL HYDRIDE HYDROGEN STORAGE SYSTEM. Apurba Sakti EGEE 520, Mathematical Modeling of EGEE systems Spring 2007

Accurate Estimating Simultaneous Switching Noises by Using Application Specific Device Modeling

Novel Comprehensive Analytical Probabilistic Models of The Random Variations in MOSFET s High Frequency Performances

MOSIS REPORT. Spring MOSIS Report 1. MOSIS Report 2. MOSIS Report 3

Lecture 8-1. Low Power Design

A Multigrid-like Technique for Power Grid Analysis

Modeling of High Voltage AlGaN/GaN HEMT. Copyright 2008 Crosslight Software Inc.

ESE 570: Digital Integrated Circuits and VLSI Fundamentals

Mixed-Signal IC Design Notes set 1: Quick Summary of Device Models

The Inverter. Digital Integrated Circuits A Design Perspective. Jan M. Rabaey Anantha Chandrakasan Borivoje Nikolic

Magnetic core memory (1951) cm 2 ( bit)

Announcements. EE141- Fall 2002 Lecture 7. MOS Capacitances Inverter Delay Power

EE C245 - ME C218 Introduction to MEMS Design Fall Today s Lecture

Digital Integrated Circuits A Design Perspective

P. R. Nelson 1 ECE418 - VLSI. Midterm Exam. Solutions

EE241 - Spring 2000 Advanced Digital Integrated Circuits. Announcements

Wire antenna model of the vertical grounding electrode

Topic 4. The CMOS Inverter

ECE-343 Test 1: Feb 10, :00-8:00pm, Closed Book. Name : SOLUTION

Announcements. EE141- Spring 2003 Lecture 8. Power Inverter Chain

Thin Film Transistors (TFT)

Programmable Timer High-Performance Silicon-Gate CMOS

UNIVERSITY OF CALIFORNIA College of Engineering Department of Electrical Engineering and Computer Sciences. Professor Oldham Fall 1999

Example: High-frequency response of a follower

TECHNICAL INFORMATION

Digital Integrated Circuits 2nd Inverter

Errata of K Introduction to VLSI Systems: A Logic, Circuit, and System Perspective

Dynamics of Dickson Charge Pump Circuit

Topics. Dynamic CMOS Sequential Design Memory and Control. John A. Chandy Dept. of Electrical and Computer Engineering University of Connecticut

HN58C66 Series word 8-bit CMOS Electrically Erasable and Programmable CMOS ROM. ADE F (Z) Rev. 6.0 Apr. 12, Description.

EE 466/586 VLSI Design. Partha Pande School of EECS Washington State University

Assignment 3 ELEC 312/Winter 12 R.Raut, Ph.D.

Chapter 2 Switched-Capacitor Circuits

EE382M-14 CMOS Analog Integrated Circuit Design

Impact of sidewall spacer on gate leakage behavior of nano-scale MOSFETs

CMOS Digital Integrated Circuits Lec 10 Combinational CMOS Logic Circuits

The CMOS Inverter: A First Glance

A Low-Error Statistical Fixed-Width Multiplier and Its Applications

Octal 3-State Noninverting Buffer/Line Driver/Line Receiver High-Performance Silicon-Gate CMOS

GMU, ECE 680 Physical VLSI Design 1

Lecture 7 Circuit Delay, Area and Power

Lecture 25. Semiconductor Memories. Issues in Memory

Transcription:

