Parabola 1.1.1.1. Conic Sections:Conic Sections:Conic Sections:Conic Sections: A conic section, or conic is the locus of a point which moves in a plane so that its distance from a fixed point is in a constant ratio to its perpendicular distance from a fixed straight line. • The fixed point is called the Focus. • The fixed straight line is called the Directrix. • The constant ratio is called the Eccentricity denoted by e. • The line passing through the focus & perpendicular to the directrix is called the Axis. • A point of intersection of a conic with its axis is called a Vertex. 2.2.2.2. Section of right circular cone by different planesSection of right circular cone by different planesSection of right circular cone by different planesSection of right circular cone by different planes A right circular cone is as shown in the (i) Section of a right circular cone by a plane passing through its vertex is a pair of straight lines passing through the vertex as shown in the (ii) Section of a right circular cone by a plane parallel to its base is a circle as shown in the figure −−−− 3. (iii) Section of a right circular cone by a plane parallel to a generator of the cone is a parabola as shown in the (iv) Section of a right circular cone by a plane neither parallel to any generator of the cone nor perpendicular or parallel to the axis of the cone is an ellipse or hyperbola as shown in the figure −−−− 5 & 6. Figure -5 Figure -6 3D View : 3.3.3.3. General equation of a conic: Focal directrix property :General equation of a conic: Focal directrix property :General equation of a conic: Focal directrix property :General equation of a conic: Focal directrix property : The general equation of a conic with focus (p, q) & directrix lx + my + n = 0 is: (l2 + m2) [(x − p)2 + (y − q)2] = e2 (lx + my + n)2 ≡ ax2 + 2hxy + by2 + 2gx + 2fy + c = 0 4.4.4.4. Dist inguishing var ious conics :Dist inguishing var ious conics :Dist inguishing var ious conics :Dist inguishing var ious conics : The nature of the conic section depends upon the position of the focus S w.r.t. the directrix & also upon the value of the eccentricity e. Two different cases arise. Case (I) When The Focus Lies On The Directrix. In this case ∆ ≡ abc + 2fgh − af2 − bg2 − ch2 = 0 & the general equation of a conic represents a pair of straight lines if: e > 1 ≡ h2 > ab the lines will be real & distinct intersecting at S. e = 1 ≡ h2 > ab the lines will coincident. e < 1 ≡ h2 < ab the lines will be imaginary. Case (II) When The Focus Does Not Lie On Directrix. a parabola an ellipse a hyperbola rectangular hyperbola e = 1; ∆ ≠ 0, 0 < e < 1; ∆ ≠ 0; e > 1; ∆ ≠ 0; e > 1; ∆ ≠ 0 h² = ab h² < ab h² > ab h² > ab; a + b = 0 PARABOLA 5.5.5.5. Defini t ion and TerminologyDefini t ion and TerminologyDefini t ion and TerminologyDefini t ion and Terminology A parabola is the locus of a point, whose distance from a fixed point (focus) is equal to perpendicular distance from a fixed straight line (directrix). Four standard forms of the parabola are y² = 4ax; y² = − 4ax; x² = 4ay; x² = − 4ay For parabola y2 = 4ax: (i) Vertex is (0, 0) (ii) focus is (a, 0) (iii) Axis is y = 0 (iv) Directrix is x + a = 0 Focal Distance: The distance of a point on the parabola from the focus. Focal Chord : A chord of the parabola, which passes through the focus. Double Ordinate: A chord of the parabola perpendicular to the axis of the symmetry. Latus Rectum: A double ordinate passing through the focus or a focal chord perpendicular to the axis of parabola is called the Latus Rectum (L.R.). For y² = 4ax. ⇒ Length of the latus rectum = 4a. ⇒ ends of the latus rectum are L(a, 2a) & L’ (a, − 2a). NOTE : (i) Perpendicular distance from focus on directrix = half the latus rectum. (ii) Vertex is middle point of the focus & the point of intersection of directrix & axis. (iii) Two parabolas are said to be equal if they have the same latus rectum. Examples : Find the equation of the parabola whose focus is at (– 1, – 2) and the directrix the line x – 2y + 3 = 0. Solution. Let P(x, y) be any point on the parabola whose focus is S(– 1, – 2) and the directrix x – 2y + 3 = 0. Draw PM perpendicular to directrix x – 2y + 3 = 0. Then by definition, SP = PM ⇒ SP2 = PM2 ⇒ (x + 1)2 + (y + 2)2 = 2 41 3y2x + +− ⇒ 5 [(x + 1)2 + (y + 2)2] = (x – 2y + 3)2 ⇒ 5(x2 + y2 + 2x + 4y + 5) = (x2 + 4y2 + 9 – 4xy + 6x – 12y) ⇒ 4x2 + y2 + 4xy + 4x + 32y + 16 = 0 This is the equation of the required parabola. Example : Find the vertex, axis, focus, directrix, latusrectum of the parabola, also draw their rough sketches. 4y2 + 12x – 20y + 67 = 0 Solution. The given equation is 4y2 + 12x – 20y + 67 = 0 ⇒ y2 + 3x – 5y + 4 67 = 0 ⇒ y2 – 5y = – 3x – 4 67 ⇒ y2 – 5y + 2 2 5 = – 3x – 4 67 + 2 2 5 ⇒ 2 2 5y − = – 3x – 4 42 ⇒ 2 2 5y − = – 3 + 2 7 x ....(i) Let x = X – 2 7 , y = Y + 2 5 ....(ii) Using these relations, equation (i) reduces to Y2 = – 3X ....(iii) This is of the form Y2 = – 4aX. On comparing, we get 4a = 3 ⇒ a = 3/4. Vertex - The coordinates of the vertex are (X = 0, Y = 0) So, the coordinates of the vertex are − 2 5 , 2 7 [Putting X = 0, Y = 0 in (ii)] Axis: The equation of the axis of the parabola is Y = 0. So, the equation of the axis is y = 2 5 [Putting Y = 0 in (ii)] Focus- The coordinates of the focus are (X = –a, Y = 0) i.e. (X = – 3/4, Y = 0). So, the coordinates of the focus are (–17/4, 5/2) [Putting X = 3/4 in (ii)] Directrix - The equation of the directrix is X = a i.e. X = 4 3 . So, the equation of the directrix is x = – 4 11 [Putting X = 3/4 in (ii)] Latusrectum - The length of the latusrectum of the given parabola is 4a = 3. Self Practice Problems 1. Find the equation of the parabola whose focus is the point (0, 0)and whose directrix is the straight line 3x – 4y + 2 = 0. Ans. 16x2 + 9y2 + 24xy – 12x + 16y – 4 = 0 2. Find the extremities of latus rectum of the parabola y = x2 – 2x + 3. Ans. 4 9 , 2 1 4 9 , 2 3 3. Find the latus rectum & equation of parabola whose vertex is origin & directrix is x + y = 2. Ans. 24 , x2 + y2 – 2xy + 8x + 8y = 0 4. Find the vertex, axis, focus, directrix, latusrectum of the parabola y2 – 8y – x + 19 = 0. Also draw their roguht sketches. Ans. 5. Find the equation of the parabola whose focus is (1, – 1) and whose vertex is (2, 1). Also find its axis and latusrectum. Ans. (2x – y – 3)2 = – 20 (x + 2y – 4), Axis 2x – y – 3 = 0. LL′ = 4 5 . 6.6.6.6. Parametr ic Representat ion:Parametr ic Representat ion:Parametr ic Representat ion:Parametr ic Representat ion: The simplest & the best form of representing the co−ordinates of a point on the parabola is (at², 2at) i.e. the equations x = at² & y = 2at together represents the parabola y² = 4ax, t being the parameter. Example : Find the parametric equation of the parabola (x – 1)2 = –12 (y – 2) Solution. ∵ 4a = – 12 ⇒ a = 3, y – 2 = at2 x – 1 = 2 at ⇒ x = 1 – 6t, y = 2 – 3t2 Self Practice Problems 1. Find the parametric equation of the parabola x2 = 4ay Ans. x = 2at, y = at2. 7.7.7.7. Position of a point Relative to a Parabola:Position of a point Relative to a Parabola:Position of a point Relative to a Parabola:Position of a point Relative to a Parabola: The point (x1 y1) lies outside, on or inside the parabola y² = 4ax according as the expression y1² − 4ax1is positive, zero or negative. Example : Check weather the point (3, 4) lies inside or outside the paabola y2 = 4x. Solution. y2 – 4x = 0 ∵ S1 ≡ y12 – 4x1 = 16 – 12 = 4 > 0 ∴ (3, 4) lies outside the parabola. Self Practice Problems 1. Find the set of value's of α for which (α, – 2 – α) lies inside the parabola y2 + 4x = 0. Ans. a ∈ (– 4 – 2 3 , – 4 + 2 3 ) 8.8.8.8. Line & a Parabola:Line & a Parabola:Line & a Parabola:Line & a Parabola: The line y = mx + c meets the parabola y² = 4ax in two points real, coincident or imaginary according as a >< c m ⇒ condition of tangency is, c = a/m.Length of the chord intercepted by the parabola on the line y = m x + c is: 4 12 2 m a m a m c + −( ) ( ) . NOTE : 1. The equation of a chord joining t1 & t2 is 2x − (t1 + t2) y + 2 at1 t2 = 0.2. If t1 & t2 are the ends of a focal chord of the parabola y² = 4ax then t1t2 = −1. Hence the co−ordinates at the extremities of a focal chord can be taken as (at², 2at) & a t a t2 2 , − 3. Length of the focal chord making an angle α with the x− axis is 4acosec² α. Example : Discuss the position of line y = x + 1 with respect to parabolas y2 = 4x. Solution. Solving we get (x + 1)2 = 4x ⇒ (x – 1)2 = 0 so y = x + 1 is tangent to the parabola. Example : Prove that focal distance of a point P(at2, 2at) on parabola y2 = 4ax (a > 0) is a(1 + t2). Solution. ∵ PS = PM = a + at2 PS = a (1 + t2). Example : If t1, t2 are end points of a focal chord then show that t1 t2 = –1.Solution. Let parabola is y2 = 4ax since P, S & Q are collinear ∴ mPQ = mPS ⇒ 21 tt 2 + = 1t t2 2 1 1 − ⇒ t12 – 1 = t12 + t1t2 ⇒ t1t2 = – 1 Example : If the endpoint t1, t2 of a chord satisfy the relation t1 t2 = k (const.) then prove that the chord always passesthrough a fixed point. Find the point? Solution. Equation of chord joining (at12, 2at1) and (at22, 2at2) is y – 2at1 = 21 tt 2 + (x – at12) (t1 + t2) y – 2at12 – 2at1t2 = 2x – 2at12 y = 21 tt 2 + (x + ak) (∵ t1t2 = k) ∴ This line passes through a fixed point (– ak, 0). Self Practice Problems 1. If the line y = 3x + λ intersect the parabola y2 = 4x at two distinct point's then set of value's of 'λ' is Ans. (– ∞, 1/3) 2. Find the midpoint of the chord x + y = 2 of the parabola y2 = 4x. Ans. (4, – 2) 3. If one end of focal chord of parabola y2 = 16x is (16, 16) then coordinate of other end is. Ans. (1, – 4) 4. If PSQ is focal chord of parabola y2 = 4ax (a > 0), where S is focus then prove that PS 1 + SQ 1 = a 1 . 5. Find the length of focal chord whose one end point is ‘t’. [Ans. 2 t 1ta + ] 9.9.9.9. Tangents to the Parabola y² = 4ax:Tangents to the Parabola y² = 4ax:Tangents to the Parabola y² = 4ax:Tangents to the Parabola y² = 4ax: (i) y y1 = 2 a (x + x1) at the point (x1, y1) ; (ii) y = mx + a m (m ≠ 0) at a m a m2 2 , (iii) t y = x + a t² at (at², 2at). NOTE : Point of intersection of the tangents at the point t1 & t2 is [ at1 t2, a(t1 + t2) ]. Example : Prove that the straight line y = mx + c touches the parabola y2 = 4a (x + a) if c = ma + m a Solution. Equation of tangent of slope ‘m’ to the parabola y2 = 4a(x + a) is y = m(x + a) + m a ⇒ y = mx + a + m 1 m but the given tangent is y = mx + c ∴ c = am + m a Example : A tangent to the parabola y2 = 8x makes an angel of 45° with the straight line y = 3x + 5. Find its equation and its point of contact. Solution. Slope of required tangent’s are m = 31 13 ∓ ± m1 = – 2, m2 = 2 1 ∵ Equation of tangent of slope m to the parabola y2 = 4ax is y = mx + m a . ∴ tangent’s y = – 2x – 1 at − 2, 2 1 y = 2 1 x + 4 at (8, 8) Example : Find the equation to the tangents to the paabola y2 = 9x which goes through the point (4, 10). Solution. Equation of tangent to parabola y2 = 9x is y = mx + m4 9 Since it passes through (4, 10) ∴ 10 = 4m + m4 9 ⇒ 16 m2 – 40 m + 9 = 0 m = 4 1 , 4 9 ∴ equation of tangent’s are y = 4 x + 9 & y = 4 9 x + 1. Example : Find the equations to the common tangents of the parabolas y2 = 4ax and x2 = 4by. Solution. Equation of tangent to y2 = 4ax is y = mx + m a ........(i) Equation of tangent to x2 = 4by is x = m1y + 1m b ⇒ y = 1m 1 x – 2 1)m( b ........(ii) for common tangent, (i) & (ii) must represent same line. ∴ 1m 1 = m & m a = – 2 1m b ⇒ m a = – bm2 ⇒ m = 3/1 b a − ∴ equation of common tangent is y = 3/1 b a − x + a 3/1 a b − . Self Practice Problems 1. Find equation tangent to parabola y2 = 4x whose intercept on y–axis is 2. Ans. 22 xy += 2. Prove that perpendicular drawn from focus upon any tangent of a parabola lies on the tangent at the vertex. 3. Prove that image of focus in any tangent to parabola lies on its directrix. 4. Prove that the area of triangle formed by three tangents to the parabola y2 = 4ax is half the area of triangle formed by their points of contacts. 