Exercise 31 Page 195

To find all real solutions of 2x^3-3x^2-50x-24=0, we need to find the zeros of the polynomial function. f(x)=2x^3-3x^2-50x-24 The degree of f(x) is 3. Thus, by the Fundamental Theorem of Algebra, we know that f(x)=0 has exactly three roots. Let's find them.

Integer Roots

By the Rational Root Theorem, we know that integer roots must be factors of the constant term. Since the constant term of f(x) is - 24, the possible integer roots are ± 1, ± 2, ± 3, ± 4, ± 6, ± 8, ± 12, and ± 24. Let's check.

x	2x^3-3x^2-50x-24	f(x)=2x^3-3x^2-50x-24
1	2( 1)^3-3( 1)^2-50( 1)-24	- 75 *
- 1	2( - 1)^3-3( - 1)^2-50( - 1)-24	21 *
2	2( 2)^3-3( 2)^2-50( 2)-24	- 120 *
- 2	2( - 2)^3-3( - 2)^2-50( - 2)-24	48 *
3	2( 3)^3-3( 3)^2-50( 3)-24	- 147 *
- 3	2( - 3)^3-3( - 3)^2-50( - 3)-24	45 *
4	2( 4)^3-3( 4)^2-50( 4)-24	- 144 *
- 4	2( - 4)^3-3( - 4)^2-50( - 4)-24	0 ✓
6	2( 6)^3-3( 6)^2-50( 6)-24	0 ✓
- 6	2( - 6)^3-3( - 6)^2-50( - 6)-24	- 264 *
8	2( 8)^3-3( 8)^2-50( 8)-24	408 *
- 8	2( - 8)^3-3( - 8)^2-50( - 8)-24	- 840 *
12	2( 12)^3-3( 12)^2-50( 12)-24	2400 *
- 12	2( - 12)^3-3( - 12)^2-50( - 12)-24	- 3312 *
24	2( 24)^3-3( 24)^2-50( 24)-24	24 696 *
- 24	2( - 24)^3-3( - 24)^2-50( - 24)-24	- 28 200 *

We found that - 4 and 6 are roots for f(x)=0. Therefore, (x+4) and (x-6) are factors of the polynomial. Let's use synthetic division to factor out one of these factors and thus finding the third root. Let's factor out (x+4).

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24

Bring down the first coefficient

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 &&& & c 2 & & &

Multiply the coefficient by the divisor

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 && & c 2 & & &

Add down

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 && & c 2 &-11 & &

▼

Repeat the process for all the coefficients

Multiply the coefficient by the divisor

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 & 44 & & c 2 & -11 & &

Add down

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 & 44 & & c 2 &-11 & -6 &

Multiply the coefficient by the divisor

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 & 44 & 24 & c 2 &-11 & -6 &

Add down

rl IR-0.15cm r - 4 & |rr 2 & -3 &-50 &-24 & -8 & 44 & 24 & c 2 &-11 & -6 & 0

Using synthetic division to remove the first root, -4, left us with the following polynomial. 2x^2-11x-6

Factoring the Remaining Quadratic Factor

We will use the Quadratic Formula to find the remaining factors. To do so, we will need to identify the values of a, b, and c. 2x^2+( - 11)x+( - 6)=0 We can see above that a= 2, b= - 11, and c= - 6. Finally, we will substitute these values into the Quadratic Formula.

x=- b±sqrt(b^2-4ac)/2a

SubstituteValues

Substitute values

x=- ( - 11)±sqrt(( - 11)^2-4( 2)( - 6))/2( 2)

▼

Solve for x and Simplify

MultNegNegOnePar

- a(- b)=a* b

x=11±sqrt((- 11)^2-4(2)(- 6))/2(2)

CalcPow

Calculate power

x=11±sqrt(121-4(2)(- 6))/2(2)

Multiply

Multiply

x=11±sqrt(121+48)/4

AddTerms

Add terms

x=11±sqrt(169)/4

CalcRoot

Calculate root

x=11± 13/4

We can simplify this result into two separate roots.

x=11± 13/4
x_1=11+13/4	x_2=11-13/4
x_1=24/4	x_2=- 2/4
x_1=6	x_2=- 1/2

We already knew that 6 was a root, but now we have found our third root, - 12. In conclusion, - 4, 6, and - 12 are all real solutions of 2x^3-3x^2-50x-24=0.