Conversion of infix expression to prefix expression
P) (A+B) *C
Solution:
⇒[+AB]*C
⇒*+ABC
P:2) (A-B) *(C+D)
Solution:
⇒[-AB]*[+CD]
⇒*-AB+CD
P:3) (A+B) /(C+D) -(D*E)
Solution:
⇒[+AB]/[+CD]-[*DE]
⇒[/+AB+CD]-[*DE]
⇒-/+AB+CD*DE
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Convert the expression given below into its equivalent prefix and postfix notation.
((A+B) ^C) -(D-E) ^(F+G))
Prefix notation:
⇒([+AB]^C-[-DE]^[+FG])
⇒-^ABC ^ -DE+FG
Postfix Notation:
⇒AB+C^DE-FG+^-
- Evaluate the following postfix expressions for A=2, B=5, C=3, D=2, E=4
ABC+DE*/-
Show stack at each step.
Solution:
ABC+DE*/-
Given, A=2, B=5, C=3, D=2, E=4
So, putting values of A, B, C, D, E into the above expression , we get
2 5 3+2 4 * / -
| Symbol Scanned |
Stack |
| (1) 2 |
2 |
| (2) 5 |
2, 5 |
| (3) 3 |
2, 5,3 |
| (4) + |
2,8 |
| (5) 2 |
2, 8,2 |
| (6) 4 |
2, 8,2,4 |
| (7) * |
2, 8,8 |
| (8) / |
2, 1 |
| (9) - |
1 |
So, the final number in stack is 1, which is the solution.
- Transform the following expression into its equivalent postfix expression using stack.
A+(B*C-(D/E↑) *G) *H)
Solution:
| Symbol Scanned |
Stack |
Expression |
| (1) A |
( |
A |
| (2) + |
(+ |
A |
| (3) ( |
(+( |
A |
| (4) B |
(+( |
AB |
| (5) * |
(+(* |
AB |
| (6) C |
(+(* |
ABC |
| (7) - |
(+(- |
ABC* |
| (8) ( |
(+(-( |
ABC* |
| (9) D |
(+(-( |
ABC*D |
| (10) / |
(+(-(/ |
ABC*D |
| (11) E |
(+(-(/ |
ABC*DE |
| (12) ↑ |
(+(-(/↑ |
ABC*DE |
| (13) F |
(+(-(/↑ |
ABC*DEF |
| (14) ) |
(+(- |
ABC*DEF↑/ |
| (15) * |
(+(-* |
ABC*DEF↑/ |
| (16) G |
(+(-* |
ABC*DEF↑/G |
| (17) ) |
(+ |
ABC*DEF↑/G*- |
| (18) * |
(+* |
ABC*DEF↑/G*- |
| (19) H |
(+* |
ABC*DEF↑/G*-H |
| (20) ) |
|
ABC*DEF↑/G*-H*+ |
The equivalent postfix expression of the above infix expression is:
ABC*DEF↑/G*-H*+
- Calculate the position of element which is present in 7th row and 8th column for a 10×10 matrix . Here base address is 6010.
Solution:
By row major order:
Address[aij] =M+(i-1) ×n+j-1
⇒a78=6010+(7-1) ×10+8-1
⇒a78=6077
By coulmn major order:
Address[aij]=M+(j-1) ×m+i+1
⇒a78=6010+(8-1) ×10+7-1
⇒a78=6086
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