10.10.10.10. Normals to the parabola y² = 4ax :Normals to the parabola y² = 4ax :Normals to the parabola y² = 4ax :Normals to the parabola y² = 4ax : (i) y − y1 = − y a 1 2 (x − x1) at (x1, y1) ; (ii) y = mx − 2am − am3 at (am2, − 2am) (iii) y + tx = 2at + at3 at (at2, 2at). NOTE : (i) Point of intersection of normals at t1 & t2 are, a (t 12 + t 22 + t1t2 + 2); − a t1 t2 (t1 + t2).(ii) If the normals to the parabola y² = 4ax at the point t1, meets the parabola again at the point t2, then t2 = − + t t1 1 2 . (iii) If the normals to the parabola y² = 4ax at the points t1 & t2 intersect again on the parabola at thepoint 't3' then t1 t2 = 2; t3 = − (t1 + t2) and the line joining t1 & t2 passes through a fixed point(−2a, 0). Example : If the normal at point ‘t1’ intersects the parabola again at ‘t2’ then show that t2 = –t1 – 1t 2 Solution. Slope of normal at P = – t1 and slope of chord PQ = 21 tt 2 + ∴ – t1 = 21 tt 2 + t1 + t2 = – 1t 2 ⇒ t2 = – t1 – 1t 2 . Example : If the normals at points t1, t2 meet at the point t3 on the parabola then prove that(i) t1 t2 = 2 (ii) t1 + t2 + t3 = 0Solution. Since normal at t1 & t2 meet the curve at t3 ∴ t3 = – t1 – 1t 2 .....(i) t3 = – t2 – 2t 2 .....(ii) ⇒ (t12 + 2) t2 = t1 (t22 + 2)t1t2 (t1 – t2) + 2 (t2 – t1) = 0 ∵ t1 ≠ t2 , t1t2 = 2 ......(iii)Hence (i) t1 t2 = 2from equation (i) & (iii), we get t3 = – t1 – t2Hence (ii) t1 + t2 + t3 = 0 Example : Find the locus of the point N from which 3 normals are drawn to the parabola y2 = 4ax are such that (i) Two of them are equally inclined to x-axis (ii) Two of them are perpendicular to each other Solution. Equation of normal to y2 = 4ax is y = mx – 2am – am3 Let the normal is passes through N(h, k) ∴ k = mh – 2am – am3 ⇒ am3 + (2a – h) m + k = 0 For given value’s of (h, k) it is cubic in ‘m’. Let m1, m2 & m3 are root’s ∴ m1 + m2 + m3 = 0 ......(i) m1m2 + m2m3 + m3m1 = a ha2 − ......(ii) m1m2m3 = – a k ......(iii) (i) If two nromal are equally inclined to x-axis, then m1 + m2 = 0 ∴ m3 = 0 ⇒ y = 0(ii) If two normal’s are perpendicular ∴ m1 m2 = – 1 from (3) m3 = a k .....(iv) from (2) – 1 + a k (m1 + m2) = a ha2 − .....(v) from (1) m1 + m2 = – a k .....(vi) from (5) & (6), we get – 1 – a k2 = 2 – a h y2 = a(x – 3a) Self Practice Problems 1. Find the points of the parabola y2 = 4ax at which the normal is inclined at 30° to the axis. Ans. − 3 a2 , 3 a , 3 a2 , 3 a 2. If the normal at point P(1, 2) on the parabola y2 = 4x cuts it again at point Q then Q = ? Ans. (9, – 6) 3. Find the length of normal chord at point ‘t’ to the parabola y2 = 4ax. Ans. 2 2 3 2 t )1t(a4 + =� 4. If normal chord at a point 't' on the parabola y2 = 4ax subtends a right angle at the vertex then prove that t2 = 2 5. Prove that the chord of the parabola y2 = 4ax, whose equation is y – x 2 + 4a 2 = 0, is a normal to the curve and that its length is 6 a3 . 6. If the normals at 3 points P, Q & R are concurrent, then show that (i) The sum of slopes of normals is zero, (ii) Sum of ordinates of points P, Q, R is zero (iii) The centroid of ∆PQR lies on the axis of parabola. 11.11.11.11. Pair of Tangents:Pair of Tangents:Pair of Tangents:Pair of Tangents: The equation to the pair of tangents which can be drawn from any point (x1, y1) to the parabola y² = 4axis given by: SS1 = T² where :S ≡ y² − 4ax ; S1 = y1² − 4ax1 ; T ≡ y y1 − 2a(x + x1). Example : Write the equation of pair of tangents to the parabola y2 = 4x drawn from a point P(–1, 2) Solution. We know the equation of pair of tangents are given by SS1 = T² ∴∴∴∴ (y2 – 4x) (4 + 4) = (2y + 2 (x – 1))2 ⇒ 8y2 – 32x = 4y2 + 4x2 + 4 + 8xy – 8y – 8x ⇒ y2 – x2 – 2xy – 6x + 2y = 1 Example : Find the focus of the point P from which tangents are drawn to parabola y2 = 4ax having slopes m1, m2 suchthat (i) m1 + m2 = m0 (const) (ii) θ1 + θ2 = θ0 (const)Sol. Equation of tangent to y2 = 4ax, is y = mx + m a Let it passes through P(h, k) ∴ m2h – mk + a = 0 (i) m1 + m2 = m0 = h k ⇒ y = m0x (ii) tanθ0 = 21 21 mm1 mm − + = h/a1 h/k − ⇒ y = (x – a) tanθ0 Self Practice Problem 1. If two tangents to the parabola y2 = 4ax from a point P make angles θ1 and θ2 with the axis of the parabola,then find the locus of P in each of the following cases. (i) tan2θ1 + tan2θ2 = λ (a constant)(ii) cos θ1 cos θ2 = λ (a constant)Ans. (i) y2 – 2ax = λx2 , (ii) x2 = λ2 {(x – a)2 + y2} 12.12.12.12. Director C i rc le:Director C i rc le:Director C i rc le:Director C i rc le: Locus of the point of intersection of the perpendicular tangents to a curve is called the Director Circle. For parabola y2 = 4ax it’s equation is x + a = 0 which is parabola’s own directrix. 13.13.13.13. Chord of Contact:Chord of Contact:Chord of Contact:Chord of Contact: Equation to the chord of contact of tangents drawn from a point P(x1, y1) isyy1 = 2a (x + x1). NOTE : The area of the triangle formed by the tangents from the point (x1, y1) & the chord of contact is(y1² − 4ax1)3/2 ÷ 2a. Example : Find the length of chord of contact of the tangents drawn from point (x1, y1) to the parabola y2 = 4ax.Solution. Let tangent at P(t1) & Q(t2) meet at (x1, y1) ∴ at1t2 = x1 & a(t1 + t2) = y1 ∵ PQ = 22122221 ))tt(a2()atat( −+− = a )4)tt)((tt4)tt(( 22121221 ++−+ = 2 22 11 2 1 a )a4y)(ax4y( +− Example : If the line x – y – 1 = 0 intersect the parabola y2 = 8x at P & Q, then find the point of intersection of tangents at P & Q. Solution. Let (h, k) be point of intersection of tangents then chord of contact is yk = 4(x + h) 4x – yk + 4h = 0 .....(i) But given is x – y – 1 = 0 ∴ 1 4 = 1 k − − = 1 h4 − ⇒ h = – 1, k = 4 ∴ point ≡ (–1, 4) Example : Find the locus of point whose chord of contact w.r.t to the parabola y2 = 4bx is the tangents of the parabola y2 = 4ax. Solution. Equation of tangent to y2 = 4ax is y = mx + m a ......(i) Let it is chord of contact for parabola y2 = 4bx w.r.t. the point P(h, k) ∴ Equation of chord of contact is yk = 2b(x + h) y = k b2 x + k bh2 .....(ii) From (i) & (ii) m = k b2 , m a = k bh2 ⇒ a = 2 2 k hb4 locus of P is y2 = x a b4 2 . Self Practice Problems 1. Prove that locus of a point whose chord of contact w.r.t. parabola passes through focus is directrix 2. If from a variable point ‘P’ on the line x – 2y + 1 = 0 pair of tangent’s are drawn to the parabola y2 = 8x then prove that chord of contact passes through a fixed point, also find that point. Ans. (1, 8) 14.14.14.14. Chord with a given middle point :Chord with a given middle point :Chord with a given middle point :Chord with a given middle point : Equation of the chord of the parabola y² = 4ax whose middle point is (x1, y1) is y − y1 = 1y a2 (x − x1) ≡ T = S1 Example : Find the locus of middle point of the chord of the parabola y2 = 4ax which pass through a given point (p, q). Solution. Let P(h, k) be the mid point of chord of parabola y2 = 4ax, so equation of chord is yk – 2a(x + h) = k2 – 4ah. Since it passes through (p, q) ∴ qk – 2a (p + h) = k2 – 4ah ∴ Required locus is y2 – 2ax – qy + 2ap = 0. Example : Find the locus of middle point of the chord of the parabola y2 = 4ax whose slope is ‘m’. Solution. Let P(h, k) be the mid point of chord of parabola y2 = 4ax, so equation of chord is yk – 2a(x + h) = k2 – 4ah. but slope = k a2 = m ∴ locus is y = m a2 Self Practice Problems 1. Find the equation of chord of parabola y2 = 4x whose mid point is (4, 2). Ans. x – y – 2 = 0 2. Find the locus of mid - point of chord of parabola y2 = 4ax which touches the parabola x2 = 4by. Ans. y (2ax – y2) = 4a2b 15.15.15.15. Important Highl ights:Important Highl ights:Important Highl ights:Important Highl ights: (i) If the tangent & normal at any point ‘P’ of the parabola intersect the axis at T & G then ST = SG = SP where ‘S’ is the focus. In other words the tangent and the normal at a point P on the parabola are the bisectors of the angle between the focal radius SP & the perpendicular from P on the directrix. From this we conclude that all rays emanating from S will become parallel to the axis of theparabola after reflection. (ii) The portion of a tangent to a parabola cut off between the directrix & the curve subtends a right angle at the focus. (iii) The tangents at the extremities of a focal chord intersect at right angles on the directrix, and hence a circle on any focal chord as diameter touches the directrix. Also a circle on any focal radii of a point P (at2, 2at) as diameter touches the tangent at the vertex and intercepts a chord of length a 1 2+ t on a normal at the point P.. (iv) Any tangent to a parabola & the perpendicular on it from the focus meet on the tangent at the vertex. (v) If the tangents at P and Q meet in T, then: ⇒ TP and TQ subtend equal angles at the focus S. ⇒ ST2 = SP. SQ & ⇒ The triangles SPT and STQ are similar. (vi) Semi latus rectum of the parabola y² = 4ax, is the harmonic mean between segments of any focal chord of the parabola. (vii) The area of the triangle formed by three points on a parabola is twice the area of the triangle formed by the tangents at these points. (viii) If normal are drawn from a point P(h, k) to the parabola y2 = 4ax then k = mh − 2am − am3 i.e. am3 + m(2a − h) + k = 0. m1 + m2 + m3 = 0 ; m1m2 + m2m3 + m3m1 = 2a h a − ; m1 m2 m3 = − k a . Where m1, m2, & m3 are the slopes of the three concurrent normals. Note that ⇒ algebraic sum of the slopes of the three concurrent normals is zero. ⇒ algebraic sum of the ordinates of the three conormal points on the parabola is zero ⇒ Centroid of the ∆ formed by three co−normal points lies on the x−axis. ⇒ Condition for three real and distinct normals to be drawn froma point P (h, k) is h > 2a & k2 < a27 4 (h – 2a)3. (ix) Length of subtangent at any point P(x, y) on the parabola y² = 4ax equals twice the abscissa of the point P. Note that the subtangent is bisected at the vertex. (x) Length of subnormal is constant for all points on the parabola & is equal to the semi latus rectum. Note : Students must try to proof all the above properties. Hyperbola The Hyperbola is a conic whose eccentricity is greater than unity. (e > 1). 1.1.1.1. Standard Equat ion & Definit ion(s)Standard Equat ion & Definit ion(s)Standard Equat ion & Definit ion(s)Standard Equat ion & Definit ion(s) Standard equation of the hyperbola is 12b 2y 2a 2x =− , where b2 = a2 (e2 − 1). Eccentricity (e) : e2 = 1 + b a 2 2 = 1 + C A T A . . 2 Foci : S ≡ (ae, 0) & S′ ≡ (− ae, 0). Equations Of Directrices : x = a e & x = − a e . Transverse Axis : The line segment A′A of length 2a in which the foci S′ & S both lie is called the transverse axis of the hyperbola. Conjugate Axis : The l ine segment B ′B between the two points B ′ ≡ (0, − b) & B ≡ (0, b) is called as the conjugate axis of the hyperbola. Principal Axes : The transverse & conjugate axis together are called Principal Axes of the hyperbola. Vertices : A ≡ (a, 0) & A′ ≡ (− a, 0) Focal Chord : A chord which passes through a focus is called a focal chord. Double Ordinate : A chord perpendicular to the transverse axis is called a double ordinate. Latus Rectum ( ���� ) : The focal chord perpendicular to the transverse axis is called the latus rectum. � = ( )2 2 2b a C A T A = . . . . = 2a (e2 − 1). Note : � (L.R.) = 2 e (distance from focus to directrix) Centre : The point which bisects every chord of the conic drawn through it is called the centre of the conic. C ≡ (0, 0) the origin is the centre of the hyperbola 1 b y a x 2 2 2 2 =− . General Note : Since the fundamental equation to the hyperbola only differs from that to the ellipse in having −b2 instead of b2 it will be found that many propositions for the hyperbola are derived from those for the ellipse by simply changing the sign of b2. Example : Find the equation of the hyperbola whose directrix is 2x + y = 1, focus (1, 2) and eccentricity 3 . Solution. Let P 9x,y) be any point on the hyperbola. Draw PM perpendicular from P on the directrix. Then by definition SP = e PM ⇒ (SP)2 = e2 (PM)2 ⇒ (x – 1)2 + (y – 2)2 = 3 2 14 1yx2 + −+ ⇒ 5 (x2 + y2 – 2x – 4y + 5} = 3 (4x2 + y2 + 1 + 4xy – 2y – 4x) ⇒ 7x2 – 2y2 + 12xy – 2x + 14y – 22 = 0 which is the required hyperbola. Example : Find the eccentricity of the hyperbola whose latus rectum is half of its transverse axis. Solution. Let the equation of hyperbola be 2 2 a x – 2 2 b y = 1 Then transverse axis = 2a and latus–rectum = a b2 2 According to question a b2 2 = 2 1 (2a) ⇒ 2b2 = a2 (∵ b2 = a2 (e2 – 1)) ⇒ 2a2 (e2 – 1) = a2 ⇒ 2e2 – 2 = 1 ⇒ e = 2 3 ∴ e = 2 3 Hence the required eccentricity is 2 3 . 