1. 4 BIT Arithmetic And Logic Unit (ALU) Philips 74HC/HCT181 Brijesh Chavda Meet Aghera Mrugesh Chandarana Sandip Patel Adviser David Parent Date: 12/03/05

2. Abstract Goal is to design 4-bit ALU driving up to 25fF. Perform arithmetic operations like A+B, A+B’, A-1, A+(AB’), AB-1. Perform Logical operations like Ex-OR, Compare, AND, NAND, NOR, OR plus 10 other logic operations. The data must be transferred at clock rate of 200MHz. Maximum area is 323 X 760 µm².

3. Introduction ALU is a building block of several complex circuits. The designed ALU is able to handle two 4 bit inputs to produce required output based on the output selector lines. Challenging to design 16 logic level circuit working with 5ns delay. Using this knowledge and experience, we can move on to designing more complex integrated circuits.

4. Design Flows Calculate the longest path delay from the circuit. Create schematic and layout for INV, NAND2 and NAND3. Combine these three building blocks to create the different blocks of the circuit. Test the schematic logic of all the modules. Assembled all the modules and flip-flops. Run DRC, extracted and LVS check to verify the design. Analyze the circuit power and timing using Analog Affirma.

5. Block diagram of Philips 74HC/HCT181

6. Longest Path Calculation CELLBITWN LoadWP LoadCint Cg or Cin of loadCg+Cint  phl  plh WNWP (cm) FF sscm INV_A160.00E+00 5.00E-152.50E-143.00E-149.00E-11 3.93E-047.11E-04 NAND2_A153.93E-047.11E-045.00E-151.85E-142.35E-142.00E-10 3.94E-043.51E-04 INV_B143.94E-043.51E-045.00E-151.25E-141.75E-141.00E-10 2.06E-043.71E-04 NAND2_B132.06E-043.71E-045.00E-159.68E-151.47E-142.00E-10 2.75E-042.45E-04 NAND2_C122.75E-042.45E-045.00E-158.72E-151.37E-142.00E-10 2.62E-042.33E-04 NAND2_D112.62E-042.33E-045.00E-158.31E-151.33E-142.00E-10 2.56E-042.28E-04 NAND2_E102.56E-042.28E-045.00E-158.13E-151.31E-142.00E-10 2.54E-042.26E-04 INV_C92.54E-042.26E-045.00E-158.06E-151.31E-141.00E-10 1.60E-042.88E-04 NAND3_A81.60E-042.88E-045.00E-157.51E-151.25E-142.50E-10 8.52E-045.02E-04 NAND2_F78.52E-045.02E-045.00E-152.27E-142.77E-142.00E-10 4.51E-044.01E-04 INV_D64.51E-044.01E-045.00E-151.43E-141.93E-141.00E-10 2.24E-044.05E-04 NAND2_G52.24E-044.05E-045.00E-151.06E-141.56E-142.00E-10 2.87E-042.55E-04 INV_E42.87E-042.55E-045.00E-159.10E-151.41E-141.00E-10 1.70E-043.08E-04 NAND2_H31.70E-043.08E-045.00E-158.02E-151.30E-142.00E-10 2.53E-042.25E-04 NAND3_B22.53E-042.25E-045.00E-158.01E-151.30E-142.35E-10 1.85E-041.63E-04 INV_F11.85E-041.63E-045.00E-155.84E-151.08E-149.00E-11 1.60E-042.89E-04 2.67E-09

7. Schematic of 4-Bit ALU

8. Layout of the circuit

9. Verification – LVS Check

10. Final TB

11. Logic Simulation

12. Lesson learned Follow the steps and guideline given by Dr. Parent How to design a compact circuit. How to fix the LVS errors. Optimize transistor size to meet out specifications. How to use cadence tools.

13. Acknowledgements Thanks to Professor David Parent for his guidelines and help throughout the project. Thanks to Cadence Design Systems for VLSI Lab.