ANALYSS OF POWER EFFCENCY FOR FOUR-PHASE POSTVE CHARGE PUMPS Chien-pin Hsu and Honchin Lin Department of Electrical Enineerin National Chun-Hsin University, Taichun, Taiwan e-mail:hclin@draon.nchu.edu.tw ABSTRACT n this paper, the compact model of power efficiency for four-phase positive chare pump is derived. The model was verified by usin post-layout simulation with 0.5µm triple-well flash memory technoloy. By includin parasitic effects in the pump, the discrepancies between the model and the post-layout simulation results are within 4%. KEY WORDS Modellin, power efficiency, body effect, threshold voltae, and chare pump 1. ntroduction The chare pump is a DC-DC voltae converter to enerate the required voltae hiher or lower than the supply voltae. Chare pump circuits are usually applied to flash memory, EEPROM and LCD displays. The most popular schemes are based on the circuit proposed by Dickson [1]. Due to low power requirement in many applications, the power efficiency of the chare pump has become one of the important issues in recent years. Palumbo et al. proposed an optimized stratey to desin minimum power consumption for the two-phase chare pump []. The power efficiency comparison between four-phase chare pump and voltae doublers [3] was presented. Even thouh the power efficiency of voltae doublers is slihtly better, they require h NMOS and PMOS transistors at the same time, unlike four-phase chare pumps only requirin NMOS or PMOS transistors. The SO CMOS process used to increase efficiency was discussed in [4]- [6]. Althouh many works have been done for power efficiencies of the two-phase chare pumps and voltae doublers, there have been few reports focused on fourphase chare pumps. n this paper, a complete chare transfer method to analyze the power efficiency is presented for the four-phase chare pump. The resultin model was verified by usin a 0.5µm triple-well flash memory process. This paper is oranized as follows. n Section, the modified four-phase four-stae positive chare is described. The formulation of power efficiency for the chare pump is derived in the next section. Section 4 shows the areement of the proposed model and the postlayout simulations. The final conclusions are iven in Section 5.. The Four-Phase Positive Chare Pump The performance of the Dickson chare pump is deraded due to threshold voltae and body effect. The modified four-stae positive chare pump with the four-phase clocks is shown in Fi. 1 [7]. The reason to add the transistor M si (i = 1~4) will be iven below. One stae of the chare pump consists of a storae capacitor (C i = C L = C, i = 1~4), an NMOS switch (M i ), a ate boostin circuitry (M i and C i ), and a body control transistors M si. Durin the chare transferrin period, the chare stored in C i is transferred to C i+1 of the next stae throuh the switch transistor, M i. n order to eliminate the threshold voltae deradation in M i, the ate boostin circuitry is used to raise much hiher ate voltae of M i. The conventional method to avoid body effect of M i is achieved by tie the well to its drain. However, the hih instantaneous PN junction between the well and the source may cause hiher noise in the chip, thus the reliability may become an issue. To minimize the noise issue, the transfer switch M si is used to track the well to the lowest potential in each stae to avoid body effects [8]. Fi. 1. The modified four-stae positive chare pump and the four-phase clocks 573-109 15

