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SURVEY OF VARIOUS TYPES OF DLL ELEMENTS ECE 518 RAHUL SRIKONDA 112147600 28TH April CONTENTS 1. 2. 3 3. 4. 5 5. INTRODUCTION DELAY ELEMENTS EXAMPLES CONCLUSION REFERENCES 1.INTRODUCTION CLOCK SIGNAL LOCKED WITH THE INCOMING SINGAL NECESSITY OF DLL OUTPUT JITTER Φclock/Φout is zero TRANSFER FUNCTION: RISE TIME FOR A STEP RESPONSE IS GIVEN BY : VARIATION IN C1/Ipump AND Kv CAN INCREASE JITTER 2. DELAY ELEMENTS: ANALOG DELAY LINE VS DIGITAL DELAY LINE JITTER PERFORMANCE COMPLEXITY LAYOUT AREA AND POWER SIMPLICITY PORTABLITY SUPPLY VOLTAGE 3. EXAMPLES: 1. DELAY LINES BASED ON INVERTERS: CONVENTIONAL DELAY LINES BASED ON INVERTERS: CHARACTERISTICS: PROVIDE THE SHORTEST DELAY DELAY LINE IS TAPPED AT EVERY OTHER INVERTER TO PROVIDE PHASE MATCHING BETWEEN ADJACENT TAPS USAGE OF A LONG DELAY LINE(LARGER AREA AND LARGER POWER CONSUMPTION) POOR OO POWER O S SUPPLY REJECTION C O RATIO A O ACCUMULATION OF JITTER IMPROVEMENTS IN DESIGN OF CONVENTIONAL DELAY LINES: CHARACTERISTICS: USAGE OF COMPLEMENTARY INPUTS PROVIDES TAPPING AT EVERY NODE REDUCTION IN TOTAL DELAY REDUCED JITTER ACCUMULATION LOW POWER CONSUMPTION AND LAYOUT AREA CREATES PROBLEMS REGARDING TAPPING OF TRUE TAPS AND COMPLEMENTARY TAPS ADDITONAL EOC DETECTOR IS NEEDED REFERENCE: THIS DELAY LINE HAS BEEN USED TO ACHIEVE INFINITE PHASE RANGE IN A 3.3v,0.4µm µ STANDARD CMOS PROCESS “A Portable Digital DLL for High-Speed CMOS Interface Circuits,1998” 2. DUAL LOOP DLL: DUAL LOOP DLL WITH LINEAR DELAY ELEMENT: CHARACTERISTICS: COMBINES THE ADVANTAGE OF FINE DELAY TUNING OF ANALOG DLL AND COARSE TUNING OF DIGITAL DLL ADVANTAGES: FINE GRAIN DELAY VARIATION IS OBTAINED VIA ANALOG DELAY ELEMENT COARSE GRAIN DELAY VARIATION IS OBTAINED VIA DIGITAL DELAY ELEMENT DISADVANTAGES: INHERENT CLOCK SKEW DUE TO DIGITAL DELAY LINE NARROW FREQENCY RANGE DUE TO ANALOG DELAY LINE ANALOG DELAY ELEMENT: CURRENT STARVED DELAY ELEMENT SIMPLE CIRCUIT NON LINEAR RELATION BETWEEN CONTROLL VOLTAGE AND OUTPUT FREQUENCY Q CAN BE LINEARIZED BY USING A CURRENT MIRROR CIRCUIT IN SERIES WITH RESISTOR ADDITONAL CIRCUITORY REQUIRED DIGITAL DELAY ELEMENT: M9-M14 MAIN ELEMENT,M6-M9 CURRENT MIRROR, M1-M4 CONTROLL ADVANTAGE:16 DELAY STEPS DISADVANTAGE:COMPLEX CIRCUIT REFERENCE: USED IN DUAL LOOP DLL BY 1.8V POWER SUPPLY BASED ON 0.18µm PROCESS “A A Novel Low-Power Low Power and High High-Performance Performance Dual-Loop Dual Loop DLL with Linear Delay Element Element”,2008 2008 3. DELAY CELL USING DIFFERENTIAL AMPLIFIER: CHARACTERISTICS: M3 AND M4 ARE MADE WEAK TO SPEED UP SIGNAL TRANSITION M5 AND M6 IMPROVE THE DRIVING CAPABILITY M7 AND M8 ARE USED TO ADJUST THE DELAY ADVANTAGE: SIMPLE CIRCUITRY DISADVANTAGE: WEAK PMOS M3 AND M4 TEND TO SLOW DOWN THE SLEW RATE ADDITIONAL DUMMY CELLS HAVE TO BE INCLUDED AFTER EACH ELEMENT FOR EQUAL LOADING REFERENCE: USED TO GENERATE 8 MULTIPHASE OUTPUTS AND HENCE 8 DELAY ELEMENTS ARE REQUIRED TO GENERATE 0.5 5GHz WIDE RANGE MULTIPHASE DLL WITH A CALIBRATED 0 5-5GHz WIDE-RANGE CHARGE PUMP IN A 