2.2.2.2. Conjugate Hyperbo la :Conjugate Hyperbo la :Conjugate Hyperbo la :Conjugate Hyperbo la : Two hyperbolas such that transverse & conjugate axes of one hyperbola are respectively the conjugate & the transverse axes of the other are called Conjugate Hyperbolas of each other. eg. x a y b 2 2 2 2 1− = & − + = x a y b 2 2 2 2 1 are conjugate hyperbolas of each. Note : (a) If e1 & e2 are the eccentrcities of the hyperbola & its conjugate then e1−2 + e2−2 = 1.(b) The foci of a hyperbola and its conjugate are concyclic and form the vertices of a square. (c) Two hyperbolas are said to be similiar if they have the same eccentricity. (d) Two similar hyperbolas are said to be equal if they have same latus rectum. (e) If a hyperbola is equilateral then the conjugate hyperbola is also equilateral. Example : Find the lengths of transverse axis and conjugate axis, eccentricity, the co-ordinates of foci, vertices, lengths of the latus-rectum and equations of the directrices of the following hyperbolas 16x2 – 9y2 = – 144. Solution. The equation 16x2 – 9y2 = –144 can be written as 9 x2 – 16 y2 = – 1 This is of the form 2 2 a x – 2 2 b y = – 1 ∴ a2 = 9, b2 = 16 ⇒ a = 3, b = 4 Length of transverse axis : The length of transverse axis = 2b = 8 Length of conjugate axis : The length of conjugate axis = 2a = 6 Eccentricity : e = + 2 2 b a1 = + 16 91 = 4 5 Foci : The coªordinates of the foci are (0, + be) i.e., (0, + 5) Vertices : The co–ordinates of the vertices are (0, + b) i.e., (0, + 4) Length of latus–rectum : The length of latus–rectum = b a2 2 = 4 )3(2 2 2 9 Equation of directrices : The equation of directrices are y = + e b y = + )4/5( 4 y = + 5 16 Self Practice Problems : 1. Find the equation of the hyperbola whose focis are (6, 4) and (– 4, 4) and eccentricity is 2. Ans. 12x2 – 4y2 – 24x + 32y – 127 = 0 2. Obtain the equation of a hyperbola with coordinates axes as principal axes given that the distances of one of its vertices from the foci are 9 and 1 units. Ans. 16 x2 – 9 y2 = 1, 16 y2 – 9 x2 = 1 3. The foci of a hyperbola coincide with the foci of the ellipse 25 x2 + 9 y2 = 1. Find the equation of the hyperbola if its eccentricity is 2. Ans. 3x2 – y2 – 12 = 0. 3.3.3.3. Aux i l iary C irc le :Aux i l iary C irc le :Aux i l iary C irc le :Aux i l iary C irc le : A circle drawn with centre C & T.A. as a diameter is called the Auxiliary Circle of the hyperbola. Equation of the auxiliary circle is x2 + y2 = a2. Note from the figure that P & Q are called the "Corresponding Points" on the hyperbola & the auxiliary circle. 4.4.4.4. Parametric Representation :Parametric Representation :Parametric Representation :Parametric Representation : The equations x = a sec θ & y = b tan θ together represents the hyperbola x a y b 2 2 2 2 1− = where θ is a parameter. The parametric equations; x = a coshφ, y = b sinhφ also represents the same hyperbola. Note that if P(θ) ≡ (a sec θ, b tan θ) is on the hyperbola then; Q(θ) ≡ (a cos θ, a sin θ) is on the auxiliary circle. The equation to the chord of the hyperbola joining two points with eccentric angles α & β is given by 2 cos 2 sin b y 2 cos a x β+α = β+α − β−α . 5.5.5.5. Posit ion Of A Point 'P' w.r .t . A Hyperbola :Posit ion Of A Point 'P' w.r .t . A Hyperbola :Posit ion Of A Point 'P' w.r .t . A Hyperbola :Posit ion Of A Point 'P' w.r .t . A Hyperbola : The quantity S1 ≡ 1 b y a x 2 2 1 2 2 1 −− is positive, zero or negative according as the point (x1, y1) lies inside, on or outside the curve. Example : Find the position of the point (5, – 4) relative to the hyperbola 9x2 – y2 = 1. Solution. Since 9 (5)2 – (–4)2 = 1 = 225 – 16 – 1 = 208 > 0, So the point (5,–4) inside the hyperbola 9x2 – y2 = 1. 6. Line And A Hyperbola : The straight line y = mx + c is a secant, a tangent or passes outside the hyperbola 1 b y a x 2 2 2 2 =− according as : c2 > or = or < a2 m2 − b2, respectively.. 7. Tangents : (i) Slope Form : y = m x ± −a m b2 2 2 can be taken as the tangent to the hyperbola x a y b 2 2 2 2 1− = , having slope 'm'. (ii) Point Form : Equation of tangent to the hyperbola 1 b y a x 2 2 2 2 =− at the point (x1, y1) is 1 b yy a xx 2 1 2 1 =− . (iii) Parametric Form : Equation of the tangent to the hyperbola x a y b 2 2 2 2 1− = at the point. (a sec θ, b tan θ) is x sec a y tan b θ θ − = 1 . Note : (i) Point of intersection of the tangents at θ1 & θ2 is x = a 2 cos 2 cos 21 21 θ+θ θ−θ , y = b tan θ+θ 2 21 (ii) If |θ1 + θ2| = pi, then tangetns at these points (θ1 & θ2) are parallel. (iii) There are two parallel tangents having the same slope m. These tangents touches the hyperbola at the extremities of a diameter. Example : Prove that the straight line �x + my + n = 0 touches the hyperbola 2 2 a x – 2 2 b y = 1 if a2�2 – b2 m2 = n2. Solution. The given line is �x + my + n = 0 or y = – m � x – m n Comparing this line with y = Mx + c ∴ M = – m � and c = – m n ..........(1) This line (1) will touch the hyperbola 2 2 a x – 2 2 b y = 1 if c2 = a2M2 – b2 ⇒ 2 2 m n = 2 22 m a l – b2 or a2�2 – b2m2 = n2 Example : Find the equation of the tangent to the hyperbola x2 – 4y2 = 36 which is perpendicular to the line x – y + 4 = 0. Solution. Let m be the slope of the tangent. Since the tangent is perpendicular to the line x – y = 0 ∴ m × 1 = –1 ⇒ m = – 1 Since x2 – 4y2 = 36 or 36 x2 – 9 y2 = 1 Comparing this with 2 2 a x – 2 2 b y = 1 ∴ a2 = 36 and b2 = 9 So the equation of tangents are y = (–1) x + 9)1(36 2 −−× y = –x + 27 ⇒ x + y + 3 3 = 0 Example :Find the equation and the length of the common tangents to hyperbola 2 2 a x – 2 2 b y = 1 and 2 2 a y – 2 2 b x = 1. Solution. Tangent at (a sec φ b tan φ) on the 1st hyperbola is a x sec φ – b y tan φ = 1 .....(1) Similarly tangent at any point (b tan θ, a sec θ) on 2nd hyperbolas is a y sec θ – b x tan θ = 1 .....(2) If (1) and (2) are common tangents then they should be identical. Comparing the co–effecients of x and y ⇒ a sec θ = – b tan φ .....(3) and – b tanθ = a sec φ or sec θ = – b a tanφ ......(4) ∵ sec2θ – tan2θ = 1 ⇒ 2 2 b a tan2φ – 2 2 a b sec2φ = 1 {from (3) and (4)} or 2 2 b a tan2φ – 2 2 a b (1+ tan 2φ) = 1 or − 2 2 2 2 a b b a tan2φ = 1 + 2 2 a b tan2φ = 22 2 ba b − and sec2φ = 1 + tan2 φ = 22 2 ba a − Hence the point of contanct are − ± − ± )ba( b , )ba( a 22 2 22 2 and − ± − ± )ba( a , )ba( b 22 2 22 2 {from (3) and (4)} Length of common tangent i.e., the distance between the above points is )ba( )ba(2 22 22 − + and equation of common tangent on putting the values of secφ and tanφ in (1) is + )ba( x 22 − ∓ )ba( y 22 − = 1 or x ∓ y = + )ba( 22 − Self Practice Problems : 1. Show that the line x cos α + y sin α = p touches the hyperbola 2 2 a x – 2 2 b y = 1 if a2 cos2 α – b2 sin2 α = p2. Ans. p2 = a2 cos2α – b2 sin2α 2. For what value of λ does the line y = 2x + λ touches the hyperbola 16x2 – 9y2 = 144 ? Ans. λ = ± 2 5 3. Find the equation of the tangent to the hyperbola x2 – y2 = 1 which is parallel to the line 4y = 5x + 7. Ans. 4y = 5x ± 3 8. NORMALS:(a)The equation of the normal to the hyperbola x a y b 2 2 2 2 1− = at the point P (x1, y1) on it is 1 2 1 2 y yb x xa + = a2 + b2 = a2 e2. (b) The equation of the normal at the point P (a sec θ, b tan θ) on the hyperbola x a y b 2 2 2 2 1− = is θ + θ tan yb sec xa = a2 + b2 = a2 e2. (c) Equation of normals in terms of its slope 'm' are y = mx ± ( ) 222 22 mba mba − + . Example : A normal to the hyperbola 2 2 a x – 2 2 b y = 1 meets the axes in M and N and lines MP and NP are drawn perpendicular to the axes meeting at P. Prove that the locus of P is the hyperbola a2x 2 – b2y2 = (a2 + b2)2. Solution. The equation of normal at the point Q (a sec φ, b tan φ) to the hyperbola 2 2 a x – 2 2 b y = 1 is ax cos φ + by cot φ = a2 + b2 ........(1) The normal (1) meets the x–axis in M φ+ 0,sec a ba 22 and y–axis in N φ+ tan b ba ,0 22 ∴ Equation of MP, the line through M and perpendicular to x–axis, is x = + a ba 22 sec φ or sec φ = )ba( ax 22 + ........(2) and the equation of NP, the line through N and perpendicular to the y–axis is y = + b ba 22 tan φ or tan φ = )ba( by 22 + .........(3) The locus of the point of intersection of MP and NP will be obtained by eliminating φ from (2) and (3), we have sec2φ – tan2φ = 1 ⇒ 222 22 )ba( xa + – 222 22 )ba( yb + = 1 or a2x2 – b2y2 = (a2 + b2)2 is the required locus of P. Self Practice Problems : 1. Prove that the line lx + my – n = 0 will be a normal to the hyperbola 2 2 a x – 2 2 b y = 1 if 2 2a � – 2 2 m b = 2 222 n )ba( + . Ans. 2 2a � – 2 2 m b = 2 222 n )ba( + . 2. Find the locus of the foot of perpendicular from the centre upon any normal to the hyperbola 2 2 a x – 2 2 b y = 1. Ans. (x2 + y2)2 (a2y2 – b2x2) = x2y2 (a2 + b2) 9.9.9.9. Pair of Tangents:Pair of Tangents:Pair of Tangents:Pair of Tangents: The equation to the pair of tangents which can be drawn from any point (x1, y1) to the hyperbola 2 2 2 2 b y a x − = 1 is given by: SS1 = T² where : S ≡ 2 2 2 2 b y a x − – 1 ; S1 = 2 2 1 2 2 1 b y a x − – 1 ; T ≡ 2 1 a xx – 2 1 b yy – 1. Example : How many real tangents can be drawn from the point (4, 3) to the ellipse 16 x2 – 9 y2 =1. Find the equation these tangents & angle between them. Solution. Given point P ≡ (4, 3) Hyperbola S ≡ 16 x2 – 9 y2 – 1 = 0 ∵ S1 ≡ 16 16 – 9 9 – 1 = – 1 < 0 ⇒ Point P ≡ (4, 3) lies outside the hyperbola. ∴ Two tangents can be drawn from the point P(4, 3). Equation of pair of tangents is SS1 = T2 ⇒ −− 1 9 y 16 x 22 . (– 1) = 2 1 9 y3 16 x4 −− ⇒ – 16 x2 + 9 y2 + 1 = 16 x2 + 9 y2 + 1 – 6 xy – 2 x + 3 y2 ⇒ 3x2 – 4xy – 12x + 16y = 0 θ = tan–1 3 4 Example : Find the locus of point of intersection of perpendicular tangents to the hyperbola 2 2 2 2 b y a x − = 1 Solution. Let P(h, k) be the point of intersection of two perpendicular tangents equation of pair of tangents is SS1 = T2 ⇒ −− 1 b y a x 2 2 2 2 −− 1 b k a h 2 2 2 2 = 2 22 1b ky a hx −− ⇒ 2 2 a x −− 1 b k 2 2 – 2 2 b y −1 a h 2 2 + ........ = 0 .........(i) Since equation (i) represents two perpendicular lines ∴ 2a 1 −− 1 b k 2 2 – 2b 1 −1 a h 2 2 = 0 ⇒ – k2 – b2 – h2 + a2 = 0 ⇒ locus is x2 + y2 = a2 – b2 Ans. 10. Director Circle : The locus of the intersection point of tangents which are at right angles is known as the Director Circle of the hyperbola. The equation to the director circle is : x2 + y2 = a2 − b2. If b2 < a2 this circle is real. If b2 = a2 (rectangular hyperbola) the radius of the circle is zero & it reduces to a point circle at the origin. In this case the centre is the only point from which the tangents at right angles can be drawn to the curve. If b2 > a2, the radius of the circle is imaginary, so that there is no such circle & so no pair of tangents at right angle can be drawn to the curve. 11.11.11.11. Chord of Contact:Chord of Contact:Chord of Contact:Chord of Contact: Equation to the chord of contact of tangents drawn from a point P(x1, y1) to the hyperbola 2 2 a x – 2 2 b y = 1 is T = 0, where T = 2 1 a xx – 2 1 b yy – 1 Example : If tangents to the parabola y2 = 4ax intersect the hyperbola 2 2 a x – 2 2 b y = 1 at A and B, then find the locus of point of intersection of tangents at A and B. Solution. Let P ≡ (h, k) be the point of intersection of tangents at A & B ∴ equation of chord of contact AB is 2a xh – 2b yk = 1 .............(i) which touches the parabola equation of tangent to parabola y2 = 4ax y = mx – m a ⇒ mx – y = – m a .............