36
every next term is 4 smaller than previous so 7th term = -23
The given sequence is 11, 31, 51, 72 The nth term of this sequence can be expressed as an = 11 + (n - 1) × 20 Therefore, the nth term is 11 + (n - 1) × 20, where n is the position of the term in the sequence.
Deduct 4 each time * * * * * The term to value equation is Un = 39 - 4n
94-1-6-11
One of the infinitely many possible rules for the nth term of the sequence is t(n) = 4n - 1
In this case, 22 would have the value of 11.
every next term is 4 smaller than previous so 7th term = -23
an = an-1 + d term ar-1 = 11 difference d = -11 ar = ar-1 + d = 11 - 11 = 0 The term 0 follows the term 11.
I believe the answer is: 11 + 6(n-1) Since the sequence increases by 6 each term we can find the value of the nth term by multiplying n-1 times 6. Then we add 11 since it is the starting point of the sequence. The formula for an arithmetic sequence: a_{n}=a_{1}+(n-1)d
The given sequence is 11, 31, 51, 72 The nth term of this sequence can be expressed as an = 11 + (n - 1) × 20 Therefore, the nth term is 11 + (n - 1) × 20, where n is the position of the term in the sequence.
The counting sequence is making increments of 11,that is, the n-th term will = 11 x nn = 12,t = 12 x 11= 132
The nth term of the sequence is 2n + 1.
The next sequence for 98, 87, 76, 65 is 54 This is an arithmetic sequence with the first term being 98 and the common difference being -11 So the next term is 65+(-11) = 54
Deduct 4 each time * * * * * The term to value equation is Un = 39 - 4n
A position-to-term rule is a method in mathematics used to find the value of a term based on its position in a sequence or pattern. It typically involves using a formula or equation to determine the relationship between a term's position and its value in the sequence.
U5 = a + 5n = 4 U7 = a + 7n = 10 Therefore 2n = 6 and so n = 3 and then a = 4 - 5n = 4 - 15 = -11 So Un = -11 + 3n and therefore, U10 = a + 10n = -11 + 10*3 = -11 + 30 = 19
The nth term in this sequence is 4n + 3.