1 Calculate fare for each kilometer:

Let’s find the total fare after traveling 1 km, 2 km, 3 km, 4 km, and so on.

• After 1 km: \(\text{₹}15\)
• After 2 km: \(\text{₹}15 + \text{₹}8 = \text{₹}23\)
• After 3 km: \(\text{₹}23 + \text{₹}8 = \text{₹}31\)
• After 4 km: \(\text{₹}31 + \text{₹}8 = \text{₹}39\)
• After 5 km: \(\text{₹}39 + \text{₹}8 = \text{₹}47\)

So the sequence of fares is: \(15, 23, 31, 39, 47, \ldots\)

2 Check if the difference between consecutive terms is constant:

Let’s calculate the differences:

\[ \begin{aligned} a_2 – a_1 &= 23 – 15 = 8 \\ a_3 – a_2 &= 31 – 23 = 8 \\ a_4 – a_3 &= 39 – 31 = 8 \\ a_5 – a_4 &= 47 – 39 = 8 \end{aligned} \]

The difference between consecutive terms is constant and equals \(8\).

3 Conclusion:

Since the common difference \(d = 8\) is constant throughout the sequence, this situation forms an Arithmetic Progression (AP).

The AP has:

• First term: \(a = 15\)
• Common difference: \(d = 8\)

1 Calculate remaining air after each operation:

Let the initial amount of air be \(V\) units.

• Initially: \(V\)
• After 1st operation: \(V – \frac{V}{4} = \frac{3V}{4}\)
• After 2nd operation: \(\frac{3V}{4} – \frac{1}{4} \times \frac{3V}{4} = \frac{3V}{4} \times \frac{3}{4} = \frac{9V}{16}\)
• After 3rd operation: \(\frac{9V}{16} \times \frac{3}{4} = \frac{27V}{64}\)

The sequence is: \(V, \frac{3V}{4}, \frac{9V}{16}, \frac{27V}{64}, \ldots\)

2 Check if the difference is constant:

Let’s assume \(V = 64\) units for easy calculation:

Sequence becomes: \(64, 48, 36, 27, \ldots\)

\[ \begin{aligned} a_2 – a_1 &= 48 – 64 = -16 \\ a_3 – a_2 &= 36 – 48 = -12 \\ a_4 – a_3 &= 27 – 36 = -9 \end{aligned} \]

The differences are \(-16, -12, -9, \ldots\) which are NOT constant.

3 Identify the pattern:

Notice that each term is obtained by multiplying the previous term by \(\frac{3}{4}\):

\[ \frac{a_{n+1}}{a_n} = \frac{3}{4} \text{ (constant ratio)} \]

This is a Geometric Progression (GP), not an AP.

1 Calculate cost for each metre:

• 1st metre: \(\text{₹}150\)
• 2nd metre: \(\text{₹}150 + \text{₹}50 = \text{₹}200\)
• 3rd metre: \(\text{₹}200 + \text{₹}50 = \text{₹}250\)
• 4th metre: \(\text{₹}250 + \text{₹}50 = \text{₹}300\)
• 5th metre: \(\text{₹}300 + \text{₹}50 = \text{₹}350\)

The sequence is: \(150, 200, 250, 300, 350, \ldots\)

2 Check if the difference is constant: \[ \begin{aligned} a_2 – a_1 &= 200 – 150 = 50 \\ a_3 – a_2 &= 250 – 200 = 50 \\ a_4 – a_3 &= 300 – 250 = 50 \\ a_5 – a_4 &= 350 – 300 = 50 \end{aligned} \]

The common difference \(d = 50\) is constant.

3 Conclusion:

Since the difference between consecutive terms is constant, this situation forms an AP with:

• First term: \(a = 150\)
• Common difference: \(d = 50\)

1 Calculate amount after each year:

Using the compound interest formula with \(P = 10000\) and \(r = 8\%\):

• After 0 years (Initially): \(\text{₹}10000\)
• After 1 year: \(10000 \times 1.08 = \text{₹}10800\)
• After 2 years: \(10000 \times (1.08)^2 = \text{₹}11664\)
• After 3 years: \(10000 \times (1.08)^3 = \text{₹}12597.12\)
• After 4 years: \(10000 \times (1.08)^4 = \text{₹}13604.89\)

The sequence is: \(10000, 10800, 11664, 12597.12, 13604.89, \ldots\)

2 Check if the difference is constant: \[ \begin{aligned} a_2 – a_1 &= 10800 – 10000 = 800 \\ a_3 – a_2 &= 11664 – 10800 = 864 \\ a_4 – a_3 &= 12597.12 – 11664 = 933.12 \\ a_5 – a_4 &= 13604.89 – 12597.12 = 1007.77 \end{aligned} \]

The differences are \(800, 864, 933.12, 1007.77, \ldots\) which are NOT constant.

3 Identify the pattern:

Each term is obtained by multiplying the previous term by \(1.08\):

\[ \frac{a_{n+1}}{a_n} = 1.08 \text{ (constant ratio)} \]

This is a Geometric Progression (GP) with common ratio \(r = 1.08\), not an AP.