(ii) equation (i) & (ii) as must be same ∴ 2a h m = − − 2b k 1 = 1 m a − ⇒ m = k h 2 2 a b & m = – 2b ak ∴ 2 2 ka hb = – 2b ak ⇒ locus of P is y2 = – 3 4 a b . x Ans. 12.12.12.12. Chord with a given middle point :Chord with a given middle point :Chord with a given middle point :Chord with a given middle point : Equation of the chord of the hyperbola 2 2 2 2 b y a x − = 1 whose middle point is (x1, y1) is T = S1, where S1 = 2 2 1 2 2 1 b y a x − – 1 ; T ≡ 2 1 a xx – 2 1 b yy – 1. Example : Find the locus of the mid - point of focal chords of the hyperbola 2 2 a x – 2 2 b y = 1. Solution. Let P ≡ (h, k) be the mid-point ∴ equation of chord whose mid-point is given 2a xh – 2b yk – 1 = 2 2 a h – 2 2 b k – 1 since it is a focal chord, ∴ it passes through focus, either (ae, 0) or (–ae, 0) If it passes trhrough (ae, 0) ∴ locus is a ex = 2 2 a x – 2 2 b y If it passes through (–ae, 0) ∴ locus is – a ex = 2 2 a x – 2 2 b y Ans. Example : Find the condition on 'a' and 'b' for which two distinct chords of the hyperbola 2 2 a2 x – 2 2 b2 y = 1 passing through (a, b) are bisected by the line x + y = b. Solution. Let the line x + y = b bisect the chord at P(α, b – α) ∴ equation of chord whose mid-point is P(α, b – α) 2a2 xα – 2b2 )b(y α− = 2 2 a2 α – 2 2 b2 )b( α− Since it passes through (a, b) ∴ a2 α – b2 )b( α− = 2 2 a2 α – 2 2 b2 )b( α− α2 − 22 b 1 a 1 + α − a 1 b 1 = 0 α = 0, α = b 1 a 1 1 + ∴ a ≠ ± b Example : Find the locus of the mid point of the chords of the hyperbola 2 2 a x – 2 2 b y = 1 which subtend a right angle at the origin. Solution. let (h,k) be the mid–point of the chord of the hyperbola. Then its equation is 2a hx – 2b ky – 1 = 2 2 b h – 2 2 b k – 1 or 2a hx – 2b ky = 2 2 a h – 2 2 b k ........(i) The equation of the lines joining the origin to the points of intersection of the hyperbola and the chored (1) is obtained by making homogeneous hyperbola with the help of (1) ∴ 2 2 a x – 2 2 b y = 2 2 2 2 2 2 22 b k a h b ky a hx − − ⇒ 2a 1 2 2 2 2 2 b k a h − x2 – 2b 1 2 2 2 2 2 b k a h − y2 = 4 2 a h x2 + 4 2 b k y2 – 22ba hk2 xy .......(2) The lines represented by (2) will be at right angle if coefficient of x2 + coefficient of y2 = 0 ⇒ 2a 1 2 2 2 2 2 b k a h − – 4 2 a h – 2b 1 2 2 2 2 2 b k a h − – 4 2 b k = 0 ⇒ 2 2 2 2 2 b k a h − − 22 b 1 a 1 = 4 2 a h + 4 2 b k hence, the locus of (h,k) is 2 2 2 2 2 b y a x − − 22 b 1 a 1 = 4 2 a x + 4 2 b y Self Practice Problem 1. Find the equation of the chord 36 x2 – 9 y2 = 1 which is bisected at (2, 1). Ans. x = 2y 2. Find the point 'P' from which pair of tangents PA & PB are drawn to the hyperbola 25 x2 – 16 y2 = 1 in such a way that (5, 2) bisect AB Ans. 12, 4 375 3. From the points on the circle x2 + y2 = a2, tangent are drawn to the hyperbola x2 – y2 = a2, prove that the locus of the middle points of the chords of contact is the curve (x2 – y2)2 = a2 (x2 + y2). Ans. (x2 – y2)2 = a2 (x2 + y2). 13. Diameter : The locus of the middle points of a system of parallel chords with slope 'm' of an hyperbola is called its diameter. It is a straight line passing through the centre of the hyperbola and has the equation y = − b a m 2 2 x. NOTE : All diameters of the hyperbola passes through its centre. 14. Asymptotes : Definition : If the length of the perpendicular let fall from a point on a hyperbola to a straight line tends to zero as the point on the hyperbola moves to infinity along the hyperbola, then the straight line is called the Asymptote of the hyperbola. Equations of Asymptote : x a y b + = 0 and x a y b − = 0 . Pair of asymptotes : x a y b 2 2 2 2 0− = . NOTE : (i) A hyperbola and its conjugate have the same asymptote. (ii) The equation of the pair of asymptotes differs from the equation of hyperbola (or conjugate hyperbola) by the constant term only. (iii) The asymptotes pass through the centre of the hyperbola & are equally inclined to the transverse axis of the hyperbola. Hence the bisectors of the angles between the asymptotes are the principle axes of the hyperbola. (iv) The asymptotes of a hyperbola are the diagonals of the rectangle formed by the lines drawn through the extremities of each axis parallel to the other axis. (v) Asymptotes are the tangent to the hyperbola from the centre. (vi) A simple method to f ind the co-ordinates of the centre of the hyperbola expressed as a general equation of degree 2 should be remembered as: Let f (x, y) = 0 represents a hyperbola. Find ∂∂ f x & ∂∂ f y .Then the point of intersection of ∂∂ f x = 0 & ∂∂ f y = 0 gives the centre of the hyperbola. Example : Find the asymptotes xy – 3y – 2x = 0. Solution. Since equation of a hyperbola and its asymptotes differ in constant terms only, ∴ Pair of asymptotes is given by xy – 3y – 2x + λ = 0 where λ is any constant such that it represents two straight lines. ∴ abc + 2fgh – af2 – bg2 – ch2 = 0 ⇒ 0 + 2 × – 2 3 × – 1 × 2 1 – 0 – 0 – λ 2 2 1 = 0 ∴ λ = 6 From (1), the asymptotes of given hyperbola are given by xy – 3y – 2x + 6 = 0 or (y – 2) (x – 3) = 0 ∴ Asymptotes are x – 3 = 0 and y – 2 = 0 Example : The asymptotes of a hyperbola having centre at the point (1, 2) are parallel to the lines 2x + 3y = 0 and 3x + 2y = 0. If the hyperbola passes through the point (5, 3), show that its equation is (2x + 3y – 8) (3x + 2y + 7) = 154 Solution. Let the asymptotes be 2x + 3y + λ = 0 and 3x + 2y + µ = 0. Since asymptotes passes through (1,2), then λ = – 8 and µ = – 7 Thus the equation of asympotes are 2x + 3y – 8 = 0 and 3x + 2y – 7 = 0 Let the equation of hyperbola be (2x + 3y – 8) (3x + 2y – 7) + v = 0 ......(1) It passes through (5,3), then (10 + 9 – 8) (15 + 6 – 7) + v = 0 ⇒ 11 × 14 + v = 0 ∴ v = – 154 putting the value of v in (1) we obtain (2x + 3y – 8) (3x + 2y – 7) – 154 = 0 which is the equation of required hyperbola. Self Practice Problems : 1. Show that the tangent at any point of a hyperbola cuts off a triangle of constant area from the asymptotes and that the portion of it intercepted between the asymptotes is bisected at the point of contact. 15. Rectangular Or Equilateral Hyperbola : The particular kind of hyperbola in which the lengths of the transverse & conjugate axis are equal is called an Equilateral Hyperbola. Note that the eccentricity of the rectangular hyperbola is 2 . Rectangular Hyperbola (xy = c2) : It is referred to its asymptotes as axes of co−ordinates. Vertices : (c, c) & (− c, − c); Foci : ( )2 2c c, & ( )− −2 2c c, , Directrices : x + y = ± 2 c Latus Rectum (l ) : � = 2 2 c = T.A. = C.A. Parametric equation x = ct, y = c/t, t ∈ R – {0} Equation of a chord joining the points P (t1) & Q(t2) is x + t1 t2 y = c (t1 + t2). Equation of the tangent at P (x1, y1) is x x y y1 1 + = 2 & at P (t) is x t + t y = 2 c. Equation of the normal at P (t) is x t3 − y t = c (t4 − 1). Chord with a given middle point as (h, k) is kx + hy = 2hk. Example : A triangle has its vertices on a rectangle hyperbola. Prove that the orthocentre of the triangle also lies on the same hyperbola. Solution. Let "t1", "t2" and "t3" are the vertices of the triangle ABC, described on the rectangular hyperbola xy = c2. ∴ Co–ordinates of A,B and C are 1 1 t c ,ct , 2 2 t c ,ct and 3 3 t c ,ct respectively Now lope of BC is 23 23 ctct tt − − = – 32tt 1 ∴ Slope of AD is t2t3Equation of Altitude AD is y – 1t c = t2t3(x – ct1) or t1y – c = x t1t2t3 – ct12t2t3 .....(1)Similarly equation of altitude BE is t2y – c = x t1t2t3 – ct1t22t3 ......(2) Solving (1) and (2), we get the orthocentre −− 321 321 ttct, ttt c Which lies on xy = c2. Example : A, B, C are three points on the rectangular hyperbola xy = c2, find (i) The area of the triangle ABC (ii) The area of the triangle formed by the tangents A, B and C. Sol. Let co–ordinates of A,B and C on the hyperbola xy = c2 are 1 1 t c ,ct , 2 2 t c ,ct and 3 3 t c ,ct respectively.. (i) ∴ Area of triangle ABC = 2 1 2 2 1 1 t c ct t c ct + 3 3 2 2 t c ct t c ct + 1 1 3 3 t c ct t c ct = 2 c2 3 1 1 3 2 3 3 2 1 2 2 1 t t t t t t t t t t t t −+−+− = 321 2 ttt2 c 2 2 1 2 321 2 3 2 213 2 23 2 3 tttttttttttt −+−+− = 321 2 ttt2 c | (t1 – t2) (t2 – t3) (t3 – t1) | (ii) Equations of tangents at A,B,C are x + t12 – 2ct1 = 0 x + yt22 – 2ct2 = 0 and x + yt32 – 2ct3 = 0 ∴ Required Area = |CCC|2 1 321 2 3 2 3 2 2 2 1 2 1 ct2t1 ct2t1 ct2t1 − − − .........(1) where C1 = 2 3 2 1 t1 t1 , C2 = – 2 3 2 1 t1 t1 and C3 = 2 2 2 1 t1 t1 ∴ C1 = t32 – t22, C2 = t12 – t32 and C3 = t22 – t12 From (1) = )tt()tt()tt(2 1 2 1 2 2 2 3 2 1 2 2 2 3 −−− 4c2.(t1 – t2)2 (t2 – t3)2 (t3 – t1)2 = 2c2 )133221 133221 tt()tt()tt( )tt()tt()tt( +++ −−− ∴ Required area is, 2c2 )tt()tt()tt( )tt()tt()tt 133221 133221 +++ −−−( Example : Prove that the perpendicular focal chords of a rectangular hyperbola are equal. Solution. Let rectangular hyperbola is x2 – y2 = a2 Let equations of PQ and DE are y = mx + c ......(1) and y = m1x + c1 .......(2) respectively. Be any two focal chords of any rectangular hyperbola x2 – y2 = a2 through its focus. We have to prove PQ = DE. Since PQ ⊥ DE. ∴ mm1 = –1 ......(3) Also PQ passes through S (a 2 ,0) then from (1), 0 = ma 2 +c or c2 = 2a2m2 ......(4) Let (x1,y1) and (x2,y2) be the co–ordinates of P and Q then(PQ)2 = (x1 – x22) + (y1 – y2)2 ......(5)Since (x1,y1) and (x2,y2) lie on (1) ∴ y1 = mx1 + c and y2 = mx2 + c ∴ (y1 – y2) = m (x1 – x2) .......(6)From (5) and (6) (PQ)2 = (x1 – x2)2 (1 + m2) .......(7) Now solving y = mx + c and x2 – y2 = a2 then x2 – (mx + c)2 = a2 or (m2 – 1) x2 + 2mcx + (a2 + c2) = 0 ∴ x1 + x2 = 1m mc2 2 − and x1x2 = 1m ca 2 22 − + ⇒ (x1 – x2)2 = (x1 + x2)2 – 4x1x2 = 22 22 )1m( cm4 − – )1m( )ca(4 2 22 − + = 22 2222 )1m( }maca{4 − −+ = 22 22 )1m( )1m(a4 − + {∵ c2 = 2a2m2} From (7), (PQ)2 = 4a2 − + 1m 1m 2 2 Similarly, (DE)2 = 4a2 2 2 1 2 1 1m 1m − + = 4a2 2 2 2 1 m 1 1 m 11 − − + − (∵ mm1 = – 1) = 4a2 − + 1m 1m 2 2 = (PQ)2 Thus (PQ)2 = (DE)2 ⇒ PQ = DE. Hence perpendicular focal chords of a rectangular hyperbola are equal. 15. Important Results : • Locus of the feet of the perpendicular drawn from focus of the hyperbola x a y b 2 2 2 2 1− = upon any tangent is its auxiliary circle i.e. x2 + y2 = a2 & the product of these perpendiculars is b2. • The portion of the tangent between the point of contact & the directrix subtends a right angle at the corresponding focus. • The tangent & normal at any point of a hyperbola bisect the angle between the focal radii. This spells the reflection property of the hyperbola as "An incoming light ray " aimed towards one focus is reflected from the outer surface of the hyperbola towards the other focus. It follows that if an ellipse and a hyperbola have the same foci, they cut at right angles at any of their common point. Note that the ellipse x a y b 2 2 2 2 1+ = & the hyperbola x a k y k b 2 2 2 2 2 2 − − − = 1 (a > k > b > 0) are confocal and therefore orthogonal. • The foci of the hyperbola and the points P and Q in which any tangent meets the tangents at the vertices are concyclic with PQ as diameter of the circle. • If from any point on the asymptote a straight line be drawn perpendicular to the transverse axis, the product of the segments of this line, intercepted between the point & the curve is always equal to the square of the semi conjugate axis. • Perpendicular from the foci on either asymptote meet it in the same points as the corresponding directrix & the common points of intersection lie on the auxiliary circle. • The tangent at any point P on a hyperbola x a y b 2 2 2 2 1− = with centre C, meets the asymptotes in Q and R and cuts off a ∆ CQR of constant area equal to ab from the asymptotes & the portion of the tangent intercepted between the asymptote is bisected at the point of contact. This implies that locus of the centre of the circle circumscribing the ∆ CQR in case of a rectangular hyperbola is the hyperbola itself & for a standard hyperbola the locus would be the curve, 4 (a2x2 − b2y2) = (a2 + b2)2. • If the angle between the asymptote of a hyperbola x a y b 2 2 2 2 1− = is 2 θ then the eccentricity of the hyperbola is sec θ. • A rectangular hyperbola circumscribing a triangle also passes through the orthocentre of this triangle. If i i t c ,tc i = 1, 2, 3 be the angular points P, Q, R then orthocentre is − − 321 321 tttc,ttt c . • If a circle and the rectangular hyperbola xy = c2 meet in the four points t1, t2, t3 & t4, then(a) t1 t2 t3 t4 = 1(b) the centre of the mean position of the four points bisects the distance between the centres of the two curves. (c) the centre of the circle through the points t1, t2 & t3 is : +++++ +++ 321321 ttt,ttt 321321 t 1 t 1 t 1 2 c ttt 1 2 c Example : A ray emanating from the point (5, 0) is incident on the hyperbola 9x2 – 16y2 = 144 at the point P with abscissa 8. Find the equation of the reflected ray after first reflection and point P lies in first quadrant. Solution. Given hyperbola is 9x2 – 16y2 = 144. This equation can be rewritten as 16 x2 – 9 y2 = 1 ......