1. ECE2030 Introduction to Computer Engineering Lecture 17: Memory and Programmable Logic
Prof. Hsien-Hsin Sean Lee
School of Electrical and Computer Engineering
Georgia Tech

2. Memory Random Access Memory (RAM) Read-Only Memory (ROM)
Contrary to Serial Access Memory (e.g. Tape)
Static Random Access Memory (SRAM)
Data stored so long as Vdd is applied
6-transistors per cell
Faster
Differential
Dynamic Random Access Memory (DRAM)
Require periodic refresh
Smaller (can be implemented with 1 or 3 transistor)
Slower
Single-Ended
Can be read and written
Typically, addressable at byte granularity
Read-Only Memory (ROM)

3. Block Diagram of Memory
N-bit Data Input
(for Write) N
K-bit address lines
Memory Unit K
Read/Write
2k words
N-bit per word
Chip Enable N
N-bit Data Output
(for Read)
Example: 2MB memory, byte-addressable
N = 8 (because of byte-addressability)
K = 21 (1 word = 8-bit)

4. Static Random Access Memory (SRAM)
Wordline (WL)
BitLine
BitLine
Typically each bit is implemented with 6 transistors (6T SRAM Cell)
During read, the bitline and its inverse are precharged to Vdd (1) before set WL=1
During write, put the value on Bitline and its inverse on Bitline_bar before set WL=1

5. Dynamic Random Access Memory (DRAM)
Wordline (WL)
Bitline
1-transistor DRAM cell
During a write, put value on bitline and then set WL=1
During a read, precharge bitline to Vdd (1) before assert WL to 1
Storage decays, thus requires periodic refreshing (read-sense-write)

6. Memory Description Capacity of a memory is described as
# addresses x Word size
Examples:
Memory
# of addr
# of data lines
# of addr lines
# of total bytes
1M x 8
1,048,576 8 20
1 MB
2M x 4
2,097,152 4 21
1K x 4
1024 10
512 B
4M x 32
4,194,304 32 22
16 MB
16K x 64
16,384 64 14
128 KB

7. How to Address Memory 4x8 Memory 2-to-4 Decoder A0 1 2 A1 3 CS Chip
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A0 1
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit 2
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A1 3
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit CS
Chip
Select D7 D6 D5 D4 D3 D2 D1 D0

8. How to Address Memory 4x8 Memory 2-to-4 Decoder A0=1 1 2 A1=0 3 CS
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
A0=1 1
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit 2
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
A1=0 3
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit CS
Chip
Select=1 D7 D6 D5 D4 D3 D2 D1 D0
Access address = 0x1

9. Use 2 Decoders 8x4 Memory 2-to-4 Decoder Row A1 1 2 A2 3 CS 1 Chip
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A1 1
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit 2
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A2 3
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit CS
Tristate
Buffer
(read) D0 D1 D2 D3
Chip
Select 1 CS
1-to-2 Decoder Column Decoder A0

10. Tristate Buffer Similar to Transmission GateEn
Input
Output En
Input
Output
Output En
Input
Vdd
CMOS circuit
Similar to Transmission Gate
Could amplify signal (in contrast to a TG)
Typically used for signal traveling, e.g. bus

11. Bi-directional Bus using Tri-state Buffer
(control data flow for read/write) A
Input/Output B

12. Read/Write Memory 8x4 Memory A1 1 2-to-4 Row Decoder 2 A2 3 CS
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A1 1
2-to-4
Row
Decoder
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit 2
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A2 3
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit CS
Rd/Wr = 0 D0 D1 D2 D3 1
Chip
Select = 0 CS
1-to-2 Column Decoder A0

13. Read/Write Memory 8x4 Memory A1 1 2-to-4 Row Decoder 2 A2 3 CS
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A1 1
2-to-4
Row
Decoder
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit 2
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit A2 3
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit
1-bit CS
Rd/Wr = 1 D0 D1 D2 D3 1
Chip
Select = 1 CS
1-to-2 Column Decoder A0

14. Building Memory in Hierarchy
Design a 1Mx8 using 1Mx4 memory chips D7 D6 D5 D4
A19
A18
1Mx4
R/W CS
A17 A0 CS D3 D2 D1 D0
A19
A18
A17 A0
1Mx4
R/W CS

15. Building Memory in Hierarchy
Design a 2Mx4 using 1Mx4 memory chips
A19
A18
A17 A0
1Mx4
R/W CS D3 D2 D1 D0
Note that 1-to-2
decoder is the wire
itself (or use
an inverter)
1-to-2
Decoder CS 1
A20
A19
A18
A17 A0
1Mx4
R/W CS

16. Building Memory in Hierarchy
Design a 2Mx8 using 1Mx4 memory chips
A19
A18
A17 A0
1Mx4 CS
R/W D7 D6 D5 D4 D3 D2 D1 D0
A20
1-to-2
Decoder CS 1

17. Memory Model
32-bit address space can address up to 4GB (232) different memory locations
Flat Memory Model
0x0A
0xB6
0x41
0xFC
Lower
Memory
Address 0x
Higher 0x 0x 0x
0xFFFFFFFF
0x0D

18. Endianness [Danny Cohen 91]
Byte ordering  How a multiple byte data word stored in memory
Endianness (from Gulliver’s Travels)
Big Endian
Most significant byte of a multi-byte word is stored at the lowest memory address
e.g. Sun Sparc, PowerPC
Little Endian
Least significant byte of a multi-byte word is stored at the lowest memory address
e.g. Intel x86
Some embedded & DSP processors would support both for interoperability

