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ELEN 468 Lecture 121 ELEN 468 Advanced Logic Design Lecture 12 Synthesis of Combinational Logic I
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ELEN 468 Lecture 122 Synthesis Logic synthesis Boolean descriptions => circuits RTL synthesis RTL descriptions => Boolean descriptions Behavioral synthesis Behavioral descriptions => RTL descriptions
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ELEN 468 Lecture 123 Objective of Synthesis Area Delay
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ELEN 468 Lecture 124 Logic Synthesis Translation Engine Optimization Engine Mapping Engine Behavioral Descriptions Technology Libraries Two-level Logic Functions Optimized Multi- level Logic Functions Technology Implementation
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ELEN 468 Lecture 125 Translation Engine Read in Verilog-based descriptions Translate into Boolean equations SOP – sum of product POS – product of sum A Verilog description consisting only of a netlist of combinational primitives without feedback can always be synthesized
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ELEN 468 Lecture 126 Logic Optimization Remove redundant logic, exploit logic sharing Substitution Factoring Decomposition Extraction Elimination/flattening
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ELEN 468 Lecture 127 Substitution Express a Boolean function in terms of its inputs and another function G = a + b F = a + b + c G = a + b F = G + c
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ELEN 468 Lecture 128 Factoring Find the common factors among a set of functions F = ac + ad + bc + bd + e F = ( a + b ) ( c + d ) + e Two-level => multi-level Area reduced Delay increased
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ELEN 468 Lecture 129 Decomposition Express one Boolean function in terms of new nodes F = abc + abd + a’c’d’ + b’c’d’ 9 gates, 40 transistors F = XY + X’Y’ X = ab Y = c + d 7 gates, 24 transistors Figure 8.6, 8.7, page 287
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ELEN 468 Lecture 1210 Extraction Express a set of Boolean functions in terms of new nodes F = ( a + b ) cd + e G = ( a + b ) e’ H = cde X = a + b Y = cd F = XY + e G = Xe’ H = Ye
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ELEN 468 Lecture 1211 Elimination / Flattening Remove a node in a function Increase area Reduce delay F = Ga + G’b G = c + d F = ac + ad + bc’d’
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ELEN 468 Lecture 1212 Combinational Logic Delay Combinational logic delay <= clock period Combinational Logic Register Primary Input Register Primary Output clock
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ELEN 468 Lecture 1213 Synthesis Support to Verilog Commonly supported Figure 8.17, page 297 Unsupported Figure 8.18, page 298
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ELEN 468 Lecture 1214 Exercise 3
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ELEN 468 Lecture 1215 Find Delay module M ( y, a, b, c ); output y; input a, b, c; and #(2, 4) (w1, a, b); not #3 (w2, c); nor #(5, 2 ) (y, w1, w2); endmodule module M ( y, a, b, c ); output y; input a, b, c; and #(2, 4) (w1, a, b); not #3 (w2, c); nor #(5, 2 ) (y, w1, w2); endmodule a -> y (9, 4) b -> y (9, 4) c -> y (8, 5)
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ELEN 468 Lecture 1216 FSM of Traffic Light Control module traffic ( light, clock, pedx ); input clock, pedx; output [1:0] light; reg [1:0] light; reg [7:0] timer; parameter green = 2`b01; parameter yellow = 2`b10; parameter red = 2`b11; always @ ( timer ) begin if ( timer < 100 ) light <= green; else if ( timer < 110 ) light <= yellow; else light <= red; end always @ ( posedge clock ) begin if ( timer < 130 ) timer <= timer+ 1; else timer <= 0; end always @ ( posedge pedx ) if ( light == green ) timer <= 100; endmodule module traffic ( light, clock, pedx ); input clock, pedx; output [1:0] light; reg [1:0] light; reg [7:0] timer; parameter green = 2`b01; parameter yellow = 2`b10; parameter red = 2`b11; always @ ( timer ) begin if ( timer < 100 ) light <= green; else if ( timer < 110 ) light <= yellow; else light <= red; end always @ ( posedge clock ) begin if ( timer < 130 ) timer <= timer+ 1; else timer <= 0; end always @ ( posedge pedx ) if ( light == green ) timer <= 100; endmodule
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