(1) Since x co–ordinate of P is 8. Let y co–ordinate of P ia α. ∵ (8,α) lies on (1) ∴ 16 64 – 9 2α = 1 ⇒ α2 = 27 ⇒ a = 3 3 (∵ P lies in first quadrant) Hence coªordinate of point P is (8,3 3 ). ∵ Equation of reflected ray passing through P (8,3 3 ) and S′(–5,0) ∴ Its equation is y – 3 3 = 85 330 −− − (x – 8) or 13y – 39 3 = 3 3 x – 24 3 or 3 3 x – 13y + 15 3 = 0. SHORT REVISION PARABOLA 1. CONIC SECTIONS: A conic section, or conic is the locus of a point which moves in a plane so that its distance from a fixed point is in a constant ratio to its perpendicular distance from a fixed straight line. � The fixed point is called the FOCUS. � The fixed straight line is called the DIRECTRIX. � The constant ratio is called the ECCENTRICITY denoted by e. � The line passing through the focus & perpendicular to the directrix is called the AXIS. � A point of intersection of a conic with its axis is called a VERTEX. 2. GENERAL EQUATION OF A CONIC : FOCAL DIRECTRIX PROPERTY : The general equation of a conic with focus (p, q) & directrix lx + my + n = 0 is : (l2 + m2) [(x − p)2 + (y − q)2] = e2 (lx + my + n)2 ≡ ax2 + 2hxy + by2 + 2gx + 2fy + c = 0 3. DISTINGUISHING BETWEEN THE CONIC : The nature of the conic section depends upon the position of the focus S w.r.t. the directrix & also upon the value of the eccentricity e. Two different cases arise. CASE (I) : WHEN THE FOCUS LIES ON THE DIRECTRIX. In this case D ≡ abc + 2fgh − af2 − bg2 − ch2 = 0 & the general equation of a conic represents a pair of straight lines if : e > 1 the lines will be real & distinct intersecting at S. e = 1 the lines will coincident. e < 1 the lines will be imaginary. CASE (II) : WHEN THE FOCUS DOES NOT LIE ON DIRECTRIX. a parabola an ellipse a hyperbola rectangular hyperbola 4. PARABOLA : DEFINITION : A parabola is the locus of a point which moves in a plane, such that its distance from a fixed point (focus) is equal to its perpendicular distance from a fixed straight line (directrix). Standard equation of a parabola is y2 = 4ax. For this parabola : (i) Vertex is (0, 0) (ii) focus is (a, 0) (iii) Axis is y = 0 (iv) Directrix is x + a = 0 FOCAL DISTANCE : The distance of a point on the parabola from the focus is called the FOCAL DISTANCE OF THE POINT. FOCAL CHORD : A chord of the parabola, which passes through the focus is called a FOCAL CHORD. DOUBLE ORDINATE : A chord of the parabola perpendicular to the axis of the symmetry is called a DOUBLE ORDINATE. LATUS RECTUM : A double ordinate passing through the focus or a focal chord perpendicular to the axis of parabola is called the LATUS RECTUM. For y2 = 4ax. � Length of the latus rectum = 4a. � ends of the latus rectum are L(a, 2a) & L' (a, − 2a). 2 = 4ax ; y2 = − 4ax ; x2 = 4ay ; x2 = − 4ay 5. POSITION OF A POINT RELATIVE TO A PARABOLA : The point (x1 y1) lies outside, on or inside the parabola y2 = 4ax according as the expression y12 − 4ax1 is positive, zero or negative. 6. LINE & A PARABOLA : The line y = mx + c meets the parabola y2 = 4ax in two points real, coincident or imaginary according as a < > c m ⇒ condition of tangency is, c = m a . 7. Length of the chord intercepted by the parabola on the line y = m x + c is : )mca)(m1(a m 4 2 2 −+ . e = 1 ; D ≠ 0, 0 < e < 1 ; D ≠ 0 ; e > 1 ; D ≠ 0 ; e > 1 ; D ≠ 0 h² = ab h² < ab h² > ab h² > ab ; a + b = 0 Note that: (i) Perpendicular distance from focus on directrix = half the latus rectum. (ii) Vertex is middle point of the focus & the point of intersection of directrix & axis. (iii) Two parabolas are laid to be equal if they have the same latus rectum. Four standard forms of the parabola are y Note: length of the focal chord making an angle α with the x− axis is 4aCosec² α. 8. PARAMETRIC REPRESENTATION : The simplest & the best form of representing the co−ordinates of a point on the parabola is (at2, 2at). The equations x = at² & y = 2at together represents the parabola y² = 4ax, t being the parameter. The equation of a chord joining t1 & t2 is 2x − (t1 + t2) y + 2 at1 t2 = 0.Note: If the chord joining t1, t2 & t3, t4 pass through a point (c, 0) on the axis, then t1t2 = t3t4 = − c/a.9. TANGENTS TO THE PARABOLA y2 = 4ax : (i) y y1 = 2 a (x + x1) at the point (x1, y1) ; (ii) y = mx + m a (m ≠ 0) at m a2 , m a 2 (iii) t y = x + a t² at (at2, 2at). Note : Point of intersection of the tangents at the point t1 & t2 is [ at1 t2, a(t1 + t2) ].10. NORMALS TO THE PARABOLA y2 = 4ax : (i) y − y1 = a2 y1 − (x − x1) at (x1, y1) ; (ii) y = mx − 2am − am3 at (am2, − 2am) (iii) y + tx = 2at + at3 at (at2, 2at). Note : Point of intersection of normals at t1 & t2 are, a (t 12 + t 22 + t1t2 + 2) ; − a t1 t2 (t1 + t2). 11. THREE VERY IMPORTANT RESULTS : (a) If t1 & t2 are the ends of a focal chord of the parabola y² = 4ax then t1t2 = −1. Hence the co-ordinates at the extremities of a focal chord can be taken as (at2, 2at) & − t a2 , t a 2 . (b) If the normals to the parabola y² = 4ax at the point t1, meets the parabola again at the point t2, then t2 = +− 1 1 t 2 t . (c) If the normals to the parabola y² = 4ax at the points t1 & t2 intersect again on the parabola at the point 't3' then t1 t2 = 2 ; t3 = − (t1 + t2) and the line joining t1 & t2 passes through a fixed point (−2a, 0). General Note : (i) Length of subtangent at any point P(x, y) on the parabola y² = 4ax equals twice the abscissa of the point P. Note that the subtangent is bisected at the vertex. (ii) Length of subnormal is constant for all points on the parabola & is equal to the semi latus rectum. (iii) If a family of straight lines can be represented by an equation λ2P + λQ + R = 0 where λ is a parameter and P, Q, R are linear functions of x and y then the family of lines will be tangent to the curve Q2 = 4 PR. 12. The equation to the pair of tangents which can be drawn from any point (x1, y1) to the parabola y² = 4axis given by : SS1 = T2 where :S ≡ y2 − 4ax ; S1 = y12 − 4ax1 ; T ≡ y y1 − 2a(x + x1). 13. DIRECTOR CIRCLE : Locus of the point of intersection of the perpendicular tangents to the parabola y² = 4ax is called the DIRECTOR CIRCLE. It’s equation is x + a = 0 which is parabola’s own directrix. 14. CHORD OF CONTACT : Equation to the chord of contact of tangents drawn from a point P(x1, y1) is yy1 = 2a (x + x1). Remember that the area of the triangle formed by the tangents from the point (x1, y1) & the chord of contact is (y12 − 4ax1)3/2 ÷ 2a. Also note that the chord of contact exists only if the point P is not inside. 15. POLAR & POLE : (i) Equation of the Polar of the point P(x1, y1) w.r.t. the parabola y² = 4ax is, y y1= 2a(x + x1)(ii) The pole of the line lx + my + n = 0 w.r.t. the parabola y² = 4ax is − 1 am2 , 1 n . Note: (i) The polar of the focus of the parabola is the directrix. (ii) When the point (x1, y1) lies without the parabola the equation to its polar is the same as the equation to the chord of contact of tangents drawn from (x1, y1) when (x1, y1) is on the parabola the polar is the same as the tangent at the point. (iii) If the polar of a point P passes through the point Q, then the polar of Q goes through P. (iv) Two straight lines are said to be conjugated to each other w.r.t. a parabola when the pole of one lies on the other. (v) Polar of a given point P w.r.t. any Conic is the locus of the harmonic conjugate of P w.r.t. the two points is which any line through P cuts the conic. 16. CHORD WITH A GIVEN MIDDLE POINT : Equation of the chord of the parabola y² = 4ax whose middle point is (x1, y1) is y − y1 = 1y a2 (x − x1). This reduced to T = S1 where T ≡ y y1 − 2a (x + x1) & S1 ≡ y12 − 4ax1. 17. DIAMETER : The locus of the middle points of a system of parallel chords of a Parabola is called a DIAMETER. Equation to the diameter of a parabola is y = 2a/m, where m = slope of parallel chords. Note: (i) The tangent at the extremity of a diameter of a parabola is parallel to the system of chords it bisects. (ii) The tangent at the ends of any chords of a parabola meet on the diameter which bisects the chord. (iii) A line segment from a point P on the parabola and parallel to the system of parallel chords is called the ordinate to the diameter bisecting the system of parallel chords and the chords are called its double ordinate. 18. IMPORTANT HIGHLIGHTS : (a) If the tangent & normal at any point ‘P’ of the parabola intersect the axis at T & G then ST = SG = SP where ‘S’ is the focus. In other words the tangent and the normal at a point P on the parabola are the bisectors of the angle between the focal radius SP & the perpendicular from P on the directrix. From this we conclude that all rays emanating from S will become parallel to the axis of the parabola after reflection. (b) The portion of a tangent to a parabola cut off between the directrix & the curve subtends a right angle at the focus. (c) The tangents at the extremities of a focal chord intersect at right angles on the directrix, and hence a circle on any focal chord as diameter touches the directrix. Also a circle on any focal radii of a point P (at2 2+ t on a normal at the point P. (d) Any tangent to a parabola & the perpendicular on it from the focus meet on the tangtent at the vertex. (e) If the tangents at P and Q meet in T, then : 2 = SP. SQ & � The triangles SPT and STQ are similar. (f) Tangents and Normals at the extremities of the latus rectum of a parabola y2 = 4ax constitute a square, their points of intersection being (−a, 0) & (3 a, 0). (g) Semi latus rectum of the parabola y² = 4ax, is the harmonic mean between segments of any focal chord of the parabola is ; 2a = cb bc2 + i.e. a 1 c 1 b 1 =+ . (h) The circle circumscribing the triangle formed by any three tangents to a parabola passes through the focus. (i) The orthocentre of any triangle formed by three tangents to a parabola y2 = 4ax lies on the directrix & has the co-ordinates − a, a (t1 + t2 + t3 + t1t2t3).