The circuit shown above is to be used to implement the function $Z = f\left( {A,B} \right) = \overline A + B$. The values of I and J are:

The following Boolean expression $$Y = A \cdot \overline B \cdot \overline C \cdot \overline D + \overline A \cdot B \cdot \overline C \cdot D + \overline A \cdot \overline B \cdot \overline C \cdot D + \overline A \cdot \overline B \cdot \overline C \cdot D + \overline A \cdot B \cdot C \cdot D + A \cdot \overline B \cdot \overline C \cdot D$$ can be simplified to

A

$$\overline A \cdot \overline B \cdot C + A \cdot \overline D $$

B

$$\overline A \cdot B \cdot \overline C + A \cdot \overline D $$

C

$$A \cdot \overline B \cdot \overline C + \overline A \cdot D$$

D

$$A \cdot \overline B \cdot C + \overline A \cdot D$$

For realizing a binary half-subtractor having two inputs A and B, the current set of logical expression for the outputs D (A minus B) and X (borrow) are 1. The difference output D = A̅B + AB̅ 2. The borrow output B = AB̅ Which of the above statements is/are correct?

A

1 only

B

2 only

C

Both 1 and 2

D

Neither 1 nor 2

ABCD is a parallelogram and the diagonals $\overline {AC} $ and $\overline {BD} $ intersect at 'O'. If E, F, G and H are the mid-point of $\overline {AO}$, $\overline {DO}$, $\overline {CO}$ and $\overline {BO} $ respectively, then what is the ratio of (EF + FG + GH + HE) and (AD + DC + CB + BA)?

A

1 ∶ 2

B

2 ∶ 3

C

3 ∶ 4

D

4 ∶ 5

Let the average temperatures in Centigrade (C) and Fahrenheit (F) be $$\overline C $$ and $$\overline F $$. If $$\overline C $$ and $$\overline F $$ are related to $$F = \frac{9}{2}C + 32,$$ then $$\overline F $$ and $$\overline C $$ have the relation

A

$$\overline F = \frac{9}{2}\overline C + 32$$

B

$$\overline F = \overline C + 32$$

C

$$\overline F = \frac{9}{2}\overline C $$

D

$$\overline F = \frac{9}{5}\overline C - 32$$

ΔABC is an isosceles triangle and $$\overline {AB} $$ = $$\overline {AC} $$ = 2a unit, $$\overline {BC} $$ = a unit. Draw $$\overline {AD} $$ ⊥ $$\overline {BC} $$ , and find the length of $$\overline {AD} $$

A

$$\sqrt {15} $$ a unit

B

$$\frac{{\sqrt {15} }}{2}$$ a unit

C

$$\sqrt {17} $$ a unit

D

$$\frac{{\sqrt {17} }}{2}$$ a unit

In the given circle, line $\rm\overline{AB}$ is produced to meet tangent $\rm\overline{DE}$ at point D. If $\rm\overline{AB}$ = 7 cm and $\rm\overline{DE}$ = 12 cm, then what will be the length of $\rm\overline{BD}$?

A

7 cm

B

9 cm

C

$2\sqrt{21}$ cm

D

8 cm

In the circle below, chord $\overline {AB}$ is extended to meet the tangent $\overline {DE}$ at D. If $\overline {AB}$ = 24 cm $\overline {DE}$ = 9 cm, what is the length of $\overline {BD}$?

A

4√6 cm

B

3 cm

C

5 cm

D

4 cm

The Boolean expression Y = $$\overline {{\text{ABC}}} $$ D + $$\overline {{\text{AB}}} $$ CD + $$\overline {\text{A}} $$B$$\overline {\text{C}} $$ D + $$\overline {\text{A}} $$BCD reduces to

A

AB

B

D

C

$$\overline {\text{A}} $$

D

$$\overline {\text{A}} $$D

In the given circle, chord $\overline {AB}$ is extended to meet the tangent $\overline {DE}$ at D. If $\overline {AB}$ = 10 cm and $\overline {DE}$ 12 cm, what is the length of B̅D̅?

A

7 cm

B

8 cm

C

9 cm

D

$2\sqrt {21} \;cm$

$$\left( {8.3\overline 1 + 0.\overline 6 + 0.00\overline 2 } \right)$$ is equal to :

A

$${8.9\overline {12} }$$

B

$${8.\overline {912} }$$

C

$${8.9\overline {79} }$$

D

$${8.97\overline {9} }$$

The circuit shown above is to be used to implement the function \(Z = f\left( {A,B} \right) = \overline A + B\). The values of I and J are:

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