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Penn ESE370 Fall2012 -- DeHon 1 ESE370: Circuit-Level Modeling, Design, and Optimization for Digital Systems Day 28: November 16, 2012 Memory Periphery
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Today Memory Periphery Driving Decode Sensing Energy (time permitting) Penn ESE370 Fall2012 -- DeHon 2
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Bus Drivers Penn ESE370 Fall2012 -- DeHon 3
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Memory Bank Penn ESE370 Fall2012 -- DeHon 4
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Tristate Driver Penn ESE370 Fall2012 -- DeHon 5
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Tri-State Drivers Penn ESE370 Fall2012 -- DeHon 6
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Memory Bank Penn ESE370 Fall2012 -- DeHon 7
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Row Select Logically a big AND –May include an enable for timing in synchronous Penn ESE370 Fall2012 -- DeHon 8 How many transistors (per address bit)?
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How tall is a row? Side length for cell of size: –1000 2 – 600 2 – 100 2 Penn ESE370 Fall2012 -- DeHon 9
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10 How tall is an AND? Penn ESE370 Fall2012 -- DeHon 2 6 6 3 2 2 10
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Row Select How can we do better? –Area –Delay –Match to pitch of memory row Penn ESE370 Fall2012 -- DeHon 11
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Row Select Compute inversions outside array –Just AND appropriate line (bit or /bit) Penn ESE370 Fall2012 -- DeHon 12
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Row Select Share common terms Multi-level decode Penn ESE370 Fall2012 -- DeHon 13
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Row Select Same number of lines Half as many AND inputs Penn ESE370 Fall2012 -- DeHon 14
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Row Select: Precharge NAND Penn ESE370 Fall2012 -- DeHon 15
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Row Select: Precharge NOR Penn ESE370 Fall2012 -- DeHon 16
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Sensing Penn ESE370 Fall2012 -- DeHon 17
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Penn ESE370 Fall2012 -- DeHon 18 SRAM Memory bit
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Simulation W access =20 Penn ESE370 Fall2012 -- DeHon 19
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Sense Small Swings What do we have to worry about? Penn ESE370 Fall2012 -- DeHon 20
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Sense Small Swings Variation Common mode noise Penn ESE370 Fall2012 -- DeHon 21
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Differential Sense Amp Goal: –Reject common shift Penn ESE370 Fall2012 -- DeHon 22
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Differential Sense Amp Penn ESE370 Fall2012 -- DeHon 23
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What doe this do? Output when: –In=Gnd? –In=Vdd? –Transfer curve? Penn ESE370 Fall2012 -- DeHon 24
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“Inverter” Input high –Ratioed like grounded P Input low –Pulls itself up –Until V dd -V TP Penn ESE370 Fall2012 -- DeHon 25
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DC Transfer Function Penn ESE370 Fall2012 -- DeHon 26
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Differential Sense Amp Penn ESE370 Fall2012 -- DeHon 27
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Diffamp Transfer Function in=/in, looks like “inverter” Deliberately low gain in mid region Penn ESE370 Fall2012 -- DeHon 28
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Differential Sense Amp “Inverter” output controls PMOS for second inverter Sets PMOS operating point –current Penn ESE370 Fall2012 -- DeHon 29
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Differential Sense Amp What happens when o In=/in ? o /in > in? o /in < in? Penn ESE370 Fall2012 -- DeHon 30
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Differential Sense Amp View: –Current mirror –Biases where inverter operating Penn ESE370 Fall2012 -- DeHon 31
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Differential Sense Amp View: – adjusting the pullup load resistance –Changing the trip point for “inverter” Penn ESE370 Fall2012 -- DeHon 32
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DC Transfer /in with in=0.5V Penn ESE370 Fall2012 -- DeHon 33
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DC Transfer Various in Penn ESE370 Fall2012 -- DeHon 34
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DC Transfer Various in What is trip point when: In=0.3V? In=0.4V? In=0.5V? In=0.6V? In=0.7V? Penn ESE370 Fall2012 -- DeHon 35
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After Inverter Penn ESE370 Fall2012 -- DeHon 36
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Ramp 50mV Offset Penn ESE370 Fall2012 -- DeHon 37
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Closeup 50mV Offset Penn ESE370 Fall2012 -- DeHon 38
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Connect to Column Equalize lines during precharge Penn ESE370 Fall2012 -- DeHon 39
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Singled-Ended Read Penn ESE370 Fall2012 -- DeHon 40
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5T SRAM Penn ESE370 Fall2012 -- DeHon 41
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Single Ended Given same problems –How sense small swing on single-ended case? Penn ESE370 Fall2012 -- DeHon 42
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Single Ended Need reference to compare against Want to look just like bit line Equalize with bit line Penn ESE370 Fall2012 -- DeHon 43
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Split Bit Line Split bit-line in half Precharge/equalize both Word in only one half –Only it switches Amplify difference Penn ESE370 Fall2012 -- DeHon 44
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Open Bit Line Architecture For 1T DRAM Add dummy cells Charge dummy cells to V dd /2 “read” dummy in reference half Penn ESE370 Fall2012 -- DeHon 45
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Memory Bank Penn ESE370 Fall2012 -- DeHon 46
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Energy (Time Permitting) Penn ESE370 Fall2012 -- DeHon 47
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Single Port Memory What fraction is involved in a read/write? What are most cells doing on a cycle? Reads are slow –Cycles long lots of time to leak Penn ESE370 Fall2012 -- DeHon 48
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ITRS 2009 45nm Penn ESE370 Fall2012 -- DeHon 49 High Performance Low Power I sd,leak 100nA/ m50pA/ m I sd,sat 1200 A/ m560 A/ m C g,total 1fF/ m0.91fF/ m V th 285mV585mV C 0 = 0.045 m × C g,total
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High Power Process V=1V d=1000 =0.5 W access =W buf =2 Full swing for simplicity C sc = 0 –(just for simplicity, typically <C load ) BL: C load =1000C 0 ≈ 45 fF = 45×10 -15 F W N = 2 I leak = 9×10 -9 A P= (45×10 -15 ) freq + 1000×9×10 -9 W Penn ESE370 Fall2012 -- DeHon 50
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Relative Power P= (45×10 -15 ) freq + 1000×9×10 -9 W P= (4.5×10 -14 ) freq + 9×10 -6 W Crossover freq<200MHz How partial swing on bit line change? Reduce dynamic energy Increase percentage in leakage energy Reduce crossover frequency Penn ESE370 Fall2012 -- DeHon 51
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Consequence Leakage energy can dominate in large memories Care about low operating (or stand-by) power Use process or transistors with high V th –Reduce leakage at expense of speed Penn ESE370 Fall2012 -- DeHon 52
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Idea Minimize area of repeated cell Compensate with periphery –Amplification (restoration) Match periphery pitch to cell row/column –Decode –Sensing –Writer Drivers Penn ESE370 Fall2012 -- DeHon 53
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Admin Monday: in Detkin Lab –Read lab2 assignment before coming to class Tuesday: Proj2 Milestone due Wednesday: Lecture Thursday/Friday: Thanksgiving Holiday Penn ESE370 Fall2012 -- DeHon 54
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