(a + b)⁴ = a⁴ + 4a³b + 6a²b² + 4ab³ + b⁴ .   .  .  .  .  .  .  .(1)

Notice:  The literal factors are all the combinations of a and b  where the sum of the exponents is 4:  a⁴,  a³b,  a²b²,  ab³,  b⁴.

(a + b)5	=	5C0 a5 + 5C1 a4b + 5C2 a3b² + 5C3 a2b3 + 5C4 ab4 + 5C5 b5
	=	1a5 + a4b + a3b² + a²b3 + ab4 + b5
	=	a5  +  5a4b  +  10a3b²  +  10a²b3  +  5ab4  +  b5

The binomial coefficients here are  1  5  10  10  5  1.  Note the symmetry.

Note also that the coefficient of the first term is 1, and the coefficient of the second term is the same as the exponent of (a + b), which here is 5.

Example 2.   Expand (a − b)⁵.

Example 4.   Write the first four terms of (a + b)ⁿ.  Do not use factorials.

Solution.

(a + b)n	=	nC0 an  +  nC1 an − 1b  +  nC2 an − 2b²  +  nC3 an − 3b3
	=	an  +  nan − 1b  + an − 2b²  +  an − 3b3

Notice:  Each coefficient contains the previous coefficient.   The coefficient

contains the previous coefficient, n.

The next coefficient,

contains the previous one.

Each coefficient is the previous coefficient multiplied  by the exponent of a, and divided by the next exponent of b.

The next coeffient would be this one

multiplied  by (n − 3), and divided by 4:

Example 5.   Use the binomial theorem to expand  (a + b)⁸.

 Solution.   The expansion will begin :

(a + b)⁸ = a⁸ + 8a⁷b

The first coefficient is always 1.  The second is equal to the exponent of the expansion, which here is 8.

Now, the next coefficient will be 8 times the exponent of a -- 7 -- divided by 2.  It will be 56/2 = 28.  We have

(a + b)⁸ = a⁸ + 8a⁷b + 28a⁶b²

The next coefficient is 28· 6 -- divided by 3:

28· 6 / 3 = 28· 2 = 56.

(a + b)⁸ = a⁸ + 8a⁷b + 28a⁶b² + 56a⁵b³

The next coefficient is 56· 5 -- divided by 4:

56· 5 / 4 = 14· 5 = 70.

(a + b)⁸ = a⁸ + 8a⁷b + 28a⁶b² + 56a⁵b³ + 70a⁴b⁴

And now we have come to the point of symmetry.  For, the coefficient of a³b⁵ is equal to the coeffient of a⁵b³, which is 56.  And so on for the remaining coefficients.  Here is the complete expansion:

Example 6.   Write the 5th term in the expansion of (a + b)¹⁰.

 Solution.   In the 1st term, k = 0.  In the 2nd term, k = 1.  And so on.

Pascal's triangle

This triangular array is called Pascal's Triangle.  Each row gives the binomial coefficients.  That is, the row  1  2  1  are the coefficients of (a + b)².  The next row,  1  3  3  1,  are the coefficients of (a + b)³; and so on.  

To construct the triangle, write 1, and below it write 1  1.  Begin and end each successive row with 1.  To construct the intervening numbers, add the two numbers immediately above.

Thus to construct the third row, begin it with 1, then add the two numbers immediately above:  1 + 1.  Write 2.  Finish the row with 1.  

To construct the next row, begin it with 1, and add the two numbers immediately above: 1 + 2.  Write 3.  Again, add the two numbers immediately above:  2 + 1 = 3.  Finish the row with 1.

Example 8.   Expand  (x − 1)⁶.

Problem 1.   In the expansion of (a + b)ⁿ, each term has the form

a^{n − k}b^k,

where k successively takes on the value 0, 1, 2, . . ., n.

is the symbol for the binomial coefficient.

The binomial theorem is the statement that = ?

To see the answer, pass your mouse over the colored area.
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The combinatorial number, ⁿC_k.

Problem 2.   Use factorials to write the general term in the expansion of (a + b)ⁿ.

Problem 3.   

a)   Calculate the coefficient of  a⁴b⁶  in the expansion of (a + b)¹⁰.

¹⁰C₆ = ¹⁰C₄ = 210

b)   The coefficient of which other term is the same?   a⁶b⁴

c)   In the expansion of  (a + b)ⁿ, the coefficient of  a^{n − k}b^k  is the same as
c)   the coefficient of which other term?   a^kb^{n − k}

Problem 4.   Calculate the coefficient of

a)   x¹⁷y³ in the expansion of (x + y)²⁰.   1140

b)   x³y¹⁷ in the expansion of (x + y)²⁰.   1140

c)   x³y¹⁷ in the expansion of (x − y)²⁰.   −1140

d)   x²y¹⁸ in the expansion of (x − y)²⁰.   190

e)   x⁵y⁵ in the expansion of (x − y)¹⁰.   −252

f)   x¹⁰ in the expansion of (x − 1)¹⁵.   −3003

Problem 5.   Write the first four terms of (x + h)ⁿ.  Do not use factorials.

Problem 6.   Compute the first four terms of each of the following.

a)   (a + b)¹⁵   a¹⁵ + 15a¹⁴b + 105a¹³b² + 455a¹²b³

b)   (x − 1)²⁰   x²⁰ − 20x¹⁹ + 190x¹⁸ − 1140x¹⁷

Problem 7.   Consider the expansion of (x + b)³⁰.

a)   What is the exponent of b in the 1st term?   0 

b)   What is the exponent of b in the 3rd term?   2 

c)   In the 25th term?   24 

d)   In the kth term?   k − 1

e)   Write the fourth term, with its coefficient.   4,060x²⁷b³

Problem 8.   Calculate each of the following.

a)   The third term of (a + b)¹¹.   55a⁹b²

b)   The fifth term of (x − y)⁷.   35x³y⁴

c)   The tenth term of (x − 1)¹².   −220x³

Problem 9.   Use Pascal's triangle to expand the following.

a)   (a + b)³  =  a³ + 3a²b + 3ab² + b³

b)   (a − b)³  =  a³ − 3a²b + 3ab² − b³

c)   (x + y)⁴  =  x⁴ + 4x³y + 6x²y² + 4xy³ + y⁴

d)   (x − y)⁴  =  x⁴ − 4x³y + 6x²y² − 4xy³ + y⁴

e)   (x − 1)⁵  =  x⁵ − 5x⁴ + 10x³ − 10x² + 5x − 1

f)   (x + 2)⁵  =  x⁵ + 10x⁴ + 40x³ + 80x² + 80x + 32

g)   (2x − 1)³  =  8x³ − 12x² + 6x − 1

h)   (1 − xy)⁷ 

=  1 − 7xy + 21x²y² − 35x³y³ + 35x⁴y⁴ − 21x⁵y⁵ + 7x⁶y⁶ − x⁷y⁷

In the following Topic we will give a proof of the binomial theorem.