The output of an N-stae four-phase positive chare pump can be iven as C N Vout = ( N + 1) V Vtn (1) C C + f ( C + C ) where V tn is the threshold voltae of switch M out, C is the switch-node parasitic capacitance, is the current, and f is clock frequency whose amplitude is V. = + + 3 + + t1 t () t 3 = + + b + t (3) t 5 = + + + t (4) Qt 7 = + + t + b (5) 3. Compact Model of Power Efficiency To calculate the power efficiency of the four-phase positive chare pump, the power consumption must be evaluated. The power consumption in the chare pump includes the storae capacitor C i, the boostin capacitor C i, the tom-plate (C ) and the -plate (C ) parasitic capacitances of C i, as well as the tom-plate (C b ) and the -plate (C t ) parasitic capacitances of C i. Actually, the total switch-node parasitic capacitors include the ate capacitance of M i, C db of M i, C db and C sb of M i, and C db of M si [6]. For simplicity, those parasitic capacitances are assumed to be included in C and C t in the followin analysis. Moreover, the ideal clock sinals without buffers are directly connected to the tom plates of C i and C i for power efficiency analyses [1], since the sizes of buffers influence the power consumption and the waveforms of clocks. The clock cycles are divided into eiht different intervals in time. Fis. to 5 illustrate the chare distribution of the four-phase positive chare pump in time intervals t1, t3, t5 and t7, respectively. Durin t1, M 1, M 3 and M out are turned on and the chares of V and φ 1 are transferred to C 1, C 3 and C L, respectively. At time interval t3, the chares of V and C are transferred to C 1 and C 3 throuh M 1 and M 3, respectively. Durin t5, similar to t1, M and M 4 turn on and the chares of φ 3 are delivered to C and C 4. Similarly, at time t7, those chares stored in C 1 and C 3 are transferred to C and C 4 throuh M and M 4, respectively. Nevertheless, there is no chare consumed in the others time interval. The clock cycles are divided into eiht different intervals in time. Fis. to 5 illustrate the chare distribution of the four-phase positive chare pump in time intervals t1, t3, t5 and t7, respectively. Durin t1, M 1, M 3 and M out are turned on and the chares of V and φ 1 are transferred to C 1, C 3 and C L, respectively. At time interval t3, the chares of V and C are transferred to C 1 and C 3 throuh M 1 and M 3, respectively. Durin t5, it is similar to t1 that M and M 4 are turned on and the chares of φ 3 are delivered to C and C 4. Similarly, at time t7, those chares stored in C 1 and C 3 are transferred to C and C 4 throuh M and M 4, respectively. Nevertheless, there is no chare consumed in the other time intervals. From t1 to t8, the chares provided by V are Fi.. Chare transfer durin t1 (φ 1 = φ 3 = hih, φ = φ 4 = Fi. 3. Chare transfer durin t3 (φ 1 = φ = hih, φ 3 = φ 4 = Fi. 4. Chare transfer durin t5 (φ 1 = φ 3 = hih, φ = φ 4 = Fi. 5. Chare transfer durin t7 (φ 1 = φ = low, φ 3 = φ 4 = hih) The total chare provided by the power supply in one clock cycle is the sum of Eqns. () to (5). T = 5 + 4 + 9 + 4 + 8 t + 4 (6) 1 b Therefore, the total current consumption of the four-phase chare pump is 16

total = 5 + 4 + 9 + 4 + 8t + 4b (7) This analysis can be extended to any number of staes. For an N-stae chare pump, the total current consumption can be expressed as total = ( N + 1) + N + (N + 1) + N + Nt + Nb (8) The current that chares and dischares the tom plate and the plate of the storae capacitor is iven as [6] = C V (9) C = C + C (10) where V is the supply voltae and is the output in current. Similarly, b = C V b Ct and t Ci + C t can be obtained for the tom plate and the plate of the boostin capacitor, where is the current that chares the boostin capacitor. By definition, the power efficiency of the chare pump may be written as follows. P out Vout η = = (11) P V in By substitutin the above expressions of currents and V out into Eqn. (11), the efficiency η can be written in Eqn. (1). C N ( N+ 1)( ) V Vtn C+ C f ( C+ C ) η = NC ( 1) V f N+ C N t Cb V f V ( N+ 1) + + + + N + N C+ C ( Ci + Ct ) total (1) Since the tom-plate and the -plate parasitic capacitance C and C are nearly proportional to the storae capacitor C, we may assume C = αc and C = C. Hence, Eqns. (9) and (10) become = α V (13) = = (14) C + Similarly, C b and C t are also fractions of the boostin capacitor C i so that C b = α C i and C t = C i. b and t can be expressed as b = α i V (15) i t = = (16) C + i i 1 N ( N + 1)( ) V Vtn f (1 + ) η = NαCV + V f (N 1) γ α γ V ( N + 1) + + + Nγ + N + N 4. Model Verification f (17) To verify the compact model obtained in the previous section, the post-layout SPCE simulations were carried out with 0.5 µm triple-well flash memory technoloy. The threshold voltae of the NMOS is about 0.65 V. The storae capacitance and the boostin capacitance for the chare pump are 35 pf and 1 pf, respectively. The parameters α and based on the post-layout parasitic parameter extraction for the chare pump are α = 0.171 and = 0.0. Similarly, the parameters related to the boostin capacitors α and are 0.185 and 0.019, respectively. A set of simulation results was performed by varyin the supply voltae from 1. V to V with the output current from 0 µa to µa at the frequency of 6MHz or 10MHz. Power efficiency and V out are compared between the compact model and post-layout simulations in Fis. 6 to 9. The simulations aree well with the model with the maximum errors lower than 4%. Efficency (%) 45 35 30 Model Simulation 1. 1.4 1.6 1.8 Supply Voltae (Volt) Fi.6. Power efficiencies versus supply voltaes for the four-stae pump with f = 10 MHz and output current = 1 µa Since the storae capacitance is more than an order of manitude larer than boostin capacitor. Therefore, it can be assumed that C i is a fraction of C to have C i = γc. Thus, Eqn. (1) can be rewritten as 17

