bader

The remainder is 10.

The answer is 58.

You get n^5 - 38n^4 + 108n^3 - 336n^2 + 7220n + 148060

The remainder is 21.

Analyzing the Problem

We are given a triangle ABC with points P, Q, and R on sides AB, AB, and AC respectively. Specific ratios are provided for segment lengths related to these points. We need to find the ratio of the areas of triangles QBC and CRQ.

Solution Strategy

Relate Segment Lengths: Use the given ratios to express the lengths of AP, PQ, QB, AR, and RC in terms of a single variable.

Express Triangle Areas: Formulate the areas of triangles QBC and CRQ using the segment lengths obtained in step 1.

Find the Ratio of Areas: Divide the area of triangle QBC by the area of triangle CRQ and simplify the expression.

Steps to Solve

Relating Segment Lengths:

We are given: AP = PQ / 3 = QB / 2 and AR / 2 = RC / 3

Let x be the length of AP (or PQ / 3 or QB / 2).

Then, PQ = 3x and QB = 2x.

Similarly, let y be the length of AR (or 2 * RC / 3).

Then, RC = 3y / 2.

Expressing Triangle Areas:

Area of triangle QBC = (1/2) * Base * Height = (1/2) * QB * RC = (1/2) * 2x * (3y / 2) = 3xy

Area of triangle CRQ = (1/2) * Base * Height = (1/2) * CR * PQ = (1/2) * (3y / 2) * 3x = 4.5xy

Ratio of Areas:

[QBC] / [CRQ] = (3xy) / (4.5xy) = 2 / 3

Answer

Therefore, the ratio of the areas of triangles QBC and CRQ is 2:3.

Understanding the Problem

There are 5 players.

Player 1 starts.

A player wins by rolling a 6.

If a number other than 6 is rolled, the die passes to the corresponding player.

Solution

Let P be the probability that Player 1 wins.

There are two ways Player 1 can win:

Player 1 wins on their first roll: This happens with probability 1/6.

Player 1 wins on a subsequent roll: This happens if the die cycles through all players and returns to Player 1 without a 6 being rolled, and then Player 1 rolls a 6.

The probability of the die cycling through all players without a 6 being rolled is (5/6)^4 (since each player has a 5/6 chance of not rolling a 6). Then, Player 1 has a 1/6 chance of winning on their return roll. So the probability of Player 1 winning on a subsequent roll is (5/6)^4 * (1/6).

Therefore, the total probability of Player 1 winning is:

P = (1/6) + (5/6)^4 * (1/6)

To simplify this fraction, we can find a common denominator:

P = (6^4 + 5^4) / (6^5)

Calculating the numerator:

6^4 + 5^4 = 1296 + 625 = 1921

So, the probability that Player 1 wins is:

P = 1921/7776

Therefore, the probability that Player 1 wins is 1921/7776.

We can analyze the system of quadratic equations to determine the number of real solutions for different values of c. Here's how:

Analyzing the Discriminant:

The discriminant of a quadratic equation determines the nature of its roots (solutions). It is denoted by the symbol b2−4ac. In this case, considering the first equation (y = 6x^2 - 9x + c):

a = 6

b = -9

c (variable)

The discriminant (d) for the first equation is:

d = (-9)^2 - 4 * 6 * c

The number of real solutions depends on the value of the discriminant:

d > 0: Two real and distinct solutions (roots)

d = 0: One repeated real solution (root)

d < 0: No real solutions (complex roots)

Relating Discriminant to c:

We want to find the values of c that correspond to each case.

(a) Exactly one real solution:

For exactly one real solution (repeated root), the discriminant needs to be zero.

Therefore, we need to solve:

0 = (-9)^2 - 4 * 6 * c

This simplifies to:

c = \frac{81}{24} = \dfrac{7}{2}

(b) More than one real solution:

For more than one real solution (distinct roots), the discriminant needs to be positive.

Therefore, we need to solve:

0 < (-9)^2 - 4 * 6 * c

This simplifies to:

c < \dfrac{81}{24} = \dfrac{7}{2}

(c) No real solutions:

For no real solutions (complex roots), the discriminant needs to be negative.

Therefore, we need to solve:

0 > (-9)^2 - 4 * 6 * c

This simplifies to:

c > \dfrac{81}{24} = \dfrac{7}{2}

Summary:

(a) Exactly one real solution: c = dfrac{7}{2}

(b) More than one real solution: c < dfrac{7}{2}

(c) No real solutions: c > dfrac{7}{2}