B.Sc. MATHEMATICS I YEAR

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B.Sc. MATHEMATICS I YEAR DJMB : ALGEBRA AND SEQUENCES AND SERIES SYLLABUS Unit I: Theory of equation: Every equation f(x) = 0 of n th degree has n roots, Symmetric functions of the roots in terms of the coefficients Sum of the r th powers of the roots Newton s theorem Descartes rule of sign Rolle s theorem. Unit II: Reciprocal Equation Transformation of equation Solution of cubic and biquadratic equation Cardon s land Ferrari s methods Approximate solution of numerical equations Newton s and Horner s methods. Unit III: Sequence and series : Sequence limits, bounded, monotonic, convergent, oscillatory and divergent sequence Algebra of limits Subsequence Cauchy sequence in R and Cauchy s general principle of convergence. Unit IV: Series convergence, divergence geometric, harmonic, exponential, binomial and logarithmic series Cauchy s general principle of convergence Comparison test tests of convergence of positive termed series Kummer s test, ratio test, Raabe s test, Cauchy s root test, Cauchy s condensation test. Unit V: Summation of series using Binomial, Exponential and Logarithmic series. Books for reference:. Algebra Vol.I, T.K. Manickavachagompillai & others. Sequences and series, S. Arumugam & others 3. Real Analysis Vol.I, K. ChandrasekaraRao & K.S. Narayanan 4. Infinite series, Bromwich.

DJMB : ALGEBRA AND SEQUENCES AND SERIES S.No Contents Page.No UNIT I. Theory of Equations. Every equation f(x) = 0 of nth degree has n roots 04 3. Symmetric functions of the roots in terms of the 0 coefficients 4. Sum of the rth powers of the roots 7 5. Newton s theorem 8 6. Descartes rules of sign 39 7. Rolle s theorem 40 UNIT II 8. Reciprocal Equation 44 9. Transformation of equation 5 0. Solution of cubic and bi quadratic equation 56. Cardon s land Ferrari s methods 6. Approximate solution of numerical equations 70 3. Newton s and Horner s methods 73 UNIT III 4. Sequence and series 5. Sequence limits 86 6. bounded, monotonic, convergent, oscillatory and 87 divergent sequence 7. Algebra of limits 97 8. Subsequence 08 9. Cauchy sequence in R and Cauchy s general principle of convergence UNIT IV 0. Series. convergence, divergence geometric, harmonic, 6 exponential, binomial and logarithmic series. Cauchy s general principle of convergence 8 3. Comparison test 4. Tests of convergence of positive termed series 5. Kummer s test, ratio test, Raabe s test, Cauchy s root 8 test, Cauchy s condensation test. UNIT V Summation of series 6. Binomial series 4 7. Exponential series 6 8. Logarithmic series 77

UNIT I: THEORY OF EQUATION Theory of equation: Every equation f(x) = 0 of n th degree has n roots, Symmetric functions of the roots in terms of the coefficients Sum of the r th powers of the roots Newton s theorem Descartes rule of sign Rolle s theorem. Theory of Equations: Every equation f(x) = 0 of the n th degree has n roots Let f(x) be the polynomial a0x n +ax n + +an. We assume that every equation f(x) = 0 has at least one root real or imaginary Let α be a root of f(x) = 0. Then f(x) is exactly divisible by x α, so that f(x) = (x α) φ (x) where φ (x) is a rational integral function of degree n. Again φ (x) = 0 has a root real or imaginary and let that root be a. Then φ (x) is exactly divisible by x α, so that φ (x) = (x α) φ (x) where φ (x) is a rational integral function of degree n. f(x) = (x α) (x α) φ (x). By continuing in this way, we obtain f(x) = (x α)(x α). (x αn) φ n(x) where φ n(x) is of degree n n, i.e., zero ϕn(x) is a constant. Equating the coefficients of x n on both sides we get φ n(x) = coefficients of x n = a0 f(x) = a0 (x α)(x α). (x αn). Hence the equation f(x) =0 has n roots, since f(x) vanished when x has any one of the values α, α, αn. If x is given any value different from any one of these n roots, then no factor of f(x) can vanish and the equation is not satisfied. Hence f(x) = 0 cannot have more than n roots. 3

Example.. If α be a real root of the cubic equation x 3 + px +qx + r = 0, of which the coefficients are real, show that the other two roots of the equation are real, if p > 4q + pα + 3α. Since α is a root of the equation, x 3 + px +qx + r is exactly divisible by x α. Let x 3 + px +qx + r (x α) (x + ax +b). Equating the coefficients of powers of x on both sides, we get p = α + a q = aα + b r = b α a = p + α and b = q + aα = q + α (p + α) = q + pα + α. The other two roots of the equation are the roots of x + (p + α)x + q + pα + α = 0 Which are real if (p+ α) 4 (q+ pα + α ) 0 i.e.,p pα 4q 3α 0 i.e., p 4q + pα + 3α. Example. If x, x, x3 xn are the roots of the equation (a x) (a x) (an x)+ k = 0, then show that a, a., an are the roots of the equation (x x) (x x) (xn x) k = 0. Since x, x, x3 xn are the roots of the equation (a x) (a x) (an x) + k = 0 We have (a x) (a x) (an x) + k (x x) (x x) (xn x) (x x) (x x) (xn x) k (a x) (a x) (an x). a, a, a3 an are the roots of (x x) (x x) (xn x) k = 0. 4

Example. 3. Show that if a, b, c are real, the roots of + + = 3 x+a x+b x+c x are real. Simplifying we get x (x + b) (x + c) + x (x +c) (x + a) + x (x + a) (x + b) 3 (x + a) (x + b) (x + c) = 0 Let f(x) be the expression on the left-hand side. It can easily be seen that f (x) is a quadratic function of. f ( a) = a (b a) (c a) f ( b) = b (c b) (a b) f ( c) = c (a c) (b c). Without loss of generally let us assume that a> b> c and a, b, c are all positive. Then a b, b c, a c are positive. f ( a) = ve. f ( b) = + ve. f ( c) = ve. c. The equation has at least one real root between a and b, and another between b and The equation can have only two roots since f (x) = 0 is a quadratic equation. The roots of the equations are real. Exercises. If x 3 + 3px + q has a factor of the form x ax + a, show that q + 4p 3 = 0.. If px 3 + qx + r has a factor of the form x + ax +, prove that p = pq + r. 3. If px 5 + qx + r has a factor of the form x + ax +, prove that (p r ) (p r + qr) = p q. 4. If a, b, c are all positive, show that all the roots of 5

+ + x a x b x c = x are real. 5. If a > b > c > d and E, A, B, C, D are positive, show that the equation E + A + B + C + D = 0 x a x b x c x d if has no root between a and b, one root between b and c and one between c and d and E > 0, there is a root > d and if E < 0, there is a root < a. 6. If a < b < c < d, show that the roots of (x a) (x c) = k (x b) (x d) are real for all values of k. In an equation with rational coefficients, imaginary roots occur in pairs. Let the equation be f(x) = 0 and let α + iβ be an imaginary root of the equation. We shall show that α iβ is also a root. We have (x α iβ)( x α + iβ) = (x α) + β () If f(x) is divided by (x α) + β, let the quotient be Q(x) and the remainder be Rx + R' Here Q(x) is of degree (n ). f(x) = {( x α) + β } Q(x) + Rx + R' () Substituting (α + iβ) for x in the equation (), we get f(α + iβ) = {( α + iβ α) + β } Q(α + iβ) + R(α + iβ) + R' = R(α + iβ) + R' But f(α + iβ) = 0 since α + iβ is a root of f(x) = 0. Therefore R(α + iβ) + R' = 0. Equating to zero the real and imaginary parts Rα + R' = 0 and Rβ = 0. 6

