[size=150]Pascal's triangle is a triangular array of numbers that has several applications in combinatorial mathematics and algebra. The triangle is named after the French mathematician Blaise Pascal, who studied its properties.[br][br]Pascal's triangle is constructed in the following way:[br][br]1[br]1 1[br]1 2 1[br]1 3 3 1[br]1 4 6 4 1[br][br]Each row of the triangle represents the coefficients of the binomial expansion of (a + b)[sup]n[/sup], where n is the row number and the coefficients are separated by spaces. The first row corresponds to n = 0, the second row to n = 1, and so on.[br][br]For example, let's consider the fourth row (n = 3) of Pascal's triangle:[br][br]1 3 3 1[br][br]This row represents the coefficients of the binomial expansion of (a + b)[sup]3[/sup], which is:[br][br]1(a[sup]3[/sup]) + 3(a[sup]2[/sup])(b[sup]1[/sup]) +3(a[sup]1[/sup])(b[sup]2[/sup]) + 1(b[sup]3[/sup])[br][br]The coefficients in the row are obtained by applying the binomial coefficient formula, which uses the combinations concept mentioned earlier:[br][br]nCr = n! / (r! * (n - r)!)[br][br]In the case of Pascal's triangle, the binomial coefficients correspond to the entries in each row. Each entry is the sum of the two entries directly above it in the previous row.[br][br]The binomial expansion, using Pascal's triangle, allows us to expand expressions of the form (a + b)^n without actually multiplying them out. It provides a convenient and systematic way to determine the coefficients of the expanded terms.[br][br]Pascal's triangle and the binomial expansion are valuable tools in combinatorial mathematics and algebra, aiding in various calculations and problem-solving techniques.[/size]
[size=150]What do you observed?[/size]