Chapter Overview. Memory Classification. Memory Architectures. The Memory Core. Periphery. Reliability. Memory
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1 SRAM Design
2 Chapter Overview Classification Architectures The Core Periphery Reliability
3 Semiconductor Classification RWM NVRWM ROM Random Access Non-Random Access EPROM E 2 PROM Mask-Programmed Programmable (PROM) SRAM FIFO FLASH DRAM LIFO Shift Register CAM
4 Architecture: Decoders M bits M bits N Words S 0 S 1 S 2 S N-2 S N_1 Word 0 Word 1 Word 2 Word N-2 Word N-1 Storage Cell A 0 A 1 A K-1 Decoder S 0 Word 0 Word 1 Word 2 Word N-2 Word N-1 Storage Cell Input-Output (M bits) Input-Output (M bits) N words => N select signals Too many select signals Decoder reduces # of select signals K = log 2 N
5 Array-Structured Architecture Problem: ASPECT RATIO or HEIGHT >> WIDTH 2 L-K Bit Line Storage Cell A K A K+1 A L-1 Row Decoder Word Line Sense Amplifiers / Drivers M.2 K Amplify swing to rail-to-rail amplitude A 0 A K-1 Column Decoder Selects appropriate word Input-Output (M bits)
6 Hierarchical Architecture Row Address Column Address Block Address Control Circuitry Block Selector Global Amplifier/Driver I/O Global Data Bus Advantages: 1. Shorter wires within blocks 2. Block address activates only 1 block => power savings
7 Timing: Definitions Read Cycle READ Read Access Read Access Write Cycle WRITE Data Valid Write Access DATA Data Written
8 Timing: Approaches MSB LSB Address Bus Row Address Column Address RAS CAS Address Bus Address Address transition initiates memory operation RAS-CAS timing DRAM Timing Multiplexed Adressing SRAM Timing Self-timed
9 Read-Write Memories (RAM) STATIC (SRAM) Data stored as long as supply is applied Large (6 transistors/cell) Fast Differential DYNAMIC (DRAM) Periodic refresh required Small (1-3 transistors/cell) Slower Single Ended
10 6-transistor CMOS SRAM Cell WL M2 M4 M5 Q Q M6 M1 M3
11 CMOS SRAM Analysis (Write) WL M4 M5 Q = 0 Q = 1 M6 M1 = 1 = 0 k nm6 V, ( DD V Tn ) V 2 DD V DD = k pm4, 2 8 ( V Tp ) V 2 DD V DD 2 8 (W/L) n,m (W/L) p,m4 k nm5, V V DD DD V Tn k 2 2 n, M1 ( V Tn ) = (W/L) n,m5 10 (W/L) n,m1
12 CMOS SRAM Analysis (Read) WL M4 M5 Q = 0 Q = 1 M6 M1 C bit C bit k nm5, V V DD DD V 2 2 Tn V 2 = k 2 nm1, ( V Tn ) DD 2 8 (W/L) n,m5 10 (W/L) n,m1 (supercedes read constraint)
13 6T-SRAM Layout M2 M4 Q Q M1 M3 M5 M6 GND WL
14 Resistance-load SRAM Cell WL R L R L M3 Q Q M4 M1 M2 Static power dissipation -- Want R L large Bit lines precharged to to address t p problem
15 Periphery Decoders Sense Amplifiers Input/Output Buffers Control / Timing Circuitry
16 Row Decoders Collection of 2 M complex logic gates Organized in regular and dense fashion (N)AND Decoder NOR Decoder
17 Dynamic Decoders Precharge devices GND GND WL 3 WL 3 WL 2 WL 2 WL 1 WL 1 WL 0 WL 0 φ A 0 A 0 A 1 A 1 A 0 A 0 A 1 A 1 φ Dynamic 2-to-4 NOR decoder 2-to-4 MOS dynamic NAND Decoder Propagation delay is primary concern
18 A NAND decoder using 2-input predecoders WL 1 WL 0 A 0 A 1 A 0 A 1 A 0 A 1 A 0 A 1 A 2 A 3 A 2 A 3 A 2 A 3 A 2 A 3 A 1 A 0 A 0 A 1 A 3 A 2 A 2 A 3 Splitting decoder into two or more logic layers produces a faster and cheaper implementation
19 4 input pass-transistor based column decoder A 0 A 1 2 input NOR decoder S 0 S 1 S 2 S 3 D dvantage: speed (t pd does not add to overall memory access time) only 1 extra transistor in signal path sadvantage: large transistor count
20 4-to-1 tree based column decoder A 0 A 0 A 1 A 1 D Number of devices drastically reduced Delay increases quadratically with # of sections; prohibitive for large decoders Solutions: buffers progressive sizing combination of tree and pass transistor approaches
21 Decoder for circular shift-register WL 0 WL 1 WL 2 φ φ φ φ φ φ R φ φ R φ φ R φ φ...
22 Sense Amplifiers t p = C V I av make V as small as possible large small Idea: Use Sense Amplifer small transition s.a. input output
23 Differential Sensing - SRAM PC y M3 M4 y EQ x M1 M2 SE M5 x x SE x WL i (b) Doubled-ended Current Mirror Amplifier SRAM cell i Diff. x Sense x Amp y y D D x y SE y x (a) SRAM sensing scheme. (c) Cross-Coupled Amplifier
24 Latch-Based Sense Amplifier EQ SE SE Initialized in its meta-stable point with EQ Once adequate voltage gap created, sense amp enabled with SE Positive feedback quickly forces output to a stable operating point.
25 Single-to-Differential Conversion WL x Diff. x cell S.A. + _ V ref y y How to make good V ref?
26 Address Transition Detection A 0 DELAY t d ATD ATD A 1 DELAY t d A N-1 DELAY t d...
27 Reliability and Yield
28 Open Bit-line Architecture Cross Coupling EQ WL 1 WL 0 WL D WL D WL 0 WL 1 C W C W C C C C Sense Amplifier C C C C
29 Folded-Bitline Architecture WL 1 WL 1 WL 0 WL 0 WL D WL D C W C x y... C C C C C C EQ Sense Amplifier C x y C W
30 Transposed-Bitline Architecture " C cross (a) Straightforward bitline routing. SA " C cross SA (b) Transposed bitline architecture.
31 Alpha-particles α-particle WL n + SiO 2 1 particle ~ 1 million carriers
32 Yield Yield curves at different stages of process maturity (from [Veendrick92])
33 Redundancy Redundant columns Redundant rows Array Row Address Row Decoder : Fuse Bank Column Decoder Column Address
34 Semiconductor Trends Size as a function of time: x 4 every three years
35 Semiconductor Trends Increasing die size factor 1.5 per generation Combined with reducing cell size factor 2.6 per generation
36 Semiconductor Trends Technology feature size for different SRAM generations
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