General Term and Middle Term

For the most part, the binomial theorem is useful in determining the expanded value of an algebraic expression of the type (x + y)n. Finding the value of (x + y)2, (x + y)3, (a + b + c)2 is straightforward and may be accomplished by algebraically multiplying the exponent value by the number of times it appears in the equation. However, calculating the expanded form of (x + y)17 or other similar expressions with larger exponential values necessitates a significant amount of computation. Using the binomial theorem, it is possible to make things a little easier.

When applying this binomial theorem expansion, the exponent value might be either a negative number or a fraction.

The algebraic expansion of powers of a binomial is described by the binomial theorem or binomial expansion. In this theorem, the polynomial “(a + b)n” can be expanded into a sum of terms of the form “axzyc,” where the exponents z and c are non-negative integers and z + c = n, and the coefficient of each term is a positive integer that depends on the values of n and B.

General term of binomial expansion:

The General Term of Binomial Expansion of (x + y)n is as follows,

Tr+1 = nCr. xn-r . yr

In the binomial expansion, the General Term is represented by Tr+1
It is necessary to utilise the General term expansion in order to find the words indicated in the preceding formula
The supplied expansion needs to be expanded in order to locate the terms in the binomial expansion
The binomial expansion of the equation (a + b)n will be as follows:

(a+b)n = nC0. an + nC1. an-1. b + nC2. an-2. b2 + …. + nCn. bn

It is T1 = nC0.an that is the first term in the sequence

The second term in the series is T2 = nC1.an-1.b, and it is the second term in the series
The third term in the series is T3 = nC2.an-2.b2
The nth term in the series is Tn= nCn.bn .The series has a total of n terms

Middle term of the binomial expansion:

If (x + y)n = nCr.xn-r.yr has (n + 1) terms, with the middle term depending on the value of n.

For the Middle Term of a Binomial Expansion, we have two possible scenarios:

If n is even:

If n is an even integer, we convert it to an odd number and consider (n + 1) to be odd, with (n/2 + 1) serving as the middle component in the equation. Simply said, if n is an odd number, we regard it to be an even number.

If n is an even number, then (n + 1) is an odd number. To find out the middle word, do the following:

Take, for example, the common phrase for binomial expansion, which is

Tn/2+1 = nCn/2.xn-n/2. yn/2

Now, in the foregoing equation, we replace “r” with “n/2” to obtain the middle term .

Tr+1 = Tn/2 + 1
Tn/2+1 = nCn/2.xn-n/2.yn/2

If n is odd:

Assuming that n is an odd number, we convert it to an even number and consider (n + 1) to be even, with (n + 1/2) and (n + 3/2) as the middle terms between (n + 1/2) and (n + 3/2). For the most part, we consider odd numbers to be even when they aren’t.

If n is an odd number, we have two middle terms. To locate the middle term, use the following formula:

Take, for example, the common phrase for binomial expansion, which is

T(n-1) /2 = nC(n-1) /2. xn-(n-1) /2. y(n-1) /2

Or,

T(n+1) /2 = nC(n+1) /2. xn-(n+1) /2. y(n+1) /2

In this scenario, we substitute “r” with the two alternative values that were previously mentioned.

When we compare one term to (n + 1/2) terms, we obtain (r + 1) terms.

r + 1 = n + 1/2

r = n + 1/2 -1

r = n -½

When we compare (r + 1) with (n + 3/2), we get the second middle term.

r +1 = n +3/2

r = n + 3/2 – 1

r = n + ½

The two middle terms when n is odd are (n – 1/2) and (n + 1/2).

Conclusion:

The Binomial Expansion is in the middle of its term. According to what we know, the expansion of (a + b)n has an even number of terms (n + 1). We can write the middle term or terms of (a + b)n using the value of n as a starting point. For the most part, the binomial theorem is useful in determining the expanded value of an algebraic expression of the type (x + y)n. Finding the value of (x + y)2, (x + y)3, (a + b + c)2 is straightforward and may be accomplished by algebraically multiplying the exponent value by the number of times it appears in the equation.