V out (Volt) 8 7 6 5 4 0 100 1 00 Fi. 7. Output voltaes vs. in currents for the fourstae positive chare pump with V = 1.8 V Efficiency (%) Error (%) 30 0 10 0 100 1 00 4 3 1 6 MHz 10 MHz 0 0 100 1 00 Fi. 8. Power efficiencies and error percentae between the model and simulations are plotted as functions of in current for the four-stae chare pump with V = 1.8 V. 5. Conclusion n this work, a theoretical analysis of power efficiency is presented for the four-phase positive chare pump with body potential control to avoid body effects and minimize noise due to PN junction conduction. The compact model well arees with the post-layout simulation results. The maximum errors are always less than 4% for various in currents and supply voltaes. This model should be very helpful for desin of stae number, capacitors and operation frequency of positive four-phase chare pumps. Acknowledements The authors would like to acknowlede Chip mplementation Center (CC) of National Applied Research Laboratories (NARL) of Taiwan for the support in chip desin. This work was supported by National Science Council of Taiwan (NSC 95-1-E-005-145 and NSC 95-0-E-005-005). Efficiency (%) 55 45 35 0 4 6 8 10 Number of staes Fi. 9. Power efficiencies versus stae numbers for the four-stae chare pump with output current of 1 µa and V = 1.8 V. References [1] J. Dickson, On-chip hih-voltae eneration NMOS interated circuits usin an improved voltae multiplier technique, EEE J. Solid-State Circuits, SC- 11, 1976, 374-378. [] G. Palumbo, D. Pappalardo, and M. Gaiti, Charepump circuits: power-consumption optimization, EEE Trans. on Circuits and Systems : Fundamental Theory and Applications, 49, 00, 1535 154. [3] D. Baderna, A. Cabrini, G. Torelli, and M. Pasotti, Efficiency comparison between doubler and Dickson chare pumps, EEE nt. Symp. Circuits Syst.,, Kobe, Japan, 005, 1891-1894. [4] M. R. Houe, T. McNutt, J. Zhan, A. Mantooth, and M. M. Mojarradi, A hih voltae Dickson chare pump in SO CMOS, Proc. EEE Custom nterated Circuits Conf., 003, 493-496. [5] M. R. Houe T. Ahmad, T. R. McNutt, H. A. Mantooth, and M. M. Mojarradi, Desin technique of an on-chip, hih-voltae chare pump in SO, EEE nt. Symp. Circuits Syst., 1, Kobe, Japan, 005, 133-136. 18

[6] M. R. Houe, T. Ahmad, T. R. McNutt, H. A. Mantooth, & M. M. Mojarradi, A Technique to ncrease the Efficiency of Hih Voltae Chare Pumps, EEE Trans. on Circuits and Systems : Express Briefs, 53, 006, 364-368. [7] H. Lin, J. Lu and Y.-T. Lin, A new four-phase chare pump without body effects for low supply voltaes, Proc. EEE Asia-Pacific Conference, Taipei, Taiwan, 00, 53-56. [8] J. Shin,.-Y. Chun, Y. J. Park, & H. S. Min, A new chare pump without deradation in threshold voltae due to body effect, EEE J. Solid-State Circuits, 35, 000, 17-130. 19

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback