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1 Encoding Logic for 5 bit Analog to Digital Converter By:Kaneez Fatimah Ranjini Bhagavan Padmavathy Desikachari Veena Jain Advisor: Dr. David Parent Date: 05/17/2004
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2 Agenda Abstract Introduction - Why this Project -ADC Encoding Logic Project Details Results Cost Analysis Summary
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3 Abstract Designed Encoding logic for 5 bit Analog to Digital Converter without Sample and Hold operation Used AMI06 process Clock frequency = 200 MHz Power ~ 3mW@200MHz
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4 Why this Project This project is based on IEEE Research paper on enhanced ADC logic without sample & hold Needed interpolation from basic 8 bit circuit to 5 bit logic Dr. Parent suggested to implement this idea
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5 Encoding Logic The design of converter is optimized to minimize the effect of errors that may occur in ADC architecture without a sample & hold Two levels of Encoding Total Comparators # 32 First Encoding Level for n = 1 to 8 is given by B[n] = {C[n] and (Not C[n+8])} OR {C[n+16] and (Not C[n+24])} B[9] = {C[16] and (Not C[32])}OR {C[17] and (Not C[32])} Comparators First Encoding Level Second Encoding Level CM1 CM32 B1 B9 Bit0 Bit1 Bit4
![5 Encoding Logic The design of converter is optimized to minimize the effect of errors that may occur in ADC architecture without a sample & hold Two levels of Encoding Total Comparators # 32 First Encoding Level for n = 1 to 8 is given by B[n] = {C[n] and (Not C[n+8])} OR {C[n+16] and (Not C[n+24])} B[9] = {C[16] and (Not C[32])}OR {C[17] and (Not C[32])} Comparators First Encoding Level Second Encoding Level CM1 CM32 B1 B9 Bit0 Bit1 Bit4](http://images.slideplayer.com/16/4930307/slides/slide_5.jpg "5 Encoding Logic The design of converter is optimized to minimize the effect of errors that may occur in ADC architecture without a sample & hold Two levels of Encoding Total Comparators # 32 First Encoding Level for n = 1 to 8 is given by B[n] = {C[n] and (Not C[n+8])} OR {C[n+16] and (Not C[n+24])} B[9] = {C[16] and (Not C[32])}OR {C[17] and (Not C[32])} Comparators First Encoding Level Second Encoding Level CM1 CM32 B1 B9 Bit0 Bit1 Bit4")
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6 Encoding Logic Contd.. Second Level of Encoding – Bit 0 = (B1 XOR B2) OR (B3 XOR B4) OR (B5 XOR B6) OR (B7 XOR B8) Bit 1 = (B2 XOR B4) OR (B6 XOR B8) Bit 2 = (B4 XOR B8) Bit 3 = B8 Bit4 = B9
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7 Project Details Comparator output Simulated First Level Encoding - Inverter, AOI22 Second Level Encoding - 2 input XOR, 2input OR, 4input OR Flipflop
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8 Schematic
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9 Verilog Simulation
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10 Longest Path Calculations Basic Block Logic Level Logic Gate Cg to drive #Cdn#Cdp#Ln#LpWnWpCg Flipflo p 1NOR30ff23Ln2Lp2.87u5.07u30ff 2Keeper MUX 332Ln2Lp1.5u 3Driving MUX 332Ln2Lp2.87u5.07u 4INV11LnLp2.87u5.07u OR5INV30ff11LnLp1.5u2.48u30ff 6NOR6.8 ff774LnLp1.5u5.09u11.26ff XOR7AOI2211.26 ff 662Ln2Lp3.3u5.5u6.78ff 8INV6.78ff11LnLp3.35.5u6.78ff AOI229INV26.8ff11LnLp1.5u2.53u6.88ff 10AOI226.88ff662Ln2Lp1.5u2.53u6.88ff INV11INV6.88ff11LnLp1.5u2.53u
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11 Transient Analysis
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12 Propagation Delay
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13 Layout
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14 DRC Check & LVS
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15 Cost Analysis Time we spent on each phase of the project –verifying logic : 6 Hours –verifying timing : 20 Hours –layout : 30 Hours –post extraction : 1 Hour
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16 Summary Designed Encoding Logic for 5 bit Analog to Digital Converter without Sample & Hold. Designed Conforming to Specifications Clock frequency > 200 MHz Power < 3mW Area : 337.2 um x 104.70 um
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17 Reference IEEE Paper : An 8-bit 250 megasample per second analog-to- digital converter: operation without a sample and hold Peetz, B. Hamilton, B.D. Kang, J. This paper appears in: Solid-State Circuits, IEEE Journal of
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18 Acknowledgements Thanks to Dr. David Parent Thanks to Cadence Design Systems for the VLSI lab
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