Since β 0, R = 0 and so R' = 0 f(x) = {( x α) + β }Q(x). α iβ is also a root of f(x) = 0. Solved Problems. Form a rational cubic equation which shall have for roots, 3. Since 3 is a root of the equation, 3 + is also a root. So we have to form an equation whose roots are, 3, 3 +. Hence the required equation is (x )(x 3 )( x 3 + ) = 0 (x ){(x 3) + } = 0 (x )(x 6x + ) = 0 x 3 7x +7x = 0.. Solve the equation x 4 + 4x 3 + 5x + x = 0 of which one root is +. equation. Imaginary roots occur in pairs. Hence is also a root of the Therefore the expression on the left side of equation has the factors (x + )(x + + ). +.. The expression on the left side is exactly divisible by (x + ) +, i.e.,x + x Dividing x 4 + 4x 3 + 5x + x by x + x +, we get the quotient x + x Therefore x 4 + 4x 3 + 5x + x = (x +x + )(x + x ). Hence the other roots are obtained from x + x = 0. Thus the other roots are ±. 7

3. Show that a x α + b x β + c real. x γ x + δ = 0 has only real roots if a, b, c, α, β, γ, δ are If possible let p + iq be a root. Then p iq is also root. Substituting these values for x, we have a + b + c p+iq α p+iq β a + b + c p iq α p iq β p+iq γ p iq γ Substituting () from (), we get a iq (p α) +q iq b iq (p β) +q p iq + δ = 0 () p + iq + δ = 0 () c iq (p γ) +q iq = 0 a + b + c (p α) +q (p β) +q (p γ) +q + 3 = 0 This is only possible when q = 0 since the other factor cannot be zero. In that case the roots are real. In an equation with rational coefficients irrational roots occur in pairs. Let f(x) = 0 denotes the equation and suppose that a + b is a root of the equation where a and b are rational and b is irrational. We now show that a b is also a root of the equation () R'. (x a b )( x a + b) = (x a) b.. If f(x) is divided by (x a) b, let the quotient be Q(x) and the remainder be Rx + Here Q(x) is a polynomial of degree (n ). f(x) = {(x a) b} Q(x) + Rx + R'.() 8

Substituting a + b for x in (), we get f(a + b) = {( a + b a) b} Q(a + b) + R(a + b) + R' = R(a + b) + R' but f(a + b) = 0, since a + b is a root of f(x) = 0. Ra + R' + R b = 0. Equating the rational and irrational parts, we have Ra + R' = 0 and R = 0. R' = 0. Hence f(x) = {(x a) b}q(x). = (x a b)(x a + b)q(x). a b is a root of f(x) = 0. Solved Problems Example. Frame an equation with rational coefficients, one of whose root is 5 + Then the other roots are 5, 5 +, 5 = 0 Hence the required equation is (x 5 )(x 5 + )(x + 5 + )(x + 5 ) i.e.{(x 5) } {( x + 5) } = 0 i.e.(x x 5 +3)( x + x 5 +3) = 0 i.e.(x + 3) 4x.5 = 0 i.e. x 4 4x + 9 = 0. 9

Example. Solve the equation x 4 5x 3 + 4x + 8x 8 = 0 given that one of the roots is 5. Since the irrational roots occur in pairs, + 5 is also a root. The factors corresponding to these roots are (x + 5 )( x 5), i.e.(x ) 5 i.e. x x 4. Dividing x 4 5x 3 + 4x + 8x 8 by x x 4, we get the quotient x 3x +. Therefore x 4 5x 3 + 4x + 8x 8 = (x x 4)(x 3x + ) = (x x 4)(x )(x ) The roots of the equation are ± 5,,. Example 3. Form the equation with rational coefficients whose roots are (i) + 5, 5 (ii) 3 +. Solution : (i) + 5, 5 Then the other roots are + 5, 5, 5, 5 + Hence the equation is (x + 5 )(x 5 )(x 5 )(x 5 + ) = 0 {(x ) ( 5 ) } (x 5) 3 = 0 (x x +6) (x 0x + 6) = 0 x 4 x 3 + 7x 3x + 676 = 0. (ii) 3 + Then the other roots are 3 +, 3, 3 +, 3 x + 3 3 x 3 3 = 0 0

(x + 3x + 5)(x 3x + 5) = 0 x 4 x + 5 = 0. Example 4. Solve : x 4 4x 3 + 8x + 35 = 0 given that + i 3 is a root of it. Since the irrational roots occur in pair, i 3 is also a root. The factors corresponding to these roots are (x ) (i 3) x 4x + 7. Dividing x 4 4x 3 + 8x + 35 by x 4x + 7, we get the equation x + 4x + 5 x 4 4x 3 + 8x + 35 = (x 4x + 7)( x + 4x + 5) The roots of the equation are ± i 3, ± i Example 5.Solve the equation x 6 3x 5 + 5x 4 + 6x 3 7x + 8 = 0 given that one root is. Then the other roots are, +,, + x 3 x + 3 = 0 (x x + 3)(x + x + 3) = 0 x 4 x +9 = 0 Dividing x 6 3x 5 + 5x 4 + 6x 3 7x + 8 by x 4 x + 9 we get the equation x 3x + 9 x 6 3x 5 + 5x 4 + 6x 3 7x + 8 = (x 4 x +9)( x 3x + 9) Exercises The roots of the equation are ±,, ±, 3. ±i 7 / 4. Find the equation with rational coefficients whose roots are (i) 4 3, 5 +. (ii) 5.

. Solve the equation x 4 + x 3 5x + 6x + = 0 given that + is a root of it 3. Solve the equation x 6 4x 5 x 4 + 40x 3 + x 4x = 0 given that one root is 3. Answer :. (i)x 4 0x 3 9x + 480x 39= 0,(ii) x 4 8x + 36 = 0,. ± 3, 3. ± 3, ± 5. Relation between the roots and coefficient of equations. Let the equation be x n + p x n- + p x n- + + p n- x + p n = 0.If this equation has the roots α, α, α 3,, α n, then we have x n + p x n- + p x n- + + p n- x + p n = (x α )(x α ) ( x α n ) = x n α x n + α α x n +( ) n α, α, α 3,, α n = x n S x n- + S x n- + ( ) n S n Where S r is the sum of the products of the quantities α, α, α 3,, α n taken r at a time. Equating the coefficients of like powers on both sides, we have p = S = sum of the roots. ( ) p = S = sum of the products of the roots taken two at a time. ( ) 3 p 3 = S 3 = sum of the products of the roots taken three at a time. ( ) n p n = S n = product of the roots. If the equation is a 0 x n + a x n- + a x n- + + a n- x + a n = 0. Divide each term of the equation by a 0. The equation becomes x n + a x n + a x n + + a n x + a n = 0 a 0 a 0 a 0 a 0 and so we have α = a a 0 α α = a a 0 α α α 3 = a 3 a 0 α α α 3 α n = ( ) n a n a 0 These n equations are of no help in the general solution of an equation but they are often helpful in the solution of numerical equations when some special relation is known to exist among the roots. The method is illustrated in the examples given below.

Example. Show that the roots of the equation x 3 + px + qx + r = 0 are in Arithmetical progression if p 3 9pq + 7r = 0 show that the above condition is satisfied by the equation x 3 6x + 3x 0 = 0. Hence or otherwise solve the equation. Let the roots of the equation x 3 + px + qx + r = 0 be α δ, α, α + δ. We have from the relation of the roots and coefficients α δ+ α + α + δ = p (α δ) α + ( α δ)( α + δ) + α (α + δ) = q (α δ)α (α + δ) = r. Simplifying these equation, we get 3α = p () 3 α δ = q () α 3 α δ = r. (3) From (), α = p. 3 From (), δ = 3. p 3 / q = p q. 3 Substituting these value in (3), we get. p 3 /3. p / 3.p q/ = r 3 i.e.,p 3 9pq + 7 r = 0. In the equation x 3 6x + 3x 0 = 0. p = 6, q = 3, r = 0. Therefore p 3 9pq + 7 r = ( 6) 3 9( 6)3 + 7( 0) = 0 The condition is satisfied and so the roots of the equation are in arithmetical progression. In this case the equations (), (), (3) become 3α = 6 3 α δ = 3 α 3 α δ = 0. α =, δ = 3 Therefore δ = i.e., δ = ± i. The roots are i,, + i. 3