(j) The area of the triangle formed by three points on a parabola is twice the area of the triangle formed by the tangents at these points. (k) If normal drawn to a parabola passes through a point P(h, k) then k = mh − 2am − am3 i.e. am3 + m(2a − h) + k = 0. Then gives m1 + m2 + m3 = 0 ; m1m2 + m2m3 + m3m1 = 2a h a − ; m1 m2 m3 = − k a . where m1, m2, & m3 are the slopes of the three concurrent normals. Note that the algebraic sum of the: � slopes of the three concurrent normals is zero. � ordinates of the three conormal points on the parabola is zero. � Centroid of the ∆ formed by three co-normal points lies on the x-axis. � TP and TQ subtend equal angles at the focus S. � ST , 2at) as diameter touches the tangent at the vertex and intercepts a chord of length a 1 EXERCISE–1 Q.1 Show that the normals at the points (4a, 4a) & at the upper end of the latus ractum of the parabola y2 = 4ax intersect on the same parabola. Q.2 Prove that the locus of the middle point of portion of a normal to y2 = 4ax intercepted between the curve & the axis is another parabola. Find the vertex & the latus rectum of the second parabola. Q.3 Find the equations of the tangents to the parabola y2 = 16x, which are parallel & perpendicular respectively to the line 2x – y + 5 = 0. Find also the coordinates of their points of contact. Q.4 A circle is described whose centre is the vertex and whose diameter is three-quarters of the latus rectum of a parabola y2 = 4ax. Prove that the common chord of the circle and parabola bisects the distance between the vertex and the focus. Q.5 Find the equations of the tangents of the parabola y2 = 12x, which passes through the point (2,5). Q.6 Through the vertex O of a parabola y2 = 4x , chords OP & OQ are drawn at right angles to one another. Show that for all positions of P, PQ cuts the axis of the parabola at a fixed point. Also find the locus of the middle point of PQ. Q.7 Let S is the focus of the parabola y2 = 4ax and X the foot of the directrix, PP' is a double ordinate of the curve and PX meets the curve again in Q. Prove that P'Q passes through focus. Q.8 Three normals to y² = 4x pass through the point (15, 12). Show that one of the normals is given by y = x − 3 & find the equations of the others. Q.9 Find the equations of the chords of the parabola y2 = 4ax which pass through the point (–6a, 0) and which subtends an angle of 45° at the vertex. Q.10 Through the vertex O of the parabola y2 = 4ax, a perpendicular is drawn to any tangent meeting it at P & the parabola at Q. Show that OP · OQ = constant. Q.11 'O' is the vertex of the parabola y2 = 4ax & L is the upper end of the latus rectum. If LH is drawn perpendicular to OL meeting OX in H, prove that the length of the double ordinate through H is 4a 5 . Q.12 The normal at a point P to the parabola y2 = 4ax meets its axis at G. Q is another point on the parabola such that QG is perpendicular to the axis of the parabola. Prove that QG2 − PG2 = constant. Q.13 If the normal at P(18, 12) to the parabola y2= 8x cuts it again at Q, show that 9PQ = 80 10 Q.14 Prove that, the normal to y2 = 12x at (3, 6) meets the parabola again in (27, −18) & circle on this normal chord as diameter is x2 + y2 − 30x + 12y − 27 = 0. Q.15 Find the equation of the circle which passes through the focus of the parabola x2 = 4y & touches it at the point (6, 9).Q.16 P & Q are the points of contact of the tangents drawn from the point T to the parabola y2 = 4ax. If PQ be the normal to the parabola at P, prove that TP is bisected by the directrix. Q.17 Prove that the locus of the middle points of the normal chords of the parabola y2 = 4ax is a2x y a4 a2 y 2 32 −=+ . Q.18 From the point (−1, 2) tangent lines are drawn to the parabola y2 = 4x. Find the equation of the chord of contact. Also find the area of the triangle formed by the chord of contact & the tangents. Q.19 Show that the locus of a point that divides a chord of slope 2 of the parabola y2 = 4x internally in the ratio 1 : 2 is a parabola. Find the vertex of this parabola. Q.20 From a point A common tangents are drawn to the circle x2 + y2 = a2/2 & parabola y2 = 4ax. Find the area of the quadrilateral formed by the common tangents, the chord of contact of the circle and the chord of contact of the parabola. Q.21 Prove that on the axis of any parabola y² = 4ax there is a certain point K which has the property that, if a chord PQ of the parabola be drawn through it, then 22 )QK( 1 )PK( 1 + is same for all positions of the chord. Find also the coordinates of the point K. Q.22 Prove that the two parabolas y2 = 4ax & y2 = 4c (x − b) cannot have a common normal, other than the axis, unless )ca( b − > 2. Q.23 Find the condition on ‘a’ & ‘b’ so that the two tangents drawn to the parabola y2 = 4ax from a point are normals to the parabola x2 y2 = 4ax is y2(2x + a) = a(3x + a)2. Q.25 Show that the locus of a point, such that two of the three normals drawn from it to the parabola y2 = 4ax are perpendicular is y2 = a(x − 3a). = 4by. Q.24 Prove that the locus of the middle points of all tangents drawn from points on the directrix to the parabola EXERCISE–2 Q.1 In the parabola y2 = 4ax, the tangent at the point P, whose abscissa is equal to the latus ractum meets the axis in T & the normal at P cuts the parabola again in Q. Prove that PT : PQ = 4 : 5. Q.2 Two tangents to the parabola y2= 8x meet the tangent at its vertex in the points P & Q. If PQ = 4 units, prove that the locus of the point of the intersection of the two tangents is y2 = 8 (x + 2). Q.3 A variable chord t1 t2 of the parabola y2 = 4ax subtends a right angle at a fixed point t0 of the curve.Show that it passes through a fixed point. Also find the co−ordinates of the fixed point. Q.4 Two perpendicular straight lines through the focus of the parabola y² = 4ax meet its directrix in T & T' respectively. Show that the tangents to the parabola parallel to the perpendicular lines intersect in the mid point of T T '. Q.5 Two straight lines one being a tangent to y2 = 4ax and the other to x2 = 4by are right angles. Find the locus of their point of intersection. Q.6 A variable chord PQ of the parabola y2 = 4x is drawn parallel to the line y = x. If the parameters of the points P & Q on the parabola are p & q respectively, show that p + q = 2. Also show that the locus of the point of intersection of the normals at P & Q is 2x − y = 12. Q.7 Show that an infinite number of triangles can be inscribed in either of the parabolas y2 = 4ax & x2 = 4by whose sides touch the other. Q.8 If (x1, y1), (x2, y2) and (x3, y3) be three points on the parabola y2 = 4ax and the normals at these points meet in a point then prove that 2 13 1 32 3 21 y xx y xx y xx − + − + − = 0. Q.9 Show that the normals at two suitable distinct real points on the parabola y2 = 4ax intersect at a point on the parabola whose abscissa > 8a. Q.10 The equation y = x2 + 2ax + a represents a parabola for all real values of a. (a) Prove that each of these parabolas pass through a common point and determine the coordinates of this point. (b) The vertices of the parabolas lie on a curve. Prove that this curve is a parabola and find its equation. Q.11 The normals at P and Q on the parabola y2 = 4ax intersect at the point R (x1, y1) on the parabola and the tangents at P and Q intersect at the point T. Show that, l(TP) · l(TQ) = 2 1 (x1 – 8a) 221 a4y + Also show that, if R moves on the parabola, the mid point of PQ lie on the parabola y2 = 2a(x + 2a). Q.12 If Q (x1, y1) is an arbitrary point in the plane of a parabola y2 = 4ax, show that there are three points on the parabola at which OQ subtends a right angle, where O is the origin. Show furhter that the normal at these three points are concurrent at a point R.,determine the coordinates of R in terms of those of Q. Q.13 PC is the normal at P to the parabola y2 = 4ax, C being on the axis. CP is produced outwards to Q so that PQ = CP; show that the locus of Q is a parabola, & that the locus of the intersection of the tangents at P & Q to the parabola on which they lie is y2 (x + 4a) + 16 a3 = 0. Q.14 Show that the locus of the middle points of a variable chord of the parabola y2 = 4ax such that the focal distances of its extremities are in the ratio 2 : 1, is 9(y2 – 2ax)2 = 4a2(2x – a)(4x + a). Q.15 A quadrilateral is inscribed in a parabola y2 = 4ax and three of its sides pass through fixed points on the axis. Show that the fourth side also passes through fixed point on the axis of the parabola. Q.16 Prove that the parabola y2 = 16x & the circle x2 + y2 − 40x − 16y − 48 = 0 meet at the point P(36, 24) & one other point Q. Prove that PQ is a diameter of the circle. Find Q. Q.17 A variable tangent to the parabola y2 = 4ax meets the circle x2 + y2 = r2 at P & Q. Prove that the locus of the mid point of PQ is x(x2 + y2) + ay2 = 0. Q.18 Find the locus of the foot of the perpendicular from the origin to chord of the parabola y2 = 4ax subtending an angle of 450 at the vertex. Q.19 Show that the locus of the centroids of equilateral triangles inscribed in the parabola y2 = 4ax is the parabola 9y2 − 4ax + 32 a2 = 0. Q.20 The normals at P, Q, R on the parabola y2 = 4ax meet in a point on the line y = k. Prove that the sides of the triangle PQR touch the parabola x2 − 2ky = 0. Q.21 A fixed parabola y2 = 4 ax touches a variable parabola. Find the equation to the locus of the vertex of the variable parabola. Assume that the two parabolas are equal and the axis of the variable parabola remains parallel to the x-axis. Q.22 Show that the circle through three points the normals at which to the parabola y2 = 4ax are concurrent at the point (h, k) is 2(x2 + y2) − 2(h + 2a) x − ky = 0. Q.23 Prove that the locus of the centre of the circle, which passes through the vertex of the parabola y2 = 4ax & through its intersection with a normal chord is 2y2 = ax − a2. Q.24 The sides of a triangle touch y2 = 4ax and two of its angular points lie on y2 = 4b(x + c). Show that the locus of the third angular point is a2y2 = 4(2b − a)2.(ax + 4bc) Q.25 Three normals are drawn to the parabola y2 = 4ax cos α from any point lying on the straight line y = b sin α. Prove that the locus of the orthocentre of the traingles formed by the corresponding tangents is the ellipse 2 2 2 2 b y a x + = 1, the angle α being variable. EXERCISE–3 Q.1 Find the locus of the point of intersection of those normals to the parabola x2 = 8 y which are at right angles to each other. [REE '97, 6] Q.2 The angle between a pair of tangents drawn from a point P to the parabola y2 = 4ax is 450. Show that the locus of the point P is a hyperbola. [ JEE ’98, 8 ] Q.3 The ordinates of points P and Q on the parabola y2 = 12x are in the ratio 1 : 2. Find the locus of the point of intersection of the normals to the parabola at P and Q. [ REE '98, 6 ] Q.4 Find the equations of the common tangents of the circle x2 + y2 − 6y + 4 = 0 and the parabola y2 = x. [ REE '99, 6 ] Q.5(a) If the line x − 1 = 0 is the directrix of the parabola y2 − k x + 8 = 0 , then one of the values of ' k ' is (A) 1/8 (B) 8 (C) 4 (D) 1/4 (b) If x + y = k is normal to y2 = 12 x, then ' k ' is : [JEE'2000 (Scr), 1+1] (A) 3 (B) 9 (C) − 9 (D) − 3 Q.6 Find the locus of the points of intersection of tangents drawn at the ends of all normal chords of the parabola y2 = 8(x – 1). [REE '2001, 3] Q.7(a) The equation of the common tangent touching the circle (x – 3)2 + y2 = 9 and the parabola y2 = 4x above the x – axis is (A) 3 y = 3x + 1 (B) 3 y = –(x + 3) (C) 3 y = x + 3 (D) 3 y = –(3x + 1) (b) The equation of the directrix of the parabola, y2 + 4y + 4x + 2 = 0 is (A) x = –1 (B) x = 1 (C) x = – 3 2 (D) x = 3 2 [JEE'2001(Scr), 1+1] Q.8 The locus of the mid-point of the line segment joining the focus to a moving point on the parabola y2 = 4ax is another parabola with directrix [JEE'2002 (Scr.), 3] (A) x = –a (B) x = – a 2 (C) x = 0 (D) x = a 2 Q.9 The equation of the common tangent to the curves y2 = 8x and xy = –1 is [JEE'2002 (Scr), 3] (A) 3y = 9x + 2 (B) y = 2x + 1 (C) 2y = x + 8 (D) y = x + 2 Q.10(a) The slope of the focal chords of the parabola y2 = 16x which are tangents to the circle (x – 6)2 + y2 = 2 are (A) ± 2 (B) – 1/2, 2 (C) ± 1 (D) – 2, 1/2 [JEE'2003, (Scr.)] (b) Normals are drawn from the point ‘P’ with slopes m1, m2, m3 to the parabola y2 = 4x. If locus of P with m1 m2 = α is a part of the parabola itself then find α. [JEE 2003, 4 out of 60] Q.11 The angle between the tangents drawn from the point (1, 4) to the parabola y2 = 4x is (A) pi/2 (B) pi/3 (C) pi/4 (D) pi/6 [JEE 2004, (Scr.)] Q.12 Let P be a point on the parabola y2 – 2y – 4x + 5 = 0, such that the tangent on the parabola at P intersects the directrix at point Q. Let R be the point that divides the line segment QP externally in the ratio 1: 2 1 . Find the locus of R. [JEE 2004, 4 out of 60] Q.13(a) The axis of parabola is along the line y = x and the distance of vertex from origin is 2 and that from its focus is 22 . If vertex and focus both lie in the 1st quadrant, then the equation of the parabola is (A) (x + y)2 = (x – y – 2) (B) (x – y)2 = (x + y – 2) (C) (x – y)2 = 4(x + y – 2) (D) (x – y)2 = 8(x + y – 2) [JEE 2006, 3] (b) The equations of common tangents to the parabola y = x2 and y = – (x – 2)2 is/are (A) y = 4(x – 1) (B) y = 0 (C) y = – 4(x – 1) (D) y = – 30x – 50 [JEE 2006, 5] (c) Match the following Normals are drawn at points P, Q and R lying on the parabola y2 = 4x which intersect at (3, 0). Then (i) Area of ∆PQR (A) 2 (ii) Radius of circumcircle of ∆PQR (B) 5/2 (iii) Centroid of ∆PQR (C) (5/2, 0) (iv) Circumcentre of ∆PQR (D) (2/3, 0) [JEE 2006, 6] KEY CONCEPTS ELLIPSE 1. STANDARD EQUATION & DEFINITIONS : Standard equation of an ellipse referred to its principal axes along the co-ordinate axes is 1 b y a x 2 2 2 2 =+ . Where a > b & b² = a²(1 − e²) ⇒ a2 − b2 = a2 e2. Where e = eccentricity (0 < e < 1). FOCI : S ≡ (a e , 0) & S′ ≡ (− a e , 0). EQUATIONS OF DIRECTRICES : x = e a & x = e a − . VERTICES : A′ ≡ (− a, 0) & A ≡ (a, 0) . MAJOR AXIS : The line segment A′ A in which the foci S′ & S lie is of length 2a & is called the major axis (a > b) of the ellipse. Point of intersection of major axis with directrix is called the foot of the directrix (z). MINOR AXIS : The y−axis intersects the ellipse in the points B′ ≡ (0, − b) & B ≡ (0, b). The line segment B′B of length 2b (b < a) is called the Minor Axis of the ellipse. PRINCIPAL AXIS : The major & minor axis together are called Principal Axis of the ellipse. CENTRE : The point which bisects every chord of the conic drawn through it is called the centre of the conic. C ≡ (0, 0) the origin is the centre of the ellipse 1 b y a x 2 2 2 2 =+ . DIAMETER : A chord of the conic which passes through the centre is called a diameter of the conic. FOCAL CHORD : A chord which passes through a focus is called a focal chord. DOUBLE ORDINATE : A chord perpendicular to the major axis is called a double ordinate. LATUS RECTUM : The focal chord perpendicular to the major axis is called the latus rectum. Length of latus rectum (LL′′′′) = )e1(a2)( a b2 222 −== axis major axisminor = 2e (distance from focus to the corresponding directrix) NOTE : (i) The sum of the focal distances of any point on the ellipse is equal to the major Axis. Hence distance of focus from the extremity of a minor axis is equal to semi major axis. i.e. BS = CA. (ii) If the equation of the ellipse is given as 1 b y a x 2 2 2 2 =+ & nothing is mentioned, then the rule is to assume that a > b. 2. POSITION OF A POINT w.r.t. AN ELLIPSE : The point P(x1, y1) lies outside, inside or on the ellipse according as ; 1b y a x 2 2 1 2 2 1 −+ >< or = 0. 3. AUXILIARY CIRCLE / ECCENTRIC ANGLE : A circle described on major axis as diameter is called the auxiliary circle. Let Q be a point on the auxiliary circle x2 + y2 = a2 on the ellipse & the auxiliary circle respectively ‘θ’ is called the ECCENTRIC ANGLE of the point P on the ellipse (0 ≤ θ < 2 pi). Note that axis major Semi axis minor Semi == a b )QN( )PN( � � Hence “ If from each point of a circle perpendiculars are drawn upon a fixed diameter then the locus of the points dividing these perpendiculars in a given ratio is an ellipse of which the given circle is the auxiliary circle”. 4. PARAMETRIC REPRESENTATION : The equations x = a cos θ & y = b sin θ together represent the ellipse 1 b y a x 2 2 2 2 =+ . Where θ is a parameter. Note that if P(θ) ≡ (a cos θ, b sin θ) is on the ellipse then ; Q(θ) ≡ (a cos θ, a sin θ) is on the auxiliary circle. 5. LINE AND AN ELLIPSE : The line y = mx + c meets the ellipse 1 b y a x 2 2 2 2 =+ in two points real, coincident or imaginary according as c2 is < = or > a2m2 + b2. such that QP produced is perpendicular to the x-axis then P & Q are called as the CORRESPONDING POINTS Hence y = mx + c is tangent to the ellipse 1 b y a x 2 2 2 2 =+ if c2 = a2m2 + b2. The equation to the chord of the ellipse joining two points with eccentric angles α & β is given by 2 cos 2 sin b y 2 cos a x β−α = β+α + β+α . 6. TANGENTS : (i) 1 b yy a xx 2 1 2 1 =+ is tangent to the ellipse at (x1, y1). Note :The figure formed by the tangents at the extremities of latus rectum is rhoubus of area e a2 2 (ii) y = mx ± 222 bma + is tangent to the ellipse for all values of m. Note that there are two tangents to the ellipse having the same m, i.e. there are two tangents parallel to any given direction. (iii) 1 b siny a cosx = θ + θ is tangent to the ellipse at the point (a cos θ, b sin θ). (iv) The eccentric angles of point of contact of two parallel tangents differ by pi. Conversely if the difference between the eccentric angles of two points is p then the tangents at these points are parallel. (v) Point of intersection of the tangents at the point α & β is a 2 2 cos cos β−α β+α , b 2 2 cos sin β−α β+α . 7. NORMALS : (i) Equation of the normal at (x1, y1) is 1 2 1 2 y yb x xa − = a² − b² = a²e². (ii) Equation of the normal at the point (acos θ, bsin θ) is ; ax. sec θ − by. cosec θ = (a² − b²). (iii) Equation of a normal in terms of its slope 'm' is y = mx − 222 22 mba m)ba( + − . 8. DIRECTOR CIRCLE :Locus of the point of intersection of the tangents which meet at right angles is called the Director Circle. The equation to this locus is x² + y² = a² + b² i.e. a circle whose centre is the centre of the ellipse & whose radius is the length of the line joining the ends of the major & minor axis. 9. Chord of contact, pair of tangents, chord with a given middle point, pole & polar are to be interpreted as they are in parabola. 10. DIAMETER : The locus of the middle points of a system of parallel chords with slope 'm' of an ellipse is a straight line passing through the centre of the ellipse, called its diameter and has the equation y = ma b 2 2 − x. 11. IMPORTANT HIGHLIGHTS : Refering to an ellipse 1 b y a x 2 2 2 2 =+ . H −−−− 1 If P be any point on the ellipse with S & S′ as its foci then � (SP) + � (S′P) = 2a. H −−−− 2 The product of the length’s of the perpendicular segments from the foci on any tangent to the ellipse is b2 and the feet of these perpendiculars Y,Y′ lie on its auxiliary circle.The tangents at these feet to the auxiliary circle meet on the ordinate of P and that the locus of their point of intersection is a similiar ellipse as that of the original one. Also the lines joining centre to the feet of the perpendicular Y and focus to the point of contact of tangent are parallel. H −−−− 3 If the normal at any point P on the ellipse with centre C meet the major & minor axes in G & g respectively, & if CF be perpendicular upon this normal, then (i) PF. PG = b2 (ii) PF. Pg = a2 (iii) PG. Pg = SP. S′ P (iv) CG. CT = CS2 (v) locus of the mid point of Gg is another ellipse having the same eccentricity as that of the original ellipse. [where S and S′ are the focii of the ellipse and T is the point where tangent at P meet the major axis] H −−−− 4 The tangent & normal at a point P on the ellipse bisect the external & internal angles between the focal distances of P. This refers to the well known reflection property of the ellipse which states that rays from one focus are reflected through other focus & vice−versa. Hence we can deduce that the straight lines joining each focus to the foot of the perpendicular from the other focus upon the tangent at any point P meet on the normal PG and bisects it where G is the point where normal at P meets the major axis. H −−−− 5 The portion of the tangent to an ellipse between the point of contact & the directrix subtends a right angle at the corresponding focus. H −−−− 6 The circle on any focal distance as diameter touches the auxiliary circle. H −−−− 7 Perpendiculars from the centre upon all chords which join the ends of any perpendicular diameters of the ellipse are of constant length. H −−−− 8 If the tangent at the point P of a standard ellipse meets the axis in T and t and CY is the perpendicular on it from the centre then, (i) T t. PY = a2 − b2 and (ii) least value of Tt is a + b. Suggested problems from Loney: Exercise-32 (Q.2 to 7, 11, 12, 16, 24), Exercise-33 (Important) (Q.3, 5, 6, 15, 16, 18, 19, 24, 25, 26, 34), Exercise-35 (Q.2, 4, 6, 7, 8, 11, 12, 15) EXERCISE–4 Q.1 Find the equation of the ellipse with its centre (1, 2), focus at (6, 2) and passing through the point (4, 6). Q.2 The tangent at any point P of a circle x2 + y2 = a2 meets the tangent at a fixed point A (a, 0) in T and T is joined to B, the other end of the diameter through A, prove that the locus of the intersection of AP and BT is an ellipse whose ettentricity is 2 1 . Q.3 The tangent at the point α on a standard ellipse meets the auxiliary circle in two points which subtends a right angle at the centre. Show that the eccentricity of the ellipse is (1 + sin²α)−1/2. Q.4 An ellipse passes through the points (− 3, 1) & (2, −2) & its principal axis are along the coordinate axes in order. Find its equation. Q.5 If any two chords be drawn through two points on the major axis of an ellipse equidistant from the centre, show that 1 2 tan· 2 tan· 2 tan· 2 tan = δγβα , where α, β, γ, δ are the eccentric angles of the extremities of the chords. Q.6 If the normals at the points P, Q, R with eccentric angles α, β, γ on the ellipse 1 b y a x 2 2 2 2 =+ are concurrent, then show that 0 2sincossin 2sincossin 2sincossin = γγγ βββ ααα Q.7 Prove that the equation to the circle, having double contact with the ellipse 1 b y a x 2 2 2 2 =+ at the ends of a latus rectum, is x2 + y2 – 2ae3x = a2 (1 – e2 – e4). Q.8 Find the equations of the lines with equal intercepts on the axes & which touch the ellipse 1 9 y 16 x 22 =+ . Q.9 The tangent at P θθ sin 11 16 ,cos4 to the ellipse 16x2 + 11y2 = 256 is also a tangent to the circle x2 + y2 − 2x − 15 = 0. Find θ. Find also the equation to the common tangent. Q.10 A tangent having slope 3 4 − to the ellipse 132 y 18 x 22 =+ , intersects the axis of x & y in points A & B respectively. If O is the origin, find the area of triangle OAB. Q.11 ‘O’ is the origin & also the centre of two concentric circles having radii of the inner & the outer circle as ‘a’ & ‘b’ respectively. A line OPQ is drawn to cut the inner circle in P & the outer circle in Q. PR is drawn parallel to the y-axis & QR is drawn parallel to the x-axis. Prove that the locus of R is an ellipse touching the two circles. If the focii of this ellipse lie on the inner circle, find the ratio of inner : outer radii & find also the eccentricity of the ellipse. Q.12 ABC is an isosceles triangle with its base BC twice its altitude. A point P moves within the triangle such that the square of its distance from BC is half the rectangle contained by its distances from the two sides. Show that the locus of P is an ellipse with eccentricity 3 2 passing through B & C. Q.13 Let d be the perpendicular distance from the centre of the ellipse 1 b y a x 2 2 2 2 =+ to the tangent drawn at a point P on the ellipse.If F1 & F2 are the two foci of the ellipse, then show that (PF1 − PF2)2 = − 2 2 2 d b1a4 . Q.14 Common tangents are drawn to the parabola y2 = 4x & the ellipse 3x2 + 8y2 = 48 touching the parabola at A & B and the ellipse at C & D. Find the area of the quadrilateral. Q.15 If the normal at a point P on the ellipse of semi axes a, b & centre C cuts the major & minor axes at G & g, show that a2. (CG)2 + b2. (Cg)2 = (a2 − b2)2. Also prove that CG = e2CN, where PN is the ordinate of P. Q.16 Prove that the length of the focal chord of the ellipse 1 b y a x 2 2 2 2 =+ which is inclined to the major axis at angle θ is θ+θ 2222 2 cosbsina ba2 . Q.17 The tangent at a point P on the ellipse 1 b y a x 2 2 2 2 =+ intersects the major axis in T & N is the foot of the perpendicular from P to the same axis. Show that the circle on NT as diameter intersects the auxiliary circle orthogonally. Q.18 The tangents from (x1, y1) to the ellipse 1b y a x 2 2 2 2 =+ intersect at right angles. Show that the normals at the points of contact meet on the line 11 x x y y = . Q.19 Find the locus of the point the chord of contact of the tangent drawn from which to the ellipse 1 b y a x 2 2 2 2 =+ touches the circle x2 + y2 = c2, where c < b < a. Q.20 Prove that the three ellipse 1 b y a x 2 1 2 2 1 2 =+ , 1 b y a x 2 2 2 2 2 2 =+ and 1 b y a x 2 3 2 2 