gain cell embedded dram for ultra-low power … 6, 2015 1 gain cell embedded dram for ultra-low...
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May 6, 2015 1
Gain Cell Embedded DRAM for Ultra-Low Power Applications at scaled CMOS Nodes
May 6, 2015
Robert Giterman
EnICS Labs Nanoelectronics Program
Faculty of Engineering, Bar-Ilan University, Israel
May 6, 2015 2
Increasing Need for Embedded Memories in VLSI SoCs
• Memories often consume >50% of area & power
• 1st point of failure under voltage scaling
• Limit yield
Intel Xeon
Intel AMD Opteron 6300
May 6, 2015 3
Evolution of Total Cache Size Over Time
www.anandtech.comsource:
2MB
10MB
5X in 4 years
50x increase in 25 years [ITRS’11]
May 6, 2015 4
The 6T SRAM Bit Cell
• Several standby leakage paths.
• Dense, symmetric layout, but still six transistors.
• Supply voltage limited due to ratioed operation.
• Single-ported.
May 6, 2015 5
Advantages and Drawbacks of Gain Cells
In light of technology and voltage scaling, gain-cells have several advantages over conventional 6T SRAM and 1T-1C eDRAM:
• Smaller cell size than SRAM, less bitcell leakage
• Compared to 1T-1C eDRAM:
– Logic-compatible, i.e., no special processing steps, and no extra cost.
– Non-destructive read operation.
• Naturally two-port.
• Optimize for read-ability AND write-ability.
Drawbacks:
• Dynamic. Energy-costly refresh cycles?!
• May have lower retention (refresh + leakage) power than SRAM (leakage only)
Chun, VLSI’09
SRAM
Gain-cells
Trench cap Stacked caps
Kang, McGraw-Hill’03
May 6, 2015 6
Gain Cells : Basic Topologies
MW MS
MR
RWLWWL
WB
L
RB
L
3T Gain Cell
MRMW
RWLWB
L
WWL
RB
L
2T Gain Cell
Somasekhar, et al. JSSC 2009 Chun, et al. JSSC 2011
• Dynamic memory cell, built from MOS transistors (& MOS caps), write port (WWL & WBL), storage cap, and read port (RWL & RBL).
May 6, 2015 8
Main Leakage Components • Conventional 2T gain cell
implementations in sub-100nm technologies display very low retention times, due to substantially higher leakage currents.
• Depending on the type of write transistor (WT), one of the data levels has a much higher retention time than the other (‘1’ for a PMOS WT, ‘0’ for a NMOS WT).
Level ‘1’ is stored
Level ‘0’ is stored
May 6, 2015 9
Main Leakage Components • Conventional 2T gain cell
implementations in sub-100nm technologies display very low retention times, due to substantially higher leakage currents.
• Depending on the type of write transistor (WT), one of the data levels has a much higher retention time than the other (‘1’ for a PMOS WT, ‘0’ for a NMOS WT).
May 6, 2015 10
4T Gain Cell • The ‘weaker’ data level is strengthened by the addition of a buffer node (BN) and a
feedback device to the basic configuration, which conditionally discharges node BN according to the stored data level.
• The data retention time (DRT) estimation is higher by an order of magnitude than that of a conventional 2T gain cell.
May 6, 2015 11
4T Gain Cell • The ‘weaker’ data level is strengthened by the addition of a buffer node (BN) and a
feedback device to the basic configuration, which conditionally discharges node BN according to the stored data level.
• The data retention time (DRT) estimation is higher by an order of magnitude than that of a conventional 2T gain cell.
• The proposed gain cell layout is only 60% of a redrawn 6T SRAM cell in the same 65nm node.
May 6, 2015 12
Comparison With other Embedded Memory Options
May 6, 2015 13
Questions and Open Discussion