Example. Find the condition that the roots of the equation ax 3 + 3bx + 3cx + d = 0 may be in geometric progression. Solve the equation 7x 3 + 4x 8x 8 = 0 whose roots are in geometric progression. Let the roots of the equation be k, k, kr. r Therefore k r k + k + kr = 3b a + r k + k r = 3c a k 3 = d a..().()..(3) From (), k. r From (), k. r + + r/ = 3b a. + + r/ = 3c a. Divided one by the other, we get k = c b Substituting this value of k in (3), we get. c b /3 = d a. Therefore ac 3 = b 3 d. In the equation 7x 3 + 4x 8x 8 = 0 k k r + k + kr = 4 7 r + k + k r = 8 7 k 3 = 8 7 k = 3. Substituting the value of k in(4), we get 3. r + + r/ = 4 7 3r + 0r +3 = 0 (3r + )(r + 3) = 0 Therefore r = or r = 3. 3 For both the value of r, the roots are, 3, 9. 4

Example 3. Solve the equation 8x 3 8x 36x + 8 = 0 whose roots are in harmonic progression. Let the roots be α, β, γ. Then β = α + γ i.e., γα = βγ + αβ () From the relation between the coefficients and the roots we have α + β + γ = 8 8 αβ + βγ + γα = 36 8 α β γ = 8 8.()..(3).(4) From () and (3), we get γα + γα = 36 8 3γα = 36 8 Therefore γα = 4 7.(5) Substituting this value of γα in (4), we get β. 4 7 / = 8 8 Therefore β = 3. From (), we have α + γ = 8 8 3 = 4 9 (6) From (5)and (6), we get α = 9 and γ = 3 5

The roots are 9, 3 and 3. Example 4. If the sum of two roots of the equation x 4 + px 3 + qx + rx + s = 0 equals the sum of the other two, prove that p 3 +8r = 4pq. Let the roots of the equation be α, β, γ and δ Then α + β = γ + δ..() From the relation of the coefficients and the roots, we have α + β + γ + δ = p () αβ + αγ + αδ + βγ + βδ+ γδ = q..(3) αβγ + αβδ + αγδ + βγδ = r..(4) αβγδ = s..(5) From () and (), we get (α + β ) = p (6) (3) can be written as αβ + γδ + (α + β)(γ +δ) = q i.e., (αβ + γδ) + (α + β) = q (7) (4) can be written as αβ(γ + δ) + γδ(α + β) = r (αβ+ γδ)(α + β) = r (8) From (6) and (7), we get αβ + γδ + p = q 4 αβ + γδ = q p 4..(9) 6

From (8), we get p (αβ+ γδ) = r αβ+ γδ = r p. (0) Equating (9) and (0), we get q p 4 = r p 4pq p 3 = 8r p 3 + 8r = 4pq. Example 5. Solve the equation x 4 x 3 + 4x + 6x = 0 given that two of its roots are equal in magnitude and opposite in sign. Let the roots of the equation be α, β, γ and δ Here γ = δ i.e., γ + δ = 0 () From the relation of the roots and coefficients α + β + γ + δ = αβ + αγ + αδ + βγ + βδ+ γδ = 4 ()..(3) αβγ + αβδ + αγδ + βγδ = 6..(4) αβγδ =..(5) from () and (), we get α + β =.(6) (3) can be written as αβ + γδ + (α + β)(γ +δ) = 4 αβ + γδ = 4 (7) (4) can be written as αβ(γ + δ) + γδ(α + β) = 6 7

γδ(α + β) = 6..(8) from (6) and (8), we get γδ = 3..(9) but γ + δ = 0 γ = 3, δ = 3. From (7) and (9), we get αβ = 7 α and β are the roots of x x + 7 = 0. α = + 6, β = 6 Therefore the roots of the equation are ± 3, ± 6. Example 6. Find the condition that the general bi quadratic equation ax 4 + 4bx 3 + 6cx + 4dx + e = 0 may have two pairs of equal roots. Let the roots be α, α, β, β. From the relations of coefficients and roots α +β = 4b a.() α + β + 4αβ = 6c a () α β + α β = 4d a.(3) α β = e a (4) From (), we get α +β = b a..(5) From (3), we get αβ(α +β) = 4d a αβ = d b (6) From (5) and (6), we get that α, β are the roots of the equation x + b a x + d b = 0 ax 4 + 4bx 3 + 6cx + 4dx + e a.x + b a x + d b / 8

Comparing coefficients 6c = a. 4b a + d b / and e = ad b 3abc = a d + b 3 and eb = ad. Exercises. Solve the equation 6x 3 x + 6x = 0 whose roots are in harmonic progression.. Find the values of a and b for which the roots of the equation 4x 4 6x 3 + ax + bx 7 = 0 are in arithmetical progression. 3. The roots of the equation 8x 3 4x + 7x = 0 are in geometrical progression. Find them. 4. Solve x 4 8x 3 + 4x + 8x 5 = 0, it being given that the sum of two of the roots is equal to the sum of the other two. 5. If two roots of the equation x 4 + px 3 + qx + rx + s = 0 are equal in value but differ in sign, show that r + p s = pqr. 6. Show that the four roots, α, β, γ and δ of the equation x 4 + px 3 + qx + rx + s = 0 will be connected by the relation α β + γ δ = 0 if p s + r = 4qs. 7. Solve the equation x 4 x 3 3x + 4x = 0given that the product of two of the roots is unity. Answer :.,,,.a = 4 or 4 96, b = 4 or, 3., 3 9 9 4 Symmetric function of the roots 3± 5,, 4., 5,, 3, 7., ± 5 If a function involving all the roots of an equation is unaltered in value if any two of the roots are interchanged, it is called a symmetric function of the roots. Let α, α, α 3, α n be the roots of the equation. f (x) = x n + p x n + p x n +. + p n = 0. We have learned that S = Σ α = p S = Σ α α = p 9

S 3 = Σ α α α 3 = p 3.... Without knowing the values of the roots separately in terms of the coefficients, by using the above relations between the coefficients and the roots of an equation, we can express any symmetric function of the roots in terms of the coefficients of the equations. Example. If α, β, γ are the roots of the equations x 3 + px + qx + r = 0, Express the value of Σ α β in terms of the coefficients. We have α + β + γ = p αβ + βγ + γα = q αβγ = r. Σ α β = α β + α γ + β α + β γ + γ α + γ β = (αβ + βγ + γα) (α + β + γ) 3αβγ = q ( p) 3 ( r) = 3r pq. Example. If α, β, γ, δ be the roots of the bi quadratic equation x 4 + px 3 + qx + rx + s = 0, Find () Σ α, () Σ α βγ, (3) Σ α β, (4) Σ α 3 β and (5) Σ α 4. The relations between the roots and the coefficients are α + β + γ + δ = p. αβ + αγ + αδ + βγ + βδ + γδ = q αβγ + αβδ + αγδ + βγδ = r 0

αβγδ = s. Σ α = α + β + γ + δ = (α + β + γ + δ) (αβ + αγ + αδ + βγ + βδ + γδ) = (Σ α) Σ αβ = p q. Σ α βγ = (αβγ + αβδ + αγδ + βγδ) (α + β + γ + δ) 4 αβγδ = (Σ αβγ) (Σ α) 4 αβγδ = pr 4s. Σ α β = α β + α γ + α δ + β γ + β δ + γ δ = (Σ αβ) Σ α βγ 6 αβγδ = q (pr 4s) 6s = q pr + s. Σ α 3 β = (Σ α ) (Σ αβ) Σ α βγ = (p q) q (pr 4s) = p q q pr + 4s. Σ α 4 = (Σ α ) Σ α β = (p q) (q pr + s) = p 4 4p q + q + 4pr 4s. Example 3. If α, β, γ are the roots of the equation x 3 + ax + bx + c =0, from the equation whose roots are αβ, βγ, and γα.

