1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= 4 – 2 = 2 \\ a_3 – a_2 &= 8 – 4 = 4 \\ a_4 – a_3 &= 16 – 8 = 8 \end{aligned} \]

2 Check if differences are constant:

The differences are: \(2, 4, 8, \ldots\)

These differences are NOT constant.

3 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

Note: This is a Geometric Progression (GP) with common ratio \(r = 2\).

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= \frac{5}{2} – 2 = \frac{5}{2} – \frac{4}{2} = \frac{1}{2} \\ a_3 – a_2 &= 3 – \frac{5}{2} = \frac{6}{2} – \frac{5}{2} = \frac{1}{2} \\ a_4 – a_3 &= \frac{7}{2} – 3 = \frac{7}{2} – \frac{6}{2} = \frac{1}{2} \end{aligned} \]

2 Check if differences are constant:

All differences equal \(\frac{1}{2}\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = \frac{1}{2}\)

3 Find next three terms:

Add \(d = \frac{1}{2}\) to each previous term:

\[ \begin{aligned} a_5 &= \frac{7}{2} + \frac{1}{2} = \frac{8}{2} = 4 \\ a_6 &= 4 + \frac{1}{2} = \frac{9}{2} \\ a_7 &= \frac{9}{2} + \frac{1}{2} = \frac{10}{2} = 5 \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= -3.2 – (-1.2) = -3.2 + 1.2 = -2 \\ a_3 – a_2 &= -5.2 – (-3.2) = -5.2 + 3.2 = -2 \\ a_4 – a_3 &= -7.2 – (-5.2) = -7.2 + 5.2 = -2 \end{aligned} \]

2 Check if differences are constant:

All differences equal \(-2\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = -2\)

3 Find next three terms:

Add \(d = -2\) to each previous term:

\[ \begin{aligned} a_5 &= -7.2 + (-2) = -7.2 – 2 = -9.2 \\ a_6 &= -9.2 + (-2) = -9.2 – 2 = -11.2 \\ a_7 &= -11.2 + (-2) = -11.2 – 2 = -13.2 \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= -6 – (-10) = -6 + 10 = 4 \\ a_3 – a_2 &= -2 – (-6) = -2 + 6 = 4 \\ a_4 – a_3 &= 2 – (-2) = 2 + 2 = 4 \end{aligned} \]

2 Check if differences are constant:

All differences equal \(4\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = 4\)

3 Find next three terms:

Add \(d = 4\) to each previous term:

\[ \begin{aligned} a_5 &= 2 + 4 = 6 \\ a_6 &= 6 + 4 = 10 \\ a_7 &= 10 + 4 = 14 \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= (3 + \sqrt{2}) – 3 = \sqrt{2} \\ a_3 – a_2 &= (3 + 2\sqrt{2}) – (3 + \sqrt{2}) = \sqrt{2} \\ a_4 – a_3 &= (3 + 3\sqrt{2}) – (3 + 2\sqrt{2}) = \sqrt{2} \end{aligned} \]

2 Check if differences are constant:

All differences equal \(\sqrt{2}\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = \sqrt{2}\)

3 Find next three terms:

Add \(d = \sqrt{2}\) to each previous term:

\[ \begin{aligned} a_5 &= 3 + 3\sqrt{2} + \sqrt{2} = 3 + 4\sqrt{2} \\ a_6 &= 3 + 4\sqrt{2} + \sqrt{2} = 3 + 5\sqrt{2} \\ a_7 &= 3 + 5\sqrt{2} + \sqrt{2} = 3 + 6\sqrt{2} \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= 0.22 – 0.2 = 0.02 \\ a_3 – a_2 &= 0.222 – 0.22 = 0.002 \\ a_4 – a_3 &= 0.2222 – 0.222 = 0.0002 \end{aligned} \]

2 Check if differences are constant:

The differences are: \(0.02, 0.002, 0.0002, \ldots\)

These differences are NOT constant.

3 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= -4 – 0 = -4 \\ a_3 – a_2 &= -8 – (-4) = -8 + 4 = -4 \\ a_4 – a_3 &= -12 – (-8) = -12 + 8 = -4 \end{aligned} \]

2 Check if differences are constant:

All differences equal \(-4\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = -4\)

3 Find next three terms:

Add \(d = -4\) to each previous term:

\[ \begin{aligned} a_5 &= -12 + (-4) = -16 \\ a_6 &= -16 + (-4) = -20 \\ a_7 &= -20 + (-4) = -24 \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= -\frac{1}{2} – \left(-\frac{1}{2}\right) = 0 \\ a_3 – a_2 &= -\frac{1}{2} – \left(-\frac{1}{2}\right) = 0 \\ a_4 – a_3 &= -\frac{1}{2} – \left(-\frac{1}{2}\right) = 0 \end{aligned} \]

2 Check if differences are constant:

All differences equal \(0\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = 0\)

Note: This is a constant sequence (all terms are equal).

3 Find next three terms:

Since \(d = 0\), all terms remain the same:

\[ a_5 = a_6 = a_7 = -\frac{1}{2} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= 3 – 1 = 2 \\ a_3 – a_2 &= 9 – 3 = 6 \\ a_4 – a_3 &= 27 – 9 = 18 \end{aligned} \]

2 Check if differences are constant:

The differences are: \(2, 6, 18, \ldots\)

These differences are NOT constant.

