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Digital Electronics Tutorial: Number System & Arithmetic Circuits Solutions

Digital Electronics Tutorial: Number System & Arithmetic Circuits Solutions. Number System. Conversion to Base 10 FFA 16 1101100 2 1000 2 1000 16 Binary Addition in 2’complement 100 110 + 000 111 100 111 + 000 101 100 111 + 100 100 011 111 + 010 111 Binary Subtraction in 2’complement

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Digital Electronics Tutorial: Number System & Arithmetic Circuits Solutions

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  1. Digital ElectronicsTutorial: Number System & Arithmetic Circuits Solutions

  2. Number System • Conversion to Base 10 • FFA16 • 11011002 • 10002 • 100016 • Binary Addition in 2’complement • 100 110 + 000 111 • 100 111 + 000 101 • 100 111 + 100 100 • 011 111 + 010 111 • Binary Subtraction in 2’complement • 100 110 - 000 111 • 100 111 - 000 101 • 100 111 - 100 100 • 011 111 - 010 111

  3. Number System Solutions (1/3) • Conversion to Base 10 • FFA16 = F × 162 + F × 161 + A × 160 = 15 × 162 + 15 × 161 + 10 × 160 = 4090 • 11011002 = 1 × 26 + 1 × 25 + 0 × 24 + 1 × 23 + 1 × 22 + 0 × 21 + 0 × 20 = 108 • 10002 = 1 × 23 + 0 × 22 + 0 × 21 + 0 × 20 = 8 • 100016 = 1 × 163 + 0 × 162 + 0 × 161 + 0 × 160 = 4096

  4. Number System Solutions (2/3) • Binary Addition in 2’complement • 100 110 + • 000 111 • __________ • 101 101 • 100 111 + • 000 101 • __________ • 101 100 • 100 111 + • 100 100 • __________ • Overflow1 001 011 • 011 111 + • 010 111 • __________ • Overflow110 110

  5. Number System Solution (3/3) • Binary Subtraction in 2’complement • 100 110 - 000 111 = 100 110 + 111 000 + 1 • 100 111 - 000 101 = 100 111 + 111 010 + 1 • 100 111 - 100 100 = 100 111 + 011 011 + 1 • 011 111 - 010 111 = 011 111 + 101 000 + 1 • 100 110 + • 111 000 • 1 • Overflow1 011 111 • 100 111 + • 111 010 • 1 • Overflow1 100 010 • 100 111 + • 011 011 • 1 • 1 000 011 • 011 111 + • 101 000 • 1 • 1 001 000

  6. Arithmetic Circuits Implement a combinational logic circuit that converts a 4-bit sign and magnitude numbers into corresponding 4-bit two’s complement numbers. Draw an input/output conversion truth table, intermediate K-maps, and your minimised two-level logic description.

  7. ABCD EFGH 0000 0000 0001 0001 0010 0010 0011 0011 0100 0100 0101 0101 0110 0110 0111 0111 1000 0000 1001 1111 1010 1110 1011 1101 1100 1100 1101 1011 1110 1010 1111 1001 Arithmetic Circuits Solution (1/4) AB 00 01 11 10 CD 00 0 0 1 0 01 0 0 1 1 11 0 0 1 1 10 0 0 1 1 E = AB + AC + AD

  8. ABCD EFGH 0000 0000 0001 0001 0010 0010 0011 0011 0100 0100 0101 0101 0110 0110 0111 0111 1000 0000 1001 1111 1010 1110 1011 1101 1100 1100 1101 1011 1110 1010 1111 1001 Arithmetic Circuits Solution (2/4) AB 00 01 11 10 CD 00 0 1 1 0 01 0 1 0 1 11 0 1 0 1 10 0 1 0 1 F = A’ B + B C’ D’ + A B’ D + A B’ C

  9. ABCD EFGH 0000 0000 0001 0001 0010 0010 0011 0011 0100 0100 0101 0101 0110 0110 0111 0111 1000 0000 1001 1111 1010 1110 1011 1101 1100 1100 1101 1011 1110 1010 1111 1001 Arithmetic Circuits Solution (3/4) AB 00 01 11 10 CD 00 0 0 0 0 01 0 0 1 1 11 1 1 0 0 10 1 1 1 1 G = C D’ + A’ C + A C’ D

  10. ABCD EFGH 0000 0000 0001 0001 0010 0010 0011 0011 0100 0100 0101 0101 0110 0110 0111 0111 1000 0000 1001 1111 1010 1110 1011 1101 1100 1100 1101 1011 1110 1010 1111 1001 Arithmetic Circuits Solution (4/4) AB 00 01 11 10 CD 00 0 0 0 0 01 1 1 1 1 11 1 1 1 1 10 0 0 0 0 H = D

  11. Bit-Serial Adder The traditional binary adder operates on all of its input bits at the same time, calculating the sum output bits in parallel. Consider an alternative way to implement a binary adder using a so-called bit serial approach. The two numbers to be added are presented to a Finite State Machine one bit at a time, with the lowest order bits presented first. The Finite State Machine produces at its output the lowest order bit of the sum, then the next higher order sum bit, and so on, until all of the input bits have been processed and all of the output sum bits generated. (a)Design a simple datapath for the bit-serial adder down to the gate level, and identify the interface between your control finite state machine and the datapath. Consider how to deal with carry-in and carry-out in your design. (b)Show your state diagram for a 4-bit bit-serial adder, where the outputs of the state machine are the control signals of the datapath you designed in (a). (c)Demonstrate how your subsystem works by showing step-by-step how it executes the summation of 0110 and 1100. The carry-in to the low order bit is initially zero.

  12. Bit-Serial Adder Solution (1/3) (a) Design a simple datapath for the bit-serial adder down to the gate level, and identify the interface between your control finite state machine and the datapath. Consider how to deal with carry-in and carry-out in your design. Signals: SHIFT, CinSELECT, SELECT, CE

  13. Bit-Serial Adder Solution (2/3) (b)Show your state diagram for a 4-bit bit-serial adder, where the outputs of the state machine are the control signals of the datapath you designed in (a).

  14. Cout Sum Bit-Serial Adder Solution (3/3) (c)Demonstrate how your subsystem works by showing step-by-step how it executes the summation of 0110 and 1100. The carry-in to the low order bit is initially zero. A[3:0] = 0110 B[3:0] = 1100 Cin = 0 0110 + 1100 = 1 0010   A[3:0] = 0110 B[3:0] = 1100 Step 1: SELECT = 00 CinSELECT = 0 SUM = 0000 Cout = 0 Step 2: SELECT = 01 CinSELECT = 1 SUM = 1000 Cout = 0 Step 3: SELECT = 10 CinSELECT = 1 SUM = 0100 Cout = 1 Step 4: SELECT = 11 CinSELECT = 1 SUM = 0010 Cout = 1

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