The relations between the roots and coefficients are α + β + γ = a αβ + βγ + γα = b αβγ = c. The required equation is (x αβ) (x βγ) (x γα) = 0 i.e., x 3 x (αβ + βγ + γα) (α βγ + αβ γ + αβγ ) x α β γ = 0 i.e., x 3 x (αβ + βγ + γα) + x αβγ (α + β + γ) (αβγ) = 0 i.e., x 3 bx + acx c = 0 Example 4. If α, β, γ are the roots of the equation x 3 + px + qx + r =0, from the equation whose roots are β + γ α, γ + α β, α + β γ. We have α + β + γ = p αβ + βγ + γα = q αβγ = r. In the required equation S = Sum of the roots = β + γ α + γ + α β + α + β γ = 0. S = Sum of the products of the roots taken two at a time β) = (β + γ α) (γ + α β) + (β + γ α) (α + β γ) + (α + β γ) (γ + α = (α + β + γ 3α) (α + β + γ 3β) + similar terms = ( p 3α) ( p 3β) + ( p 3α) ( p 3γ) + ( p 3γ) ( p 3β)

= (p + 3α) (p + 3β) + (p + 3α) (p + 3γ) + (p + 3γ) (p + 3β) = 3p + 6p (α + β + γ) + 9 (αβ + βγ + γα) = 3p + 6p ( p) + 9q = 9q 3p. S 3 = Products of the roots = (β + γ α) (γ + α β) (α + β γ) = (α + β + γ 3α) (α + β + γ 3β) (α + β + γ 3γ) = ( p 3α) ( p 3β) ( p 3γ) = { p 3 + 3p (α + β + γ) + 9p (αβ + βγ + γα) + 7 αβγ } = { p 3 + 3p ( p) + 9pq 7r } = p 9pq + 7r Hence the required equation is x 3 S x + S x S 3 = 0 i.e., x 3 + (9q 3p ) x (p 3 9pq + 7r) = 0. Example 5. If α, β, γ are the roots of the equation x 3 + px + qx + r =0 prove that () (α + β )( β + γ )( γ + α ) = r pq () α 3 + β 3 + γ 3 = p 3 + 3pq 3r. We have α + β + γ = p αβ + βγ + γα = q αβγ = r. (). (α + β )( β + γ )( γ + α ) = [ (p + α )( p + β)( p + γ)] 3

Since α + β + γ = p α + β = p γ = [p 3 +p (α + β + γ) + p (αβ + βγ + γα) + αβγ] = [p 3 + p p + pq r] = [p 3 p 3 + pq r] = r pq. (). α 3 + β 3 + γ 3-3αβγ = (α + β + γ)[ α + β + γ (αβ + βγ + γα)] α 3 = α, α αβ- + 3αβγ; But α = ( α) αβ Therefore α 3 = α,( α) 3 αβ- + 3αβγ; = p[p 3q] 3r = p3 + 3pq 3r. Example 6. If α, β, γ are the roots of the equation x 3 + qx + r =0 find the values of () () β+γ. β +γ β +γ Since α, β, γ are the roots of the equation x 3 + qx + r = 0. We have α + β + γ = 0 αβ + βγ + γα = q αβγ = r. Therefore β + γ = α (). = = β +γ α 0 + + = αβ = q = q α β γ αβγ r r (). β +γ = (β +γ) βγ β +γ β +γ = 0α + r α α = α 3 +r = α r α α = r ; since α = 0 α But = + + = α β +β γ +γ α = α α β γ α β γ αβγ α = α β ; since α = 0 ( αβ ) (αβγ ) since (αβ + βγ + γα) = α β + 4

α β = q ; = q = q α r r β +γ β +γ = q r = q r r. Example 7. If α, β, γ are the roots of the equation x 3 px + qx r = 0 find the value of (). β +γ βγ (). (β + γ α). Since α, β, γ are the roots of the equation x 3 px + qx r = 0 We have α + β + γ = p αβ + βγ + γα = q αβγ = r. (). β +γ βγ = β +γ βγ + α +β αβ + α +γ αγ = α β +γ +γ α +β +β α +γ αβγ = α β αβγ But α β = ( αβ + βγ + γα)(α + β + γ) 3αβγ α β αβγ ( αβ + βγ + γα )(α + β + γ) 3αβγ = αβγ = qp 3r r. (). (β + γ α) = (α + β + γ α) = (p α) = (p + 4α 4αβ) = 3p + 4 α 4p αβ = 3p + 4. α/ αβ 4p = 3p + 4p 8q 4p = 3p 8q. 5

Example 8. If α, β, γ are the roots of the equation ax 3 + bx + cx + d = 0find the value of α β Since α, β, γ are the roots of the equation ax 3 + bx + cx + d = 0 We have α + β + γ = b a αβ + βγ + γα = c a αβγ = d a =. b (αβγ ) = + + = α +β +γ = (α + β + γ) (αβ + βγ + γα ) α β α β β γ γ α α β γ a /. c a /. d a / = b ac d Exercises. If α, β, γ are the roots of the equation x 3 + px + qx + r =0 find the value of () (β + γ α) 3 + (γ + α β) 3 + (α + β γ) 3. () αβ γ + βγ α + γα β.. If α, β, γ, δ are the roots of the equation x 4 + px 3 + qx + rx + s =0, Evaluate () Σ α βγ, () Σ (β + α + δ) and (3) Σ α. Answer :. ().4r p 3 rp q, ().,. ().pr 4s, ().3p q,(3). r qr r s Sum of the powers of the roots of an equation. powers of the roots Let α, α, α 3,., α n be the roots of an equation f (x) = 0.The sum of the r th i.e., α r + α r + + α n r 6

is usually denoted by S r. We can easily see that S r constitutes a symmetric function of the roots and hence we can calculate the value of S r by the methods described in the previous article. When r is greater than 4, the calculation of S r by the previous method becomes tedious and in those cases, the following two methods can be used profitably. We have f (x) = (x α ) (x α ). (x α n ). Taking logarithms on both sides and differentiating, we get f (x) f (x) = + + + x α x α x α n xf (x) f (x) = x x α + x x α + + x x α n = + α x α x + + α n x = ( α x )- + ( α x )- +.. + ( α n x )- = + α x + α + + α +. + α x + x n x + α n +. + α x + x n +.. + + αn x + α n x +. + α n = n + (Σ α ) x + (Σ α ) n n x n + + x.. + (Σ α r ) x r +. = n + S. x + S. x +. + S r. x r +. S r = Coefficient of xf (x) in the expansion of. x r f (x) 7

Example. Find the sum of the cubes of the roots of the equation x 5 = x + x +. The equation can be written in the form f (x) = x 5 x x = 0 S r = Coefficient of x 3 in the expansion of x (5x 4 x ) x 5 x x = Coefficient of x 3 in 5 x 3 x4 x 3 x 4 x 5 = (5 x 3 x 4) ( x 3 x 4 x 5)- = (5 x 3 x 4) + x 3 + x 4 + x 5 +. x 3 + x 4 + x 5/ + = (5 x 3 x 4) ( + + ) x 3 = 3. Newton s Theorem on the sum of the powers of the roots. Let α, α, α 3,., α n be the roots of an equation f (x) = x n + p x n- + p x n- + p n = 0 and let be S r = α r + α r + + α n r so that S 0 = n. f (x) = (x α ) (x α ). (x α n ). Taking logarithms on both sides and differentiating, we get f (x) = + + + f (x) x α x α x α n i.e., f (x) = f (x) + f (x) f (x) + + x α x α x α n 8

By actual division, we obtain f (x) x α = xn- + (α + p ) x n- + (α + p α + p ) x n-3 +.. (α n + p α n +.+ p n- ) f (x) x α = xn- + (α + p ) x n- + (α + p α + p ) x n-3 +.. (α n + p α n +.+ p n- ). f (x) x α n = xn- + (α n + p ) x n- + (α n + p α n + p ) x n-3 Adding all these functions, we get +.. (α n n + p α n n +.+ p n- ). f (x) = nx n- + (S + np )x n- + (S + p S + np )x n-3 + (S n- + p S n- +. np n- ). But f (x) is also equal to nx n- + (n ) p x n- + (n ) p x n-3 +.+ p n- + p n-. Equating the coefficients in two values of f (x), we obtain the following relations : S + p = 0 S + p S + p = 0 S 3 + p S + p S + 3p 3 = 0 S 4 + p S 3 + p S + p 3 S + 4p 4 = 0.. 9

S n- + p S n- + p S n-3 +. + p n- S + (n ) p n- = 0 From these (n ) relations we can calculate in succession the values of S, S, S 3, S n- in terms of the coefficients p, p, p 3,. p n-. We can extend our results to the sums of all positive powers of the roots, viz., S n, S n+,. S r where r > n. We have x r-n f (x) = x r + p x r- + p x r- + + p n x r-n. Replacing in this identity, x by the roots α, α, α 3,., α n, in succession and adding, we have S r + p S r- + p S r- +. + p n S r-n = 0 Now giving r the values n, n +, n +, successively and observing that S 0 = n, we obtain from the last equation S n + p S n- + p S n- +. + np n = 0 S n+ + p S n + p S n- +. + p n S = 0 S n+ + p S n+ + p S n +. + p n S = 0 and so on. Thus we get S r + p S r- + p S r- +. + rp r = 0, if r < n And S r + p S r- + p S r- +. p n S r-n = 0, if r n. Cor. To find the sum of the negative integral powers of the roots of f (x) = 0, put x = y and find the sums of the corresponding positive powers of the roots of the transformed equation. Example. Show that the sum of the eleventh powers of the roots of x 7 +5x 4 + = 0 is zero. Since is greater than 7, the degree of the equation, we have to use the latter equation in Newton s theorem. 30

If we assume the equation as x 7 + p x 6 + p x 5 + p 3 x 4 + p 4 x 3 + p 5 x + p 6 x + p 7 = 0, we have p = p = p 3 = p 4 = p 5 = p 6 = 0, p 3 = 5, p 7 =. S + p S 0 + p S 9 + p 3 S 8 + p 4 S 7 + p 5 S 6 + p 6 S 5 + p 7 S 4 = 0 i.e., S + 5S 8 + S 4 = 0 () Again S 8 + p S 7 + p S 6 + p 3 S 5 + p 4 S 4 + p 5 S 3 + p 6 S + p 7 S = 0 i.e., S 8 + 5S 5 + S = 0 () Using the first equation in the Newton s theorem S 5 + p S 4 + p S 3 + p 3 S + p 4 S + 5p 5 = 0 i.e., S 5 + 5S = 0 (3) Again S 4 + p S 3 + p S + p 3 S + 4p 4 = 0 i.e., S 4 + 5S = 0 (4) Again S + p S + p = 0 i.e., S = 0 Also S = 0..(5)..(6) From (4), (5) and (6), we get S 4 = 0 From (3), (5), we get S 5 = 0 From (), we get S 8 = 0 3

Substituting the values of S 4, S 8 in (), we get S = 0. Example. If a + b + c + d = 0, show that a 5 + b 5 + c 5 + d 5 5 = a + b + c + d. a 3 + b 3 + c 3 + d 3 3 Since a + b + c + d = 0, we can consider that a, b, c, d are the roots of the equation x 4 + p x 3 + p x + p 3 x+ p 4 = 0 where p = 0. From Newton s theorem on the sums of powers of the roots, we get S 5 + p S 4 + p S 3 + p 3 S + p 4 S = 0..() S 4 + p S 3 + p S + p 3 S + 4p 4 = 0 () S 3 + p S + p S +3p 3 = 0..(3) S + p S + p = 0 (4) S + p = 0 (5) From (5), we get S = 0 From (4), we get S = - p From (3), we get S 3 = - 3p 3 From (), we get S 5-3p p 3 - p 3 p = 0 i.e., S 5 = 5p p 3. s 5 = s. s 3 5 3 i.e., a 5 + b 5 + c 5 + d 5 5 = a + b + c + d. a 3 + b 3 + c 3 + d 3 3. 3

Example 3. Find α 5 + β 5 + where α, β, γ are the roots of the equation γ 5 x 3 + x 3x = 0. Put x = y in the equation, then the equation becomes + 3 y 3 y y = 0 i.e., y 3 +3y y = 0 The roots of the equation are α, β, γ. α 5 + β 5 + γ 5 = S 5 for the equation y 3 + 3y y = 0. From Newton s theorem on the sum of the powers of the roots of the equations, we get S 5 + 3S 4 S 3 S = 0 S 4 + 3S 3 S S = 0 S 3 + 3S S S 0 = 0 S + 3S 4 = 0 S + 3 = 0. S = 3, S = 3, S 3 = 4, S 4 = 49, S 5 = 58. + + α 5 β 5 γ = 58. 5 Example 4. Show that the sum of the m th powers, where m n, of the roots of the equation x n x n- x n-. x = 0 is 3 m. 33

If m n, we get from the Newton s theorem S m S m- S m-.. m. = 0 S m- S m-.. (m ) = 0. Subtracting one from another, we get S m 3 S m- = 0 i.e., S m = + 3 S m- = + 3 ( + 3 S m- ) = + 3. + 3 S m- = + 3. + 3 ( + 3 S m-3 ) = + 3. + 3. + 3 3 S m-3. Continuing like this, we get S m = + 3. + 3. + 3 3. +. + 3 m-. S But S =. S m = + 3. + 3. + 3 3. +. + 3 m-. = (+ 3 + 3 + 3 3 +. + 3 m- ) =. (3m ) = 3 m Example 5. Determine the value of φ(α ) +φ (α ) +. + φ (α n ) Where α, α, α 3,.. α n are the roots of f (x) and φ(x) is any rational and integral function of x. 34

We have f (x) = + + + f(x) x α x α x α n and f (x) φ (x) f(x) = φ (x) x α + φ (x) x α + + φ (x) x α n Performing the division and retaining only the remainders on both sides of the equation, we have R 0 x n + R x n + + R n f(x) = φ (α ) x α + φ (α ) x α + + φ(α n ) x α n. Hence R 0 x n + R x n + + R n = Σ φ(α ) (x α ) ( x α n ). Equating the coefficients of x n on both sides of the equation, We get Σ φ(α ) = R 0. Example 6. If the degree of φ(x) does not exceed n, prove that n φ(α r ) f (α ) = 0. We have partial functions φ (x) f (x) = A x α + A x α + + A n x α n φ(x ) = A x α x α 3 x α n + A x α x α 3 x α n + + A n x α x α x α n. Put x = α. φ(α ) = A α α α α 3 α α n. f (x) = x α x α x α n. f (x) = x α x α 3 x α n + x α x α 3 x α n 35

+.+ x α x α. x α n. f (α ) = α α α α 3. α α n. φ (α ) = A f (α ) i.e., A = φ (α ) f (α ). Hence φ (x) = φ (α ). + φ (α ). + f (x) f (α ) x α f (α ) x α + φ (α n ). f (α n ) x α n = n φ (α r ) r= f (α r ). x α r. n x φ (x) = φ(α r ) f (x) r= f (α r ). x x α r. = n φ (α r ) r= f (α r ). ( α r x ). = n φ(α r ) r= f (α r ) + α r x +. α r x / +. n φ(α r ) f (α r ) r= = term independent of x in x φ (x) f (x). φ (x) is of degree n, f (x) is of degree n. Hence x φ (x) is of degree n. x φ (x) f (x) = B 0x n +B x n +.+B n x n +p x n +.+p n = B0 x +B x +..B n x n + p x +p x +..p n x n Hence in the expansion of x φ (x) f (x) there is no term independent of x. n φ(α r ) r= f (α r ) = 0. 36

Exercises. Show that the sum of the fourth powers of the roots of the equation x 5 +px 3 + qx + s = 0 is p.. If α, β, γ are the roots of x 3 + qx + r =0 prove that () 3s s 5 = 5s 3 s 4. () α 5 + β 5 + γ 5 5 (3) α 7 + β 7 + γ 7 7 = α 3 + β 3 + γ 3 3 = α 5 + β 5 + γ 5 5. α + β + γ.. α + β + γ. 3. Show that the sum of the ninth powers of the roots of x 3 +3x + 9 = 0 is zero. 4. Prove that the sum of the twentieth powers of the roots of the equation x 4 +ax + b = 0 is 50 a 4 b 4b 5. Descartes Rule of signs. An equation f (x) = 0 cannot have more positive roots than there are changes of sign in f (x) Let f(x) be a polynomial whose signs of the terms are + + - - - + - + + + - + -. In this there are seven changes of sign including changes from + to and from to +. We shall show that if this polynomial be multiplied by a binomial (corresponding to a positive root ) whose signs of the terms are +, the resulting polynomial will have atleast one more change of sign than the original. Writing down only the signs of the terms in the multiplication, we have + + + + + + + + + + + + + + + + + + + + + +± ± ± + + ± ± + + 37

