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11 x1 t15 04 polynomial theorems (2013)

N
Nigel Simmons

The document discusses two polynomial theorems: 1) The Remainder Theorem states that if a polynomial P(x) is divided by (x - a), the remainder is P(a). This is proven through algebraic manipulation. 2) The Factor Theorem states that if (x - a) is a factor of a polynomial P(x), then P(a) = 0. An example demonstrates finding a factor of a polynomial and factorizing it.

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Polynomial Theorems
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a)
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x)
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a )
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x)
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )  R(a)
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )  R(a) now degree R ( x)  1  R ( x) is a constant
Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R ( x) P  a   (a  a )Q(a )  R (a )  R(a) now degree R ( x)  1  R ( x) is a constant R( x)  R(a)  P(a)
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2)
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11 3 2
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19 3 2
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x).
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 3
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 0 3
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 0  ( x  2) is a factor 3
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 0  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 0  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2 19 x  30  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30 15 x  30
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30 15 x  30 0
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30  P ( x)  ( x  2)  x 2  2 x  15  15 x  30 0
e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15x 30  P ( x)  ( x  2)  x 2  2 x  15  15 x  30  ( x  2)( x  5)( x  3) 0
OR P  x   x 3  19 x  30
OR P  x   x 3  19 x  30  ( x  2)  
OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have?
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need?
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need?
OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15   ( x  2)( x  5)( x  3) 4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15  4x
OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15   ( x  2)( x  5)( x  3) 4x
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!!
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! Fractional factors must be of the form
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 3 2
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0 3 2
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 9 
(ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 9    x  4  2 x  3 2 x  3
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b?
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)?
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3 P x    x  1 x  3Q x   3 x  8
2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3 P x    x  1 x  3Q x   3 x  8  R x   3x  8
2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a.
2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3
2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3
2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3  16  a  3
2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3  16  a  3 a  19
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b?
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function.
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x)
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4)
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x)
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) R4  5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) R4  5 4a  b  5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 4a  b  5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 a  2
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 a  2 b  3
1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 R x   2 x  3 a  2 b  3
2x 1 1 use P   2 Exercise 4D; 1bc, 3ac, 4ac, 7acf, 8bdf, 9b, 12ac, 13, 14, 17, 23*

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11 x1 t15 04 polynomial theorems (2013)

  • 2. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a)
  • 3. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x)
  • 4. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a )
  • 5. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x)
  • 6. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )
  • 7. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )  R(a)
  • 8. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R( x) P  a   (a  a )Q(a )  R (a )  R(a) now degree R ( x)  1  R ( x) is a constant
  • 9. Polynomial Theorems Remainder Theorem If the polynomial P(x) is divided by (x – a), then the remainder is P(a) Proof: P  x   A( x)Q( x)  R( x) let A( x)  ( x  a ) P  x   ( x  a )Q( x)  R ( x) P  a   (a  a )Q(a )  R (a )  R(a) now degree R ( x)  1  R ( x) is a constant R( x)  R(a)  P(a)
  • 10. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2)
  • 11. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11
  • 12. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11 3 2
  • 13. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19 3 2
  • 14. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2
  • 15. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0
  • 16. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x).
  • 17. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 3
  • 18. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 0 3
  • 19. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). P  2    2   19  2   30 0  ( x  2) is a factor 3
  • 20. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 0  ( x  2) is a factor
  • 21. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 0  ( x  2) is a factor
  • 22. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0  ( x  2) is a factor
  • 23. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2  ( x  2) is a factor
  • 24. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x2 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2 19 x  30  ( x  2) is a factor
  • 25. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor
  • 26. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x
  • 27. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x
  • 28. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30
  • 29. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30
  • 30. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30 15 x  30
  • 31. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30 15 x  30 0
  • 32. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2 x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2 x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15 x 30  P ( x)  ( x  2)  x 2  2 x  15  15 x  30 0
  • 33. e.g. Find the remainder when P  x   5 x 3  17 x 2  x  11 is divided by (x – 2) P  x   5 x 3  17 x 2  x  11 P  2   5  2   17  2   2  11  19  remainder when P ( x ) is divided by ( x  2) is  19 3 2 Factor Theorem If (x – a) is a factor of P(x) then P(a) = 0 e.g. (i) Show that (x – 2) is a factor of P  x   x 3  19 x  30 and hence x 2 2x 15 factorise P(x). x  2 x 3  0 x 2  19 x  30 3 P  2    2   19  2   30 x3  2 x 2 0 2x 2 19 x  30  ( x  2) is a factor 2 x2  4 x 15x 30  P ( x)  ( x  2)  x 2  2 x  15  15 x  30  ( x  2)( x  5)( x  3) 0
  • 34. OR P  x   x 3  19 x  30
  • 35. OR P  x   x 3  19 x  30  ( x  2)  
  • 36. OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
  • 37. OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
  • 38. OR P  x   x 3  19 x  30  ( x  2)  leading term  leading term =leading term 
  • 39. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 
  • 40. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
  • 41. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
  • 42. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term  constant  constant =constant
  • 43. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant
  • 44. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have?
  • 45. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x
  • 46. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need?
  • 47. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x
  • 48. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need?
  • 49. OR P  x   x 3  19 x  30  ( x  2)  x 2 leading term  leading term =leading term 15  constant  constant =constant If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4x
  • 50. OR P  x   x 3  19 x  30  ( x  2)  x 2 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
  • 51. OR P  x   x 3  19 x  30  ( x  2)  x 2 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
  • 52. OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15   ( x  2)( x  5)( x  3) 4x
  • 53. OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ? 4x
  • 54. OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15  4x
  • 55. OR P  x   x 3  19 x  30  ( x  2)  x 2 2x 15  constant  constant =constant leading term  leading term =leading term If you where to expand out now, how many x would you have? 15x How many x do you need? 19x How do you get from what you have to what you need? 4 x  2  ?  P ( x)  ( x  2)  x 2  2 x  15   ( x  2)( x  5)( x  3) 4x
  • 56. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36
  • 57. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant
  • 58. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36
  • 59. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!!
  • 60. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! Fractional factors must be of the form
  • 61. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient
  • 62. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4
  • 63. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4
  • 64. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2
  • 65. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2
  • 66. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too
  • 67. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 3 2
  • 68. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0 3 2
  • 69. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2
  • 70. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  
  • 71. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 
  • 72. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 9 
  • 73. (ii) Factorise P  x   4 x 3  16 x 2  9 x  36 Constant factors must be a factor of the constant Possibilities = 1 , 2 , 3 , 4 , 6 , 9 , 12 , 18 , 36 of course they could be negative!!! factors of the constant Fractional factors must be of the form factors of the leading coefficient 1 2 3 4 6 9 12 18 36 Possibilities = , , , , , , , , 4 4 4 4 4 4 4 4 4 1 2 3 4 6 9 12 18 36 = , , , , , , , , 2 2 2 2 2 2 2 2 2 they could be negative too P  4   4  4   16  4   9  4   36 0  ( x  4) is a factor 3 2 P( x)  4 x 3  16 x 2  9 x  36   x  4  4x 2 9    x  4  2 x  3 2 x  3
  • 74. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b?
  • 75. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11
  • 76. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11
  • 77. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)?
  • 78. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1
  • 79. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1
  • 80. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3
  • 81. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3 P x    x  1 x  3Q x   3 x  8
  • 82. 2004 Extension 1 HSC Q3b) Let P(x) = (x + 1)(x – 3)Q(x) + a(x + 1) + b, where Q(x) is a polynomial and a and b are real numbers. When P(x) is divided by (x + 1) the remainder is – 11. When P(x) is divided by (x – 3) the remainder is 1. (i) What is the value of b? P 1  11 b  11 (ii) What is the remainder when P(x) is divided by (x + 1)(x – 3)? P3  1 4a  b  1 4a  12 a3 P x    x  1 x  3Q x   3 x  8  R x   3x  8
  • 83. 2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a.
  • 84. 2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3
  • 85. 2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3
  • 86. 2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3  16  a  3
  • 87. 2002 Extension 1 HSC Q2c) Suppose x 3  2 x 2  a   x  2 Q x   3 where Q(x) is a polynomial. Find the value of a. P  2   3  23  2 22  a  3  16  a  3 a  19
  • 88. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b?
  • 89. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function.
  • 90. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5
  • 91. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x)
  • 92. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4)
  • 93. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5
  • 94. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x)
  • 95. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) R4  5
  • 96. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) R4  5 4a  b  5
  • 97. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 4a  b  5
  • 98. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5
  • 99. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 a  2
  • 100. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 a  2 b  3
  • 101. 1994 Extension 1 HSC Q4a) When the polynomial P(x) is divided by (x + 1)(x – 4), the quotient is Q(x) and the remainder is R(x). (i) Why is the most general form of R(x) given by R(x) = ax + b? The degree of the divisor is 2, therefore the degree of the remainder is at most 1, i.e. a linear function. (ii) Given that P(4) = – 5 , show that R(4) = – 5 P(x) = (x + 1)(x – 4)Q(x) + R(x) P(4) = (4 + 1)(4 – 4)Q(4) + R(4) R(4) = – 5 (iii) Further, when P(x) is divided by (x + 1), the remainder is 5. Find R(x) P 1  5 R4  5 ab 5 4a  b  5  5a  10 R x   2 x  3 a  2 b  3
  • 102. 2x 1 1 use P   2 Exercise 4D; 1bc, 3ac, 4ac, 7acf, 8bdf, 9b, 12ac, 13, 14, 17, 23*