3 2 =+ will have a common tangent if 1ba 1ba 1ba 2 3 2 3 2 2 2 2 2 1 2 1 = 0. EXERCISE–5 Q.1 PG is the normal to a standard ellipse at P, G being on the major axis. GP is produced outwards to Q so that PQ = GP. Show that the locus of Q is an ellipse whose eccentricity is 22 22 ba ba + − & find the equation of the locus of the intersection of the tangents at P & Q. Q.2 P & Q are the corresponding points on a standard ellipse & its auxiliary circle. The tangent at P to the ellipse meets the major axis in T. Prove that QT touches the auxiliary circle. Q.3 The point P on the ellipse 1 b y a x 2 2 2 2 =+ is joined to the ends A, A′ of the major axis. If the lines through P perpendicular to PA, PA′ meet the major axis in Q and R then prove that l(QR) = length of latus rectum. Q.4 Let S and S' are the foci, SL the semilatus rectum of the ellipse 1 b y a x 2 2 2 2 =+ and LS' produced cuts the ellipse at P, show that the length of the ordinate of the ordinate of P is a e31 )e1( 2 2 + − , where 2a is the length of the major axis and e is the eccentricity of the ellipse. Q.5 A tangent to the ellipse 1 b y a x 2 2 2 2 =+ touches at the point P on it in the first quadrant & meets the coordinate axis in A & B respectively. If P divides AB in the ratio 3 : 1 find the equation of the tangent. Q.6 PCP ′ is a diameter of an ellipse 1 b y a x 2 2 2 2 =+ (a > b) & QCQ ′ is the corresponding diameter of the auxiliary circle, show that the area of the parallelogram formed by the tangent at P, P', Q & Q' is φ− 2sin)ba( ba8 2 where φ is the eccentric angle of the point P.. Q.7 If the normal at the point P(θ) to the ellipse 1 5 y 14 x 22 =+ , intersects it again at the point Q(2θ), show that cos θ = − (2/3). Q.8 A normal chord to an ellipse 1 b y a x 2 2 2 2 =+ makes an angle of 45° with the axis. Prove that the square of its length is equal to 322 44 )ba( ba32 + Q.9 If (x1, y1) & (x2, y2) are two points on the ellipse 1b y a x 2 2 2 2 =+ , the tangents at which meet in (h, k) & the normals in (p, q), prove that a2p = e2hx1 x2 and b4q = – e2k y1y2a2 where 'e' is the eccentricity. Q.10 A normal inclined at 45° to the axis of the ellipse 1 b y a x 2 2 2 2 =+ is drawn. It meets the x-axis & the y-axis in P & Q respectively. If C is the centre of the ellipse, show that the area of triangle CPQ is )ba(2 )ba( 22 222 + − sq. units. Q.11 Tangents are drawn to the ellipse 1 b y a x 2 2 2 2 =+ from the point + − 22 22 2 ba, ba a . Prove that they intercept on the ordinate through the nearer focus a distance equal to the major axis. Q.12 P and Q are the points on the ellipse 1 b y a x 2 2 2 2 =+ . If the chord P and Q touches the ellipse 0 a x4 b y a x4 2 2 2 2 =−+ , prove that secα + secβ = 2 where α, β are the eccentric angles of the points P and Q. Q.13 A straight line AB touches the ellipse 1 b y a x 2 2 2 2 =+ & the circle x2 + y2 = r2 ; where a > r > b. A focal chord of the ellipse, parallel to AB intersects the circle in P & Q, find the length of the perpendicular drawn from the centre of the ellipse to PQ. Hence show that PQ = 2b. Q.14 Show that the area of a sector of the standard ellipse in the first quadrant between the major axis and a line drawn through the focus is equal to 1/2 ab (θ − e sin θ) sq. units, where θ is the eccentric angle of the point to which the line is drawn through the focus & e is the eccentricity of the ellipse. Q.15 A ray emanating from the point (− 4, 0) is incident on the ellipse 9x2 + 25y2 = 225 at the point P with abscissa 3. Find the equation of the reflected ray after first reflection. Q.16 If p is the length of the perpendicular from the focus ‘S’ of the ellipse 1 b y a x 2 2 2 2 =+ on any tangent at 'P', then show that 1)SP( a2 p b 2 2 −= � . Q.17 In an ellipse 1 b y a x 2 2 2 2 =+ , n1 and n2 are the lengths of two perpendicular normals terminated at the major axis then prove that : 2 2 2 1 n 1 n 1 + = 4 22 b ba + Q.18 If the tangent at any point of an ellipse 1 b y a x 2 2 2 2 =+ makes an angle α with the major axis and an angle β with the focal radius of the point of contact then show that the eccentricity 'e' of the ellipse is given by the absolute value of α β cos cos . Q.19 Using the fact that the product of the perpendiculars from either foci of an ellipse 1 b y a x 2 2 2 2 =+ upon a tangent is b2, deduce the following loci. An ellipse with 'a' & 'b' as the lengths of its semi axes slides between two given straight lines at right angles to one another. Show that the locus of its centre is a circle & the locus of its foci is the curve, (x2 + y2) (x2 y2 + b4) = 4 a2 x2 y2. Q.20 If tangents are drawn to the ellipse 1 b y a x 2 2 2 2 =+ intercept on the x-axis a constant length c, prove that the locus of the point of intersection of tangents is the curve 4y2 (b2x2 + a2y2 – a2b2) = c2 (y2 – b2)2. EXERCISE–6 Q.1 If tangent drawn at a point (t², 2t) on the parabola y2 = 4x is same as the normal drawn at a point ( 5 cos φ, 2 sin φ) on the ellipse 4x² + 5y² = 20. Find the values of t & φ. [ REE ’96, 6 ] Q.2 A tangent to the ellipse x2 + 4y2 = 4 meets the ellipse x2 + 2y2 = 6 at P & Q. Prove that the tangents at P & Q of the ellipse x2 + 2y2 = 6 are at right angles. [ JEE '97, 5 ] Q.3(i) The number of values of c such that the straight line y = 4x + c touches the curve (x2/ 4) + y2 = 1 is (A) 0 (B) 1 (C) 2 (D) infinite (ii) If P = (x, y), F1 = (3, 0), F2 = (−3, 0) and 16x2 + 25y2 = 400, then PF1 + PF2 equals(A) 8 (B) 6 (C) 10 (D) 12 [ JEE '98, 2 + 2 ] Q.4(a) If x1, x2, x3 as well as y1, y2, y3 are in G.P. with the same common ratio, then the points (x1, y1),(x2, y2) & (x3, y3) :(A) lie on a straight line (B) lie on on ellipse (C) lie on a circle (D) are vertices of a triangle. (b) On the ellipse, 4x2 + 9y2 = 1, the points at which the tangents are parallel to the line 8x = 9y are : (A) 5 1 , 5 2 (B) − 5 1 , 5 2 (C) −− 5 1 , 5 2 (D) − 5 1 , 5 2 (c) Consider the family of circles, x2 + y2 = r2, 2 < r < 5. If in the first quadrant, the common tangent to a circle of the family and the ellipse 4 x2 + 25 y2 = 100 meets the co−ordinate axes at A & B, then find the equation of the locus of the mid−point of AB. [ JEE '99, 2 + 3 + 10 (out of 200) ] Q.5 Find the equation of the largest circle with centre (1, 0) that can be inscribed in the ellipse x2 + 4y2 = 16. [ REE '99, 6 ] Q.6 Let ABC be an equilateral triangle inscribed in the circle x2 + y2 = a2. Suppose perpendiculars from A, B, C to the major axis of the ellipse, x a y b 2 2 2 2+ = 1, (a > b) meet the ellipse respectively at P, Q, R so that P, Q, R lie on the same side of the major axis as A, B, C respectively. Prove that the normals to the ellipse drawn at the points P, Q and R are concurrent. [ JEE '2000, 7] Q.7 Let C1 and C2 be two circles with C2 lying inside C1. A circle C lying inside C1 touchesC1 internally and C2externally. Identify the locus of the centre of C. [ JEE '2001, 5 ] Q.8 Find the condition so that the line px + qy = r intersects the ellipse 2 2 2 2 b y a x + = 1 in points whose eccentric angles differ by pi 4 . [ REE '2001, 3 ] Q.9 Prove that, in an ellipse, the perpendicular from a focus upon any tangent and the line joining the centre of the ellipse to the point of contact must on the corresponding directrix. [ JEE ' 2002, 5] Q.10(a) The area of the quadrilateral formed by the tangents at the ends of the latus rectum of the ellipse 1 5 y 9 x 22 =+ is (A) 39 sq. units (B) 327 sq. units (C) 27 sq. units (D) none (b) The value of θ for which the sum of intercept on the axis by the tangent at the point ( )θθ sin,cos33 , 0 < θ < pi/2 on the ellipse 2 2 y 27 x + = 1 is least, is : [ JEE ' 2003 (Screening)] (A) 6 pi (B) 4 pi (C) 3 pi (D) 8 pi Q.11 The locus of the middle point of the intercept of the tangents drawn from an external point to the ellipse x2 + 2y2 = 2, between the coordinates axes, is (A) 1y2 1 x 1 22 =+ (B) 1y2 1 x4 1 22 =+ (C) 1y4 1 x2 1 22 =+ (D) 1y 1 x2 1 22 =+ [JEE 2004 (Screening) ] Q.12(a) The minimum area of triangle formed by the tangent to the ellipse 2 2 2 2 b y a x + = 1 and coordinate axes is (A) ab sq. units (B) 2 ba 22 + sq. units (C) 2 )ba( 2+ sq. units (D) 3 baba 22 ++ sq. units [JEE 2005 (Screening) ] (b) Find the equation of the common tangent in 1st quadrant to the circle x2 + y2 = 16 and the ellipse 4 y 25 x 22 + = 1. Also find the length of the intercept of the tangent between the coordinate axes. [JEE 2005 (Mains), 4 ] KEY CONCEPTS HYPERBOLA The HYPERBOLA is a conic whose eccentricity is greater than unity. (e > 1). 1. STANDARD EQUATION & DEFINITION(S) Standard equation of the hyperbola is 1 b y a x 2 2 2 2 =− . Where b2 = a2 (e2 − 1) or a2 e2 = a2 + b2 i.e. e2 = 1 + 2 2 a b = 1 + 2 A.T A.C FOCI : S ≡ (ae, 0) & S′ ≡ (− ae, 0). EQUATIONS OF DIRECTRICES : x = e a & x = − e a . VERTICES : A ≡ (a, 0) & A′ ≡ (− a, 0). l (Latus rectum) = ( ) .A.T .A.C a b2 = = 2a (e2 − 1). Note : l (L.R.) = 2e (distance from focus to the corresponding directrix) TRANSVERSE AXIS : The line segment A′A of length 2a in which the foci S′ & S both lie is called the T.A. OF THE HYPERBOLA. CONJUGATE AXIS : The line segment B′B between the two points B′ ≡ (0, − b) & B ≡ (0, b) is called as the C.A. OF THE HYPERBOLA. The T.A. & the C.A. of the hyperbola are together called the Principal axes of the hyperbola. 2. FOCAL PROPERTY : The difference of the focal distances of any point on the hyperbola is constant and equal to transverse axis i.e. a2SPPS =′− . The distance SS' = focal length. 3. CONJUGATE HYPERBOLA : Two hyperbolas such that transverse & conjugate axes of one hyperbola are respectively the conjugate & the transverse axes of the other are called CONJUGATE HYPERBOLAS of each other. eg. 1 b y a x 2 2 2 2 =− & 1 b y a x 2 2 2 2 =+− are conjugate hyperbolas of each. Note That : (a) If e1& e2 are the eccentrcities of the hyperbola & its conjugate then e1−2 + e2−2 = 1. (b) The foci of a hyperbola and its conjugate are concyclic and form the vertices of a square. (c) Two hyperbolas are said to be similiar if they have the same eccentricity. 4. RECTANGULAR OR EQUILATERAL HYPERBOLA : The particular kind of hyperbola in which the lengths of the transverse & conjugate axis are equal is called an EQUILATERAL HYPERBOLA. Note that the eccentricity of the rectangular hyperbola is 2 and the length of its latus rectum is equal to its transverse or conjugate axis. 5. AUXILIARY CIRCLE : A circle drawn with centre C & T.A. as a diameter is called the AUXILIARY CIRCLE of the hyperbola. Equation of the auxiliary circle is x2 + y2 = a2. Note from the figure that P & Q are called the "CORRESPONDING POINTS " on the hyperbola & the auxiliary circle. 'θ' is called the eccentric angle of the point 'P' on the hyperbola. (0 ≤ θ Note : The equations x = a sec θ & y = b tan θ together represents the hyperbola 1 b y a x 2 2 2 2 =− where θ is a parameter. The parametric equations : x = a cos h φ, y = b sin h φ also represents the same hyperbola. General Note : Since the fundamental equation to the hyperbola only differs from that to the ellipse in having – b2 instead of b2 it will be found that many propositions for the hyperbola are derived from those for the ellipse by simply changing the sign of b2. 6. POSITION OF A POINT 'P' w.r.t. A HYPERBOLA : The quantity 1 b y a x 2 2 1 2 2 1 =− is positive, zero or negative according as the point (x1, y1) lies within, upon or without the curve. 7. LINE AND A HYPERBOLA : The straight line y = mx + c is a secant, a tangent or passes outside the hyperbola 1 b y a x 2 2 2 2 =+ according as: c2 > = < a2 m2 − b2. 8. TANGENTS AND NORMALS : TANGENTS : (a) Equation of the tangent to the hyperbola 1 b y a x 2 2 2 2 =− at the point (x1, y1) is 1b yy a xx 2 1 2 1 =− . Note: In general two tangents can be drawn from an external point (x1 y1) to the hyperbola and they are y − y1 = m1(x − x1) & y − y1 = m2(x − x2), where m1 & m2 are roots of the equation(x12 − a2)m2 − 2 x1y1m + y12 + b2 = 0. If D < 0, then no tangent can be drawn from (x1 y1) