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COMP541 Memories II: DRAMs

COMP541 Memories II: DRAMs. Montek Singh Mar 2, 2010. Topics. Random-Access Memory Dynamic. Dynamic RAM. Capacitor can hold charge Transistor acts as gate No charge = ‘0’ Can connect switch & add charge to store a ‘1’ Then disconnect switch Can read by connecting switch Sense amps.

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COMP541 Memories II: DRAMs

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  1. COMP541Memories II:DRAMs Montek Singh Mar 2, 2010

  2. Topics • Random-Access Memory • Dynamic

  3. Dynamic RAM • Capacitor can hold charge • Transistor acts as gate • No charge = ‘0’ • Can connect switch & add charge to store a ‘1’ • Then disconnect switch • Can read by connecting switch • Sense amps

  4. DRAM Bit Cell • Contrast w/ SRAM SRAM bit cell: DRAM bit cell: 5-<4>

  5. Hydraulic Analogy Storage Full (1) Empty (0) Pump fills tank to 1 value Pump drains tank to 0 value

  6. Reading Outside water begins at intermediate level (black wavy line) Tank had a 1 value – raises water level Tank had a 0 value – lowers water level

  7. DRAM Characteristics • Destructive Read • When cell read, charge removed • Must be restored after a read • Refresh • Also, there’s steady leakage • Charge must be restored periodically

  8. DRAM Logical Diagram

  9. DRAM Read Signaling • Lower pin count by using same pins for row and column addresses Delay until data available

  10. DRAM Write Timing

  11. DRAM Refresh • Many strategies • Logic on chip • Here a row counter

  12. Timing • Say need to refresh every 64ms • Distributed refresh • Spread refresh out evenly over 64ms • Say on a 4Mx4 DRAM, refresh window for row 64ms/4096=15.6 us • Total time spent is 0.25ms, but spread • Burst refresh • Same 0.25ms, but all at once • May not be good in a computer system • Refresh takes low % of total time

  13. Bidirectional Lines • Many chips have one set of data pins • Used as input for write • As output for read • Tri-state • Makes sense because don’t need both at once

  14. Page Mode DRAM • DRAMs made to read & write blocks • Example • Assert RAS, leave asserted • Assert CAS multiple times to read sequence of data • Similar for writes

  15. Synchronous DRAM (SDRAM) • Has a clock • Common type in PCs late-90s • Typical DRAMs still synchronous • Multiple banks • Pipelined • Start read in one bank after another • Come back and read the resulting values one after another

  16. Read with Autoprecharge

  17. Basic Mode of Operation Address Row Column RAS CAS Data Data • Slowest mode • Uses only single row and column address • Row access is slow (60-70ns) compared to column access (5-10ns) • Leads to three techniques for DRAM speed improvement • Getting more bits out of DRAM on one access given timing constraints • Pipelining the various operations to minimize total time • Segmenting the data in such a way that some operations are eliminated for a given set of accesses

  18. Nibble (or Burst) Mode RAS ---- ---- ---- ---- ---- ---- ---- ---- ---- CAS CAS CAS CAS RA CA D1 D2 D3 D4 • Several consecutive columns are accessed • Only first column address is explicitly specified • Rest are internally generated using a counter

  19. Fast Page Mode RAS ---- ---- ---- ---- ---- ---- ---- ---- ---- CAS CAS CAS CAS RA CA1 CA2 CA3 CA4 D1 D2 D3 D4 • Accesses arbitrary columns within same row • Static column mode is similar

  20. EDO Mode RAS ---- ---- ---- ---- ---- ---- ---- ---- ---- CAS CAS CAS CAS CAS CAS CAS RA CA1 CA2 CA3 CA4 CA5 CA6 CA7 D1 D2 D3 D4 D5 D6 • Arbitrary column addresses • Pipelined • EDO = Extended Data Out • Has other modes like “burst EDO”, which allows reading of a fixed number of bytes starting with each specified column address

  21. DRAM on NEXYS2 Board • Relatively small at 128Mbits • 8M X 16 • Internal refresh • Supports pipelining • Bidirectional data lines, full set of address lines • Async (right) and sync modes • Page, burst • 70ns read cycle time • http://download.micron.com/pdf/datasheets/psram/128mb_burst_cr1_5_p26z.pdf

  22. DDR DRAM • Double Data Rate SDRAM • Transfers data on both edges of the clock • Currently popular • Attempt to alleviate the pinout problems

  23. RAMBUS DRAM (RDRAM) • Another attempt to alleviate pinout limits • Many (16-32) banks per chip • Made to be read/written in packets • Up to 1200MHz bus speeds • XDR – 8 bits per clock, 16-bit wide bus, 6.4GB • But DDR doing very well also

  24. DRAM Controllers • Very common to have chip/module that controls memory • Handles banks • Handles refresh • Multiplexes column and row addresses • RAS and CAS timing • Northbridge on PC chip set

  25. Conclusions • RAMs with different characteristics • For different purposes • Static RAM • Simple to use, small, expensive • Fast, used for cache • Dynamic RAM • Complex to interface, largest, cheap • Needs periodic refresh

  26. Links • Ram Guides (not very technical) • http://arstechnica.com/paedia/storage.html • DRAM on XSA-100 board • http://www.hynix.co.kr/datasheet/pdf/dram/(2)HY57V281620A(L)T-I.PDF

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