3 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

Note: This is a Geometric Progression (GP) with common ratio \(r = 3\).

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= 2a – a = a \\ a_3 – a_2 &= 3a – 2a = a \\ a_4 – a_3 &= 4a – 3a = a \end{aligned} \]

2 Check if differences are constant:

All differences equal \(a\), which is constant (since \(a\) is a fixed value).

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = a\)

3 Find next three terms:

Add \(d = a\) to each previous term:

\[ \begin{aligned} a_5 &= 4a + a = 5a \\ a_6 &= 5a + a = 6a \\ a_7 &= 6a + a = 7a \end{aligned} \]

1 Calculate differences between consecutive terms: \[ \begin{aligned} a_2 – a_1 &= a^2 – a = a(a – 1) \\ a_3 – a_2 &= a^3 – a^2 = a^2(a – 1) \\ a_4 – a_3 &= a^4 – a^3 = a^3(a – 1) \end{aligned} \]

2 Check if differences are constant:

The differences are: \(a(a-1), a^2(a-1), a^3(a-1), \ldots\)

These are NOT constant (unless \(a = 1\), which is excluded).

3 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

Note: This is a Geometric Progression (GP) with common ratio \(r = a\).

1 Simplify the terms: \[ \begin{aligned} a_1 &= \sqrt{2} = \sqrt{2} \\ a_2 &= \sqrt{8} = \sqrt{4 \times 2} = 2\sqrt{2} \\ a_3 &= \sqrt{18} = \sqrt{9 \times 2} = 3\sqrt{2} \\ a_4 &= \sqrt{32} = \sqrt{16 \times 2} = 4\sqrt{2} \end{aligned} \]

So the sequence becomes: \(\sqrt{2}, 2\sqrt{2}, 3\sqrt{2}, 4\sqrt{2}, \ldots\)

2 Calculate differences: \[ \begin{aligned} a_2 – a_1 &= 2\sqrt{2} – \sqrt{2} = \sqrt{2} \\ a_3 – a_2 &= 3\sqrt{2} – 2\sqrt{2} = \sqrt{2} \\ a_4 – a_3 &= 4\sqrt{2} – 3\sqrt{2} = \sqrt{2} \end{aligned} \]

3 Check if differences are constant:

All differences equal \(\sqrt{2}\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = \sqrt{2}\)

4 Find next three terms: \[ \begin{aligned} a_5 &= 4\sqrt{2} + \sqrt{2} = 5\sqrt{2} = \sqrt{50} \\ a_6 &= 5\sqrt{2} + \sqrt{2} = 6\sqrt{2} = \sqrt{72} \\ a_7 &= 6\sqrt{2} + \sqrt{2} = 7\sqrt{2} = \sqrt{98} \end{aligned} \]

1 Simplify the terms: \[ \begin{aligned} a_1 &= \sqrt{3} \\ a_2 &= \sqrt{6} \\ a_3 &= \sqrt{9} = 3 \\ a_4 &= \sqrt{12} = \sqrt{4 \times 3} = 2\sqrt{3} \end{aligned} \]

2 Calculate differences: \[ \begin{aligned} a_2 – a_1 &= \sqrt{6} – \sqrt{3} \approx 2.449 – 1.732 = 0.717 \\ a_3 – a_2 &= 3 – \sqrt{6} \approx 3 – 2.449 = 0.551 \\ a_4 – a_3 &= 2\sqrt{3} – 3 \approx 3.464 – 3 = 0.464 \end{aligned} \]

3 Check if differences are constant:

The differences are approximately: \(0.717, 0.551, 0.464, \ldots\)

These differences are NOT constant.

4 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

1 Calculate the values: \[ \begin{aligned} a_1 &= 1^2 = 1 \\ a_2 &= 3^2 = 9 \\ a_3 &= 5^2 = 25 \\ a_4 &= 7^2 = 49 \end{aligned} \]

So the sequence is: \(1, 9, 25, 49, \ldots\)

2 Calculate differences: \[ \begin{aligned} a_2 – a_1 &= 9 – 1 = 8 \\ a_3 – a_2 &= 25 – 9 = 16 \\ a_4 – a_3 &= 49 – 25 = 24 \end{aligned} \]

3 Check if differences are constant:

The differences are: \(8, 16, 24, \ldots\)

These differences are NOT constant.

4 Conclusion:

Since the difference between consecutive terms is not constant, this sequence is NOT an Arithmetic Progression.

Note: This is the sequence of squares of odd numbers.

1 Calculate the values: \[ \begin{aligned} a_1 &= 1^2 = 1 \\ a_2 &= 5^2 = 25 \\ a_3 &= 7^2 = 49 \\ a_4 &= 73 \end{aligned} \]

So the sequence is: \(1, 25, 49, 73, \ldots\)

2 Calculate differences: \[ \begin{aligned} a_2 – a_1 &= 25 – 1 = 24 \\ a_3 – a_2 &= 49 – 25 = 24 \\ a_4 – a_3 &= 73 – 49 = 24 \end{aligned} \]

3 Check if differences are constant:

All differences equal \(24\), which is constant.

Therefore, this IS an Arithmetic Progression.

Common difference: \(d = 24\)

4 Find next three terms: \[ \begin{aligned} a_5 &= 73 + 24 = 97 \\ a_6 &= 97 + 24 = 121 \\ a_7 &= 121 + 24 = 145 \end{aligned} \]