Here in the last line the ambiguous sign ± is placed wherever there are two different signs to be added. Here we see in the product () An ambiguity replaces each continuation of sign in the original polynomial. () The sign before and after an ambiguity or a set of ambiguities are unlike and (3) A change of sign is introduced in the end. Let us take the most unfavourable case and suppose that all the ambiguities are replaced by continuations, then the sign of the terms become + + + + + + + + The number of changes of sign is 8. Thus even in the most unfavourable case there is one more change of sign than the number of changes of sign in the original polynomial. Therefore we may conclude in general that the effect of multiplication of a binomial factor x α is to introduce at least one change of sign. Suppose the product of all the factors corresponding to negative and imaginary roots of f(x) = 0 be a polynomial F(x). The effect of multiplying F(x) by each of the factors x α, x β, x γ,.. corresponding to the positive roots, α, β, γ is to introduce at least one change of sign for each, so that when the complete product is formed containing all the roots, we have the resulting polynomial which has at least as many changes of signs as it has positive roots. This is Descartes rule of sign. Descartes rule of signs for negative roots. Let f (x) = (x α ) (x α ) (x α n ). By subtracting x instead of x in the equations, we get f ( x) = ( x α ) ( x α ) ( x α n ). The roots of f ( x) = 0 are α, α,., α n. The negative roots of f(x) = 0 become the positive roots of f( x) = 0. Hence to find the maximum number of negative roots of f(x) = 0, it is enough to find the maximum number of positive roots of f( x) = 0. So we can enunciate Descartes rule for negative roots as follows. 38

No equation can have a greater number of negative roots then there are changes of sign in the terms of the polynomial f ( x). Example. Determine completely the nature of the roots of the equation x 5 6x 4x + 5 = 0. The series of signs of the terms are + +. Here there are two changes of sign. Hence there cannot be more than two positive roots. Changing x into x, the equation becomes x 5 6x + 4x + 5 = 0 i.e., x 5 + 6x 4x 5 = 0. The series of the signs of the terms are + +. Here there is only one change of sign. There cannot be more than one negative root. So the equation has got at the most three real roots. The total number of roots of the equation is 5. Hence there are at least two imaginary roots of the equation. We can also determine the limits between which the real roots lie. x = 0 x 5 6x 4x + 5 = + + + + The positive roots lie between 0 and, and and, the negative root between and. Exercises. Show that the equation x 7 3x 4 x 3 = 0 has at least four imaginary roots.. Show that x 6 + 3x 5x + = 0 has at least four imaginary roots. 3. Prove that the equation x 4 + 3x = 0 has two real and two imaginary roots. 4. Show that x 7 x 4 +0x 3 8 = 0 has at least four imaginary roots. 39

Rolles Theorem. Between two consecutive real roots a and b of the equation f (x) = 0 where f (x) is a polynomial, there lies at least one real root of the equation f (x) = 0. Let f (x) be (x a) m (x b) m φ (x) where m and n are positive integers and φ (x) is not divisible by (x a) or by (x b). since a and b are consecutive real roots of f (x), the sign of φ (x) in the interval a x b is either positive throughout or negative throughout, for if it changes its sign between a and b, then there is a root of φ (x) = 0 that is of f (x) = 0 lying between a and b, which is contrary to the hypothesis that a and b are consecutive roots. f (x) = (x a) m n(x b) n- φ (x) + m(x a) m- (x b) n φ (x) + (x a) m (x b) n φ (x) = (x a) m- (x b) n- χ (x), Where χ (x) = m x b + n (x a) φ (x) + (x a) (x b) φ (x). χ (a) = m a b φ (a) χ (b) = n b a φ (b). χ (a) and χ (b) have different signs since φ (a) and φ (b) have the same sign. χ (x) = 0 has atleast one root between a and b. Hence f (x) = 0 has at least one root between a and b. Cor.. If all the roots of f (x) = 0 are real, then all the roots of f (x) = 0 are also real. If f (x) = 0 is a polynomial of degree n, f (x) = 0 is a polynomial of degree n and each root of f (x) = 0 lies in each of the ( n ) intervals between the n roots of f (x) = 0. Cor.. If all the roots of f (x) = 0 are real, then all the roots of f (x) = 0, f (x) = 0, f (x) = 0 are real. Cor. 3. At the most only one real root of f (x) = 0 can lie between two consecutive roots of f (x) = 0, that is the real roots of f (x) = 0 separate those of f (x) = 0. roots. Cor. 4. If f (x) = 0 has r real roots, then f (x) = 0 cannot have more than (r +) real 40

Cor. 5. f (x) = 0 has at least as many imaginary roots as f (x) = 0. Example. Find the nature of the roots of the equation 4x 3 x + 8x + 0 = 0. Let us consider the function f (x) = 4x 3 x + 8x + 0. We have f (x) = x 4x + 8 = 6(x ) (x 3). Hence the real roots of f (x) = 0 are and 3. So the roots of f (x) = 0, if any will be in the intervals between and, and 3, 3 and + respectively. x : 3 f (x) : + + f (x) must vanish, once in each of the above intervals. Hence f (x) = 0 has three real roots. Example. Show that the equation 3x 4 8x 3 6x + 4x 7 = 0 has no positive, one negative and two imaginary roots. Let f (x) be 3x 4 8x 3 6x + 4x 7. We have f (x) = x 3 4x x 4 = (x+) (x ) (x ). The roots of f (x) = 0 are, +, +. x : + + + f (x) : + + + + 4

f (x) = 0 has a real root lying between and, one between and + and two imaginary roots. We know that f ( + ) = +, f (0) =. The real root lying between and + lies between 0 and +. hence it is a positive root. The other real root lies between and and so it is a negative root. Example 3. Discuss the reality of the roots x 4 + 4x 3 x x + a = 0 for all the values of a. Let f (x) be x 4 + 4x 3 x x + a. f (x) = 4x 3 + x 4x = 4(x + ) (x ) (x + 3). The roots of f (x) = 0 are 3, and. x : 3 + f (x) : + a 9 7+ a a 9 + If a 9 is negative and 7 + a is positive, the four roots of f (x) are real. If 7 < a < 9, f (x) = 0 has four real roots. If a > 9, then f (x) is positive throughout and hence all the rots of f (x) = 0 are imaginary. If a < 7, the sign of f (x) at, 3,,, + are respectively +,,,, +. Hence f (x) = 0 has two real roots and two imaginary roots. Exercises. Prove that all the roots of the equation x 3 8x + 5 = 0 are real.. Find the nature of the roots of the equation () 4x 3 x + 8x + 30 = 0. 4

() x 3 9x + x + 3 = 0. (3) x 4 + 4x 3 0x + 0 = 0. 3. Show that the equation f (x) = (x a) 3 + (x b) 3 + (x c) 3 = 0 has one real and two imaginary roots. Answer :.(). One negative root and two imaginary roots, (). One negative root and two imaginary roots, (3). All the roots are real. 43

UNIT II: RECIPROCAL EQUATION Reciprocal Equation Transformation of equation Solution of cubic and biquadratic equation Cardon s land Ferrari s methods Approximate solution of numerical equations Newton s and Horner s methods. Reciprocal roots. To transform an equation into another whose roots are the reciprocals of the roots of the given equation. Let α, α, α 3,.. α n be the roots of the equation We have x n + p x n- + p x n- + p n = 0. x n + p x n- + p x n- + p n (x α ) (x α ) (x α n ). Put x =, we have y. y /n + p. y /n + p. y /n +..+ p n =. y α /. y α /... y α n / Multiplying throughout by y n, we have p n y n + p n- y n- + p n- y n- + + p y + = 0 Hence the equation = (α α.. α n ). α y /. α y /... α n y / p n y n + p n- y n- + p n- y n- + + p y + = 0 has roots α, α,, Reciprocal equation. α n If an equation remains unaltered when x is changed into its reciprocal, it is called reciprocal equation. 44