0.13µm CMOS PROCESS WITH A SUPPLY VOLTAGE OF 1.2V “A 0.5-5GHz Wide-Range Multiphase DLL With a Calibrated Charge Pump”,2007 4 PSEDUDO-NMOS 4. PSEDUDO NMOS VCDL: CHARACTERISTICS: PMOS USED AS A VARIABLE RESISTOR CONTROLLED BY Vctrl ADVANTAGE: REQUIRED DELAY CAN BE EASILY INTRODUCED VIA Vctrl DISADVANTAGE: AS RESISTANCE OF PMOS IS VARIABLE THE DUTY CYCLE WILL NOT BE 50% EXACT. HENCE EVEN NUMBER OF ELEMENTS SHOULD BE USED THUS INCREASING THE DELAY REFERENCE: “Voltage Controlled Delay Line with phase quadrature outputs for [0.9-4] GHz F-DLL dedicated to Zero-IF multistandard LO”,2009 5. ANALOG DELAY LOCKED LOOP: 8 IDENTICAL DELAY CELLS ARE CONNECTED IN SERIES TO BUILD UP A 3 BIT DELAY LINE AND THE DELAY CELL IS AS SHOWN: CHARACTERISTICS: INV_2 INV 2 AND MI FORM THE BASIC CURRENT STARVED INVERTER INV_1 AND INV_4 ARE ADDED TO GENERATE A STEEPER RAISING AND FALLING EDGE AND HENCE ACCURACY CAN BE IMPROVED ADVANTAGE: SIMPLE CIRCUITRY DISADVANTAGE: NON LINEARITY CAN BE A PROBLEM REFERENCE: Hybrid DPWM with Analog Delay Locked Loop Xuzhen Shen, Xiaobo Wu, and Jing Lu, Lin Qin, 2010 6. OTHER DELAY ELEMENTS: SINGLE ENDED DELAY FULLY DIFFERENTIAL DELAY CHARACTERISTICS: BETTER COMMON MODE NOISE REJECTION AND DUTY CYCLE DISTORTION FOR FULLY DIFFERENTIAL DELAY LEVEL TRANSLATION IS REQUIRED DEPENDENCE ON SELF BIASING TECHNIQUES Q REFERENCES: “DRAM circuit design”, Brent Keeth, R Jacob Baker, Brian Johnson, Feng Lin 4. CONCLUSION: VARIOUS DELAY ELEMENTS HAVE BEEN STUDIED AND THE USAGE OF THE TYPE OF DELAY ELEMENT DEPENDS ON THE APPLICATION IN WHICH IT IS PUT INTO USE VARIOUS FACTORS TO BE CONSIDERED WHILE CHOOSING THE DELAY ELEMENT CONSISTS OF POWER CONSUMPTIONM LAYOUT AREA, REDUCTION IN JITTER, COMPLEXITY AND SO ON 5. REFERENCES: 1. A 0.5–5-GHz Wide-Range Multiphase DLL With a Calibrated Charge Pump Chi-Nan Chuang, Student Member, IEEE, and Shen-Iuan Liu, Senior Member, IEEE,2007 2. A Novel Low‐Power and High‐Performance Dual‐Loop DLL with Linear Delay Element, M. Gharib, Department of Electrical Engineering of IUST, Iran University of Science & Technology,Tehran, Iran AND A. Abrishamifar, Department of Electrical Engineering of IUST, Iran University of Science & Technology, Tehran, Iran, 2008 3. Voltage Controlled Delay Line with phase quadrature outputs for [0.9-4] GHz F-DLL dedicated to Zero-IF multistandard LO Cédric Majek, Yann Deval, Hervé Lapuyade and Jean-Baptiste Bégueret IMS Laboratory, University of Bordeaux Bordeaux, France,2009 4. A Portable Digital DLL for High‐Speed CMOS Interface Circuits Bruno W. Garlepp, Kevin S. Donnelly, Associate Member, IEEE, Jun Kim, Pak S. Chau,,Jared L. Zerbe, Charles Huang, Chanh V. Tran, Clemenz L. Portmann, Member, IEEE, Donald Stark, Yiu‐Fai Chan, Member, IEEE, Thomas H. Lee, Member, IEEE, and Mark A. Horowitz,1998 5. Hybrid DPWM with Analog Delay Locked Loop Xuzhen Shen, Xiaobo Wu, and Jing Lu, Lin Qin, 2010 6. “DRAM circuit design”, Brent Keeth, R Jacob Baker, Brian Johnson, Feng Lin 7 CMOS circuit design, 7. design layout and simulation, simulation R Jacob Baker
