1. Final Design Report�Image Memory – VLSI Senior Design Project Brian Kociuba & Michael Rainville
December 14, 2004
ECE 715
2. Table of Contents Introduction
Goals Achieved
Design
Cell Design
Cell Array
Addressing
The data bus
System Design
Testing
DRC & LVS
Simulations
Timeline
Conclusion
3. Introduction Image memory for fingerprint recognition and matching system
Interfaces with fingerprint reader interface on input
Interfaces with fingerprint matching algorithm interface on output
4. Introduction Memory stores 128 x 128 pixel grey-scale image
16,384 memory locations addressed by a 14 bit wide address code
Each location stores 8 bits to represent a shade of grey
Information for this report presented in a “bottom-up” method
5. Achieved Goals Maintains stable operation with write/read pulse widths of 10ns and under
Write and read addressing is smooth
Output and input match
Data output is smooth and responsive to reads
Data bus is shared and well isolated
Physical layout fits on pad frame
Low power consumption ~ 14.86nW over 200ns span
6. Design: Cell Design 6T SRAM design
PMOS transistor size: 3 lambda(W) x 3 lambda(L)
NMOS transistor size: 8 lambda(W) x 2 lambda(L)
NMOS word line transistor size: 4 lambda(W) x 2 lambda(L)
Cell size: 55 lambda(X) x 50 lambda(Y)
7. Design: Cell Design Chosen transistor size ratios allow for proper latching and switching times
Cell does not force data line to 5V, just about 3.5V to allow for faster switching
Data is internally inverted to create bit and notbit lines
8. Design: Cell Array One addressable location is eight cells wide
Row and column decoder signals turn word line high by turning on an AND gate
9. Design: Array Design Custom AND gate activates a line of metal2 to turn word line high
Transistor widths are similar to the ADK AND gate design but allow for easier routing
This allows for an entire byte to addressed at once
10. Design: Array Design Memory array is a group of cascaded and flipped location arrays
A small 4 x 4 array is used on the fabricated chip
Each bit line is connected to a common bus of lines at the top of the array
Addressing lines are routed through the array without breaks or vias
11. Design: Array Design
12. Design: Array Design
13. Design: Addressing Custom decoders used (AND type)
2 bit in ? 4 line out decoders
Special delay incorporated into row decoder to fix an addressing line spike problem (0.5ns)
AND gates used for enable decoding
14. Design: Addressing
15. Design: Addressing
16. Design: Addressing
17. Design: The Data Bus The data bus consists of:
Write logic
Precharge logic
Sense amps
Output buffers
Each section explained piece by piece
This portion of circuit is critical for data accuracy, verification and cleanliness
Eight bits wide
18. Design: Write Logic The write logic is the input of the system
Data is buffered
One line is split into two, bit and inverted bit
This is the only time we used ADK components in the physical layout
19. Design: Write Logic
20. Design: Precharge Logic This array of logic charges all lines to 5 volts when activated just before a read operation
Each cluster of PMOS transistors switches on a logic zero
Each precharge “cell” consists of two “charging” transistors of width 10 lambda and an “equalizer”
21. Design: Precharge Logic
22. Design: Sense Amp Logic Sense amps use a threshold switching voltage to boost or lower signal to its proper zero of five volt level
The sense amp input is bit and inverted bit from the cell read from on its line
The output is equal to bit
One output leaves each sense amp
23. Design: Sense Amp Logic
24. Design: Output Buffer Logic The output buffers are used to clean signals on the output lines after the sense amps
Each output buffer is a double inverter
This custom setup has transistor geometries similar to that of an ADK buffer (one width is different)
This is essentially a double inverter with the output inverter having “double-wide” transistors to drive the output
25. Design: Output Buffer Logic
26. Design: System Design The system was created piece by piece
Each piece passed DRC, LVS, and timing tests separately
After a sub-module passed its tests it was added to the system
The system layout and routing was fully custom (besides the write logic)
VDD and GND metal routed through system
27. Design: System Design
28. Design: System Design
29. Design: System Design
30. Testing The system and its pieces have been tested extensively in Eldo
Custom pulses were created to test different scenarios that the system might face
Power consumption was calculated in Eldo to be 14.86nW
Eldo simulations and an LVS check are shown in the next slides
31. Testing The system layout passes LVS check with its logic
It also passes DRC rules check
32. Testing
33. Testing Decoder testing was necessary to determine functionality of decoders
34. Testing The next step was to address cells with the decoders
35. Testing We tested one data line during initial data testing
This line was “D0”
A bit was written to an addressed cell
36. Testing The bit value was read from a cell on the “D0” data line to verify its cleanliness and accuracy to the input
37. Testing Another data line was tested the same way as “D0”
Data was written to and read from the cell successfully
Different Combinations of data were written to the cells
38. Timeline
39. Timeline By December 20th:
Set small design on padframe
Scale up design for large project
Verify implementation
Test large design in Mach TA
