Question 1 If you only had 4:16 One Hot Decoder and an OR gate with the number of inputs of your choosing, fill in the blanks to explain how you would implement the function 3 X2X1 + X3 X20 with the hardware you were provided. There are 4 inputs for this function, 30 . I would choose an OR gate with [Select] 1. For input 3, I would connect it input [Select] 2. For input 22, I would connect it input [Select] 3. For input x1, I would connect it input [Select] 4. For input, I would connect it input [Select] 1. For output 0000 of the decoder, [Select] [ Select] I would connect it to the OR gate I would not use it 2. For output 0001 of the decoder, 3. For output 0010 of the decoder, [Select] 4. For output 0011 of the decoder, 5. For output 0100 of the decoder, [Select] 6. For output 0101 of the decoder, [Select] 7. For output 0110 of the decoder, [Select] 8. For output 0111 of the decoder, [Select] 9. For output 1000 of the decoder, [Select] 10. For output 1001 of the decoder, [Select] 11. For output 1010 of the decoder, [Select] 12. For output 1011 of the decoder, [Select] 13. For output 1100 of the decoder, [Select] [Select] 14. For output 1101 of the decoder, [Select] inputs. 15. For output 1110 of the decoder, [Select] 16. For output 1111 of the decoder, [Select] of the decoder. of the decoder. of the decoder. of the decoder.

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Author:Robert L. Boylestad
Publisher:Robert L. Boylestad
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### Question 1

If you only had 4:16 One Hot Decoder and an OR gate with the number of inputs of your choosing, fill in the blanks to explain how you would implement the function \( x_3 \overline{x_2} x_1 + \overline{x_3} x_2 x_0 \) with the hardware you were provided. There are 4 inputs for this function, \( x_3 \) to \( x_0 \).

- I would choose an OR gate with \([ \text{Select} ]\) inputs.

1. For input \( x_3 \), I would connect it to input \([ \text{Select} ]\) of the decoder.
2. For input \( x_2 \), I would connect it to input \([ \text{Select} ]\) of the decoder.
3. For input \( x_1 \), I would connect it to input \([ \text{Select} ]\) of the decoder.
4. For input \( x_0 \), I would connect it to input \([ \text{Select} ]\) of the decoder.

1. For output 0000 of the decoder, \([ \text{Select} ]\) 
2. For output 0001 of the decoder, \([ \text{Select} ]\) 
3. For output 0010 of the decoder, \([ \text{Select} ]\) 
4. For output 0011 of the decoder, \([ \text{Select} ]\) 
5. For output 0100 of the decoder, \([ \text{Select} ]\) 
6. For output 0101 of the decoder, \([ \text{Select} ]\) 
7. For output 0110 of the decoder, \([ \text{Select} ]\) 
8. For output 0111 of the decoder, \([ \text{Select} ]\) 
9. For output 1000 of the decoder, \([ \text{Select} ]\) 
10. For output 1001 of the decoder, \([ \text{Select} ]\) 
11. For output 1010 of the decoder, \([ \text{Select} ]\) 
12. For output 1011 of the decoder, \([ \text{Select}
Transcribed Image Text:### Question 1 If you only had 4:16 One Hot Decoder and an OR gate with the number of inputs of your choosing, fill in the blanks to explain how you would implement the function \( x_3 \overline{x_2} x_1 + \overline{x_3} x_2 x_0 \) with the hardware you were provided. There are 4 inputs for this function, \( x_3 \) to \( x_0 \). - I would choose an OR gate with \([ \text{Select} ]\) inputs. 1. For input \( x_3 \), I would connect it to input \([ \text{Select} ]\) of the decoder. 2. For input \( x_2 \), I would connect it to input \([ \text{Select} ]\) of the decoder. 3. For input \( x_1 \), I would connect it to input \([ \text{Select} ]\) of the decoder. 4. For input \( x_0 \), I would connect it to input \([ \text{Select} ]\) of the decoder. 1. For output 0000 of the decoder, \([ \text{Select} ]\) 2. For output 0001 of the decoder, \([ \text{Select} ]\) 3. For output 0010 of the decoder, \([ \text{Select} ]\) 4. For output 0011 of the decoder, \([ \text{Select} ]\) 5. For output 0100 of the decoder, \([ \text{Select} ]\) 6. For output 0101 of the decoder, \([ \text{Select} ]\) 7. For output 0110 of the decoder, \([ \text{Select} ]\) 8. For output 0111 of the decoder, \([ \text{Select} ]\) 9. For output 1000 of the decoder, \([ \text{Select} ]\) 10. For output 1001 of the decoder, \([ \text{Select} ]\) 11. For output 1010 of the decoder, \([ \text{Select} ]\) 12. For output 1011 of the decoder, \([ \text{Select}
**Question 1**