Let x n + p x n- + p x n- + + p n- x + p n = 0. () be a reciprocal equation. When x is changed into its reciprocal, we get the transformed x equation p n x n + p n- x n- + p n- x n- + + p x + = 0 x n + p n p n x n- + p n p n x n- +. + p p n x + p n = 0.() Since () is a reciprocal equation, it must be the same as (), p n p n = p, p n p n = p p p n = p n- and p n = p n. p n =. p n = ±. Case i. p n =. Then p n = p, p n = p, p n 3 = p 3, In this case the coefficients of the terms equidistant from the beginning and the end are equal in magnitude and have the same sign. Case ii. p n =, we have p n = p, p n = p,. p = p n-. In this case the terms equidistant from the beginning and the end are equal in magnitude but different in sign. Standard form of reciprocal equations. If α be a root of a reciprocal equation, must also be a root, for it is a root of the transformed α equation and the transformed equation is identical with the first equation, Hence the roots of a reciprocal equation occur in pairs α, α, β, β, 45

When the degree is odd one of its roots must be its own reciprocal. γ = γ i.e., γ =. i.e., γ = ±. If the coefficients have all like signs, then is a root ; if the coefficients of the terms equidistant from the first and last have opposite signs, then + is a root. In either case the degree of an equation can be depressed by unity if we divide the equation by x + or by x. The depressed equation is always a reciprocal equation of even degree with like signs for its coefficients. If the degree of a given reciprocal equation is even, say n = m and if terms equidistant from the first and last have opposite signs, then p m = p m. i.e., p m = 0, so that in this type of reciprocal equations, the middle term is absent. Such an equation may be written as x m + p x(x m- ) +.. 0. Dividing by x, this reduces to a reciprocal equation of like signs of even degree. Hence all reciprocal equations may be reduced to an even degree reciprocal equation with like sign, and so an even degree reciprocal equation with like signs is considered as the standard form of reciprocal equations. A reciprocal equation of the standard form can always be depressed to another of half the dimensions. It has been shown in the previous article that all reciprocal equations can be reduced to a standard form, in which the degree is even and the coefficients of terms equidistant from the beginning and the end are equal and have the same sign. Let the standard reciprocal equation be a 0 x m + a x m- + a x m- +.. a m x m +.+ a x + a 0 = 0. 46

Dividing by x m and grouping the terms equally distant from the ends, we have a 0.x m + x m /+ a.x m + x m /+..+ a m-.x + x /+ a m = 0 Let x + x = z and xr + x r = X r We have the relation X r + = z. X r X r-. Giving r in succession the values,, 3, We have X = z X X 0 = z X 3 = z X X = z 3 3z X 4 = z X 3 X = z 4 4z + X 5 = z X 4 X 3 = z 5 5z 3 + 5z and so on. Substituting these values in the above equation. We get an equation of the m t degree in z. To every root of the reduced equation in z, correspond two roots of the reciprocal equation. Thus if k be a root of the reduced equation, the quadratic x + x = k, i.e., x kx + = 0 gives the two corresponding roots k± k 4 of the given reciprocal equation. Example. Find the roots of the equation x 5 + 4x 4 + 3x 3 + 3x + 4x + = 0. This is a reciprocal equation of odd degree with like signs. (x+) is a factor of x 5 + 4x 4 + 3x 3 + 3x + 4x + The equation can be written as x 5 + x 4 + 3x 4 + 3x 3 + 3x + 3x + x + = 0 i.e., x 4 (x +)+ 3x 3 (x +)+ 3x(x +)+(x +) = 0 i.e., (x +) (x 4 + 3x 3 + 3x + ) = 0. 47

x + = 0 or x 4 + 3x 3 + 3x + = 0. Dividing by x, we get x + 3x + 3 x + x = 0.x + x / + 3.x + x / = 0. Put x + x = z. x + x = z z + 3z = 0 z = 3± 7. Hence x + x = 3± 7 i.e., x + 3 + 7 x + = 0 or x + 3 7 x + = 0. From these equations x can be found. Example. Solve the equation 6x 5 x 4 43x 3 + 43x + x 6 = 0. This is a reciprocal equation of odd degree with unlike signs. Hence x is a factor of the left- hand side. The equation can be written as follows: 6x 5 6x 4 + 5x 4 5x 3 38x + 5x 5x + 6x 6 = 0 i.e., 6x 4 (x )+ 5x 3 (x ) 38x (x )+ 5x(x )+ 6 (x ) = 0 i.e., (x ) (6x 4 + 5x 3 38x + 5x+6) = 0 x = 0 or 6x 4 + 5x 3 38x + 5x + 6 = 0. We have to solve the equation 6x 4 + 5x 3 38x + 5x + 6 = 0. 48

Dividing by x, 6x + 5x 38+ 5 x + 6 x = 0 i.e., 6.x + x /+5.x + / 38 = 0. x Put x + x = z. x + x = z. The equation becomes 6(z ) + 5z 38 = 0 i.e., 6z + 5z 50 = 0 i.e., (z 5) (3z+0) = 0. x + x = 5 or x + x = 0 3 i.e., x 5x + = 0 or 3x + 0x + 3 = 0 i.e., (x ) (x ) = 0 or (3x + ) (x + 3) = 0 i.e., x = or or 3 or 3. The roots of the equation are,,, and 3. 3 Example 3. Solve the equation 6x 6 35x 5 + 56x 4 56x + 35x 6 = 0. There is no mid-term and this is a reciprocal equation of even degree with unlike signs. We can easily see that x is a factor of the expression on left-hand side of the equation. The equation can be written as 6(x 6 ) 35x(x 4 ) + 56x (x ) = 0 i.e., 6(x )( x 4 + x +) 35x(x ) + (x + ) ) + 56x (x ) = 0 49

i.e., (x ) (6x 4 35x 3 + 6x 35x + 6) = 0 i.e., x = or or 6x 4 35x 3 +6x 35x+6 = 0. Dividing by x, we get 6x 35x+ 6 35 x + 6 x = 0. 6.x + x / 35.x + / + 6 = 0. x Put x + x = z. x + x = z. 6(z ) 35z + 6 = 0 i.e., 6z 35z 50 = 0 i.e., (3z 0) (z 5) = 0 z = 0 3 or 5. x + x = 0 3 or x + x = 5 i.e., 3x 0x+3 = 0 or x 5x+ = 0 i.e., (x 3) (3x ) = 0 or (x ) (x ) = 0 i.e., x = 3 or 3 or or The roots of the equation are,, 3, 3, and. Exercises Solve the following equations:-. x 4 0x 3 + 6x 0x + = 0.. x 4 + 3x 3 3x = 0. 3. x 6 9x 5 + 0x 4 3x 3 + 0x 9x + = 0. 4. x 5 + x 4 + x + = x (x +). 5. x 5 5x 3 + 5x = 0. 50

6. x 6 + x 5 + x 4 x x = 0. Answer :.3 ± 8, ± 3,. ±, 3± 5 5.,,, 3± 5 Transformation in general., 6. ±, ±i 3, ±i 3, 3.,, 3± 5, ± 3, 4.,,, 3± 5 Let α, α,., α n be the roots of the equations f (x) = 0, it is required to find an equation whose roots are φ (α ), φ (α ),, φ (α n ). The relation between a root x of f (x) = 0 and a root y of the required equation is y = φ (x). Now if x be eliminated between f (x) = 0 and y = φ (x), an equation in y is obtained which is the required equation. By means of the relations between the roots and coefficients of an equation we can establish a relation between the corresponding roots given and the required equations. A few examples will illustrate the methods of procedure.. Example. If α, β, γ are the roots of the equation x 3 + px + qx + r 0, from the equation whose roots are α βγ, β γα, γ αβ. We have α βγ = α α αβγ, = α α r since αβγ = r = α + α r. y = x + x r. The required equation is obtained by eliminating x between the equations 5

y = x + x... () r x 3 + px + qx + r = 0 () From (), we get x = yr +r Substituting this value of x in the equation (), we get r 3 y 3 + pr(+ r) y + q(+ r) y +(+ r) 3 = 0. Example. If a, b, c be the roots of the equation x 3 + px + qx + r = 0, find the equation whose roots are bc a, ca b, ab c. We have bc a = abc a a = r a a since abc = r. Hence the required equation is obtained by eliminating x between the equations y = r x x.. () and x 3 + px + qx + r = 0 From (), we get x 3 + xy + r = 0..().(3) Subtracting (3) from (), we get px + qx xy = 0 i.e., x(px + q y) = 0 i.e., x = 0 or px + q y = 0. x cannot be equal to zero. px + q y = 0. 5

x = y q p. Substituting this value of x in equation (), we get. y q p /3 + p.. y q p / + q.. y q / + r = 0 p i.e., y 3 + (p 3q) y + (3q p q) y + p 3 r q 3 = 0. Example 3. If α, β, γ are the roots of the equation x 3 6x + 7 = 0, from the equation whose roots are α + α + 3, β + β + 3, γ + γ + 3. Here we have to eliminate x between the equations x 3 6x + 7 = 0 () and y = x + x + 3 i.e., x + x + (3 y) = 0 () Multiplying () by x and subtracting () from it, we get x + (9 y) x 7 = 0.(3) From () and (3), we get x 4 (9 y)(3 y) = x =, 7+(3 y) (9 y) 4 so that (3 y) = (5 y)( y + y 4) i.e., y 3 y + 53y 374 = 0. Example 4. If α, β, γ are the roots of the equation x 3 + px + qx + r = 0, find the value of (α +) (β +) (γ +). 53

From the equation whose roots are α +, β +, γ +. For that, eliminate x between y = x + and x 3 + px + qx + r = 0 () () Equation () can be written as x(x + q) = (px + r) i.e., x(y + q) = {p(y ) + r} since from () x = y. Squaring x (y + q) = {p(y ) + r} i.e., (y ) (y + q) = {p(y ) + r} i.e., y 3 + y term + y term (q ) (p r) = 0. The roots of the equation are α +, β +, γ +. Products of the roots (α +) (β +) (γ +) = (q ) + (p r). Example 5. If α is a root of x (x + ) k(x ) (x + x + ) = 0, prove that α+ is also a root. From the equation whose roots are α+ β +,, γ+, δ+. α β γ δ For that, eliminate x between the equations α y = x+ x...() 54

and x (x + ) k(x ) (x + x + ) = 0..() From (), we get x = y+ y. Substituting this value of x in (), we get. y+ y / y+ + y 3 + k. y+ /...y+ y y / + y+ + y = 0 i.e., (y + ) (y) k..(y ). {(y + ) + y +(y ) } = 0 i.e., 4y (y + ) k..(y ) (4y +y + ) = 0 i.e., y (y + ) k. (y ) (y +y + ) = 0. We get the same equation as the original equation. α+ α is a root of x (x + ) k. (x ) (x +x + ) = 0. Example 6. Find the equation whose roots are the squares of the differences of the roots of the equation x 3 +px + q = 0 ( p and q being real). Hence deduce the condition that all the roots of the cubic shall be real. Let α, β, γ be the roots of the equation x 3 +px + q = 0. We have to form the equation whose roots are (β γ), (γ α), (α β). (β γ) = β + γ βγ = α + β + γ α αβγ α = (α + β + γ ) (αβ+βγ+γα) α αβγ α. Here we have α + β + γ = 0, αβ + βγ + γα = p, αβγ = q. (β γ) = p α + q α. 55

Hence to get the transformed equation eliminate x between the equations y = p x + q x and x 3 +px + q = 0 ()...() () can be written as x 3 +(y + p) x q = 0..(3) Subtracting () from (3), we get (y + p) x 3q = 0. x = 3q y+p. Substituting this value of x in (), we get. 3q y+p /3 + p. 3q /+ q = 0. y+p Simplifying y 3 + 6py + 9p y + 4p + 7q = 0. (β γ), (γ α), (α β) = (4p + 7q ). If α,β,γ are real, then α β, β γ, γ α are real and may be positive or negative. (β γ), (γ α), (α β) are all positive. Hence () (β γ), (γ α), (α β) is +ve i.e., 4p + 7q is ve. () (β γ), (γ α), (α β) is +ve i.e., 6p is +ve i.e., p is ve. 4p + 7q is negative implies that p is ve. The condition for the roots of the equation to be real is 4p + 7q is negative. 56

Cubic equation.. Let the cubic equation be x 3 +ax + b = 0. Method. The equation can be written as x 3 = ax b. The x-coordinates of the intersection of the curves y = x 3 and y = ax b will be give the roots of the equation. y = x 3 curve has a point of inflection at the origin. Method. Multiply the equation by x. We get x 4 + ax + bx = 0 i.e., (x ) + x + (a )x + bx = 0. We can easily see that the roots of the equation are the x- coordinates of the points of intersection of the parabola y = x and the circle y + y + (a )y + bx = 0. Here the origin is to be excluded since we have multiplied the equation by x.. If the cubic equation is ax 3 + bx + cx + d = 0, we can diminish the roots of the cubic by h and get an equation without the x term. One of the above two methods can be adopted to get the roots. The equation can be written as ax 3 = bx cx d i.e., x 3 = b a x c a x d a. The roots are the x-coordinates of the intersection of the curves y = x 3 and y = b a x c a x d a. 57

Example. Find graphically all the roots of x 3 7x + 6 = 0. Method. The equation can be written as x 3 = 7x 6.The x-coordinates of the points of intersection of the curve y = x 3 and the straight line y = 7x 6 will give the roots of the equation.the line y = 7x 6 intersects the curve in three real points and x-coordinates of the points are,, 3. The roots of the equations are,, 3. Method. Multiply the equation by x. We get x 4 7x + 6x = 0 i.e., (x ) + x 8x + 6x = 0. The roots are the x- coordinates of the intersection of the curves y = x and y + y 8y + 6x = 0. 58

The first curve is a parabola and the second is a circle whose centre is ( 3, 4) and the radius 5. By drawing the curves, we can see that the curves intersect at the point whose x- coordinates are,, and 3. The roots of the equation are,, and 3. Example. Show that the equation x 3 3x + 3x 7 = 0 has only one real root. Find the root graphically to the first decimal place. The equation can be written as x 3 = 3x 3x + 7. Hence the root are the x-coordinates of the points intersection of the curves y = x 3 59

and y = 3x 3x + 7. If we draw the two curves on a graph paper we will see that the two curves will intersect only in one point and the x-coordinate of that point is.8. Hence the equation has only one real root and that is.8 approximately. Bi quadratic equations. Let the equation of the bi quadratic be x 4 + ax 3 + bx + cx + d = 0. Two conics in general intersect in four points. Therefore our attempt should be to find two conics, the x- coordinates of whose points of intersection are the roots of the given equation. The equation can be written as (x + a x) a 4 x + bx + cx + d = 0. i.e., (x + a x) +x +(b a 4 )x + cx + d = 0. 60

Let y = x + a x.() Then the equation becomes y + x +(b + a 4 ) (y a x) + cx + d = 0 i.e., x + y a a (b 4 c a The equation () represents a parabola and () a circle. a ) x +(b + 4 ) y + d = 0.() Trace the curves on a graph paper and the x- coordinates of the points of intersection are the roots of the given equation. Example. Solve the equation x 4 x 3 + 4x + 6x 9 = 0 graphically. The equation can be written as (x x) + 3x + 6x 9 = 0 Let y = x x () Then the equation becomes y + x + x + 6x 9 = 0 i.e., x + y + (y+x) + 6x 9 = 0 i.e., x + y + 8x + y 9 = 0 i.e., (x + 4) +(y + ) = 36 i.e., (x + 4) +(y + ) = 6..() Trace the curves () and () on a graph paper. The curves intersect only in two real points. Therefore the given equation has only two real roots and they are approximately.6 and.7. 6

Exercises. Solve graphically the following equations:- () x 3 6x 9 = 0 () x 3 3x = 0 (3) x 3 7x 6 = 0. Solve graphically the following equations:- () x 3 x 33x + 6 = 0 () x 3 x + x 3 = 0 (3) x 3 6x + 9x 4 = 0 (4) x 3 7 = 0 (5) 4x 3 6x + x + = 0 3. Solve graphically by using y = x and a circle or otherwise 3x 4 x + 3x 4 = 0 Cardon s method. Let the equation be x 3 +px + q = 0... () Let x be u + v. Substituting this value of x in equation (), we get 6