19. Endianness Examples
Store 0x at address 0x0000, byte-addressable
Lower
Memory
Address
Lower
Memory
Address
0x0000
0x87
0x0000
0x21
0x0001
0x65
0x0001
0x43
0x0002
0x43
0x0002
0x65
0x0003
0x21
0x0003
0x87
Higher
Memory
Address
Higher
Memory
Address
BIG ENDIAN
LITTLE
ENDIAN

20. Memory Allocation (Little Endian)
.data
.globl declare
declare:
.align 0
.word 511
.byte 14
.align 2
.byte 14
.word 0x0B1E8143
.ascii “GAece”
.half 10
.word 0x2B1E8145
.space 1
.byte 52
.align 1
.byte 16
.space 2
.byte 67
0xFF e
------
0x34 1c
0x01 1 f
------ 1d
------
0x00
0x47
0x10 2 10 1e 3
0x00 11
0x41 1f 4
0x0E
0x65 12 20
------ 13
0x63
0x43 5 21 6
------
0x65 14
.align N: Align next datum
on a 2n byte boundary
.align 0: turn off automatic
alignment for .half, .word,
.float, and .double till the
next .data directive
.word: 4 bytes
.half: 2 bytes
.byte: 1 byte
.space: 1-byte space
.ascii: ASCII code (American
Standard Code for
Information Interchange)
------ 15
0x0A 7
0x0E 8 16
0x00
0x43
0x45 9 17 a
0x81 18
0x81 b
0x1E
0x1E 19
0x0B
0x2B c 1a d
------ 1b

21. Read Only Memory (ROM) “Permanent” binary information is stored
Non-volatile memory
Power off does not erase information stored
ROM
K-bit address lines
N-bit Data Output
2k words
N-bit per work K N

22. 32x8 ROM 32x8 ROM 5 8 Each represents 32 wires A4 A3 5-to-32 DecoderA4 1 A3 2
5-to-32
Decoder 3 A2 A1 28 A0 29 30 31
Fuse can be
implemented as
a diode or a
pass transistor D7 D6 D5 D4 D3 D2 D1 D0

23. Programming the 32x8 ROM D7 D6 D5 D4 D3 D2 D1 D0 A4 A3 A2 A1 A01 … 1 2 29 30 31 D7 D6 D5 D4 D3 D2 D1 D0 A4 A3 A2 A1 A0
5-to-32
Decoder

24. Example: Lookup Table
Design a square lookup table for F(X) = X2 using ROM X
F(X)=X2 1 2 4 3 9 16 5 25 6 36 7 49 X
F(X)=X2
000
000000
001
000001
010
000100
011
001001
100
010000
101
011001
110
100100
111
110001

25. Square Lookup Table using ROM1 X
F(X)=X2
000
000000
001
000001
010
000100
011
001001
100
010000
101
011001
110
100100
111
110001 X2
3-to-8
Decoder 2 3 X1 4 X0 5 6 7 F5 F4 F3 F2 F1 F0

26. Square Lookup Table using ROM1 X
F(X)=X2
000
000000
001
000001
010
000100
011
001001
100
010000
101
011001
110
100100
111
110001 X2
3-to-8
Decoder 2 3 X1 4 X0 5 6 7
Not Used
= X0 F5 F4 F3 F2 F1 F0

27. Square Lookup Table using ROM1 X
F(X)=X2
000
000000
001
000001
010
000100
011
001001
100
010000
101
011001
110
100100
111
110001 X2
3-to-8
Decoder 2 3 X1 4 X0 5 6 7 F5 F4 F3 F2 F1 F0

28. Classifying Three Basic PLDs
Fixed AND plane
(decoder)
Programmable
OR plane
Connections
(Programmable) Read-Only Memory (ROM)
INPUT
OUTPUT
Programmable
OR plane
Connections
Programmable Logic Array (PLA)
AND plane
INPUT
OUTPUT
Programmable
AND plane
Fixed
OR plane
Programmable Array Logic (PAL) Devices
PAL: trademark of AMD, use PAL as an adjective or
expect to receive a letter from AMD’s lawyers
INPUT
OUTPUT
F/F

29. Programmable Logic Array (PLA)
OR Plane B C
Programmable
AND Plane C C B B A A F2

30. Example using PLA

31. Example using PLA A B C AB AC BC
A B C C C B B A A F1 F2

32. PAL Device A A B B IO1 IO2 IO1 IO1 IO1 Programmable AND Plane A IO2 B
Fixed
OR Plane

33. PAL Device Design ExampleB B C C D D
IO1
IO1
IO1
Not programmed A
IO2 B

34. CPLD and FPGA [Brown&Rose 96]
Complex Programmable Logic Device (CPLD)
Multiple PLDs (e.g. PALs, PLAs) with programmable interconnection structure
Pioneered by Altera
Field-Programmable Gate Array (FPGA)
High logic capacity with large distributed interconnection structure
Logic capacity  number of 2-input NAND gates
Offers more narrow logic resources
CPLD offers logic resources w/ a wide number of inputs (AND planes)
Offer a higher ratio of Flip-flops to logic resources than CPLD
HCPLD (High Capacity PLD) is often used to refer to both CPLD and FPGA

35. CPLD structure Logic block PLD PLD PLD PLD I/O block PLD PLD PLD PLD
Interconnects

36. FPGA Structure
Logic block
I/O block
Interconnects

37. FPGA Programmability Floating gate transistor
Used in EPROM and EEPROM
SRAM-controlled switch  Control
Pass transistors
Multiplexers (to determine how to route inputs)
Antifuse
Similar to fuse
Originally an Open-Circuit
One-Time Programmable (OTP)