If you only had a 4:16 One Hot Decoder and an OR gate with the number of inputs of your choosing, fill in the blanks to explain how you would implement the function \(x_3 x_2 x_1 + x_3 x_2 x_0\) with the hardware you were provided. There are 4 inputs for this function, \(x_3\) to \(x_0\).

- I would choose an OR gate with [Select] inputs.

1. For input \(x_3\), I would connect it to [Select] of the decoder.
2. For input \(x_2\), I would connect it to [Select] of the decoder.
3. For input \(x_1\), I would connect it to [Select] of the decoder.
4. For input \(x_0\), I would connect it to [Select] of the decoder.

1. For output 0000 of the decoder, [Select]
2. For output 0001 of the decoder, [Select]
3. For output 0010 of the decoder, [Select]
4. For output 0011 of the decoder, [Select]
5. For output 0100 of the decoder, [Select]
6. For output 0101 of the decoder, [Select]
7. For output 0110 of the decoder, [Select]
8. For output 0111 of the decoder, [Select]
9. For output 1000 of the decoder, [Select]
10. For output 1001 of the decoder, [Select]
11. For output 1010 of the decoder, [Select]
12. For output 1011 of the decoder, [Select]
13. For output 1100 of the decoder, [Select]
14. For output 1101 of the decoder, [Select]
15. For output 1110 of the decoder, [Select]
16. For output 1111 of the decoder, [Select]

**Dropdown Explanation:**

In the provided dropdown menu, you can select numbers to substitute into the blanks, potentially representing different lines or inputs from the decoder or OR gate inputs.
Transcribed Image Text:**Question 1** If you only had a 4:16 One Hot Decoder and an OR gate with the number of inputs of your choosing, fill in the blanks to explain how you would implement the function \(x_3 x_2 x_1 + x_3 x_2 x_0\) with the hardware you were provided. There are 4 inputs for this function, \(x_3\) to \(x_0\). - I would choose an OR gate with [Select] inputs. 1. For input \(x_3\), I would connect it to [Select] of the decoder. 2. For input \(x_2\), I would connect it to [Select] of the decoder. 3. For input \(x_1\), I would connect it to [Select] of the decoder. 4. For input \(x_0\), I would connect it to [Select] of the decoder. 1. For output 0000 of the decoder, [Select] 2. For output 0001 of the decoder, [Select] 3. For output 0010 of the decoder, [Select] 4. For output 0011 of the decoder, [Select] 5. For output 0100 of the decoder, [Select] 6. For output 0101 of the decoder, [Select] 7. For output 0110 of the decoder, [Select] 8. For output 0111 of the decoder, [Select] 9. For output 1000 of the decoder, [Select] 10. For output 1001 of the decoder, [Select] 11. For output 1010 of the decoder, [Select] 12. For output 1011 of the decoder, [Select] 13. For output 1100 of the decoder, [Select] 14. For output 1101 of the decoder, [Select] 15. For output 1110 of the decoder, [Select] 16. For output 1111 of the decoder, [Select] **Dropdown Explanation:** In the provided dropdown menu, you can select numbers to substitute into the blanks, potentially representing different lines or inputs from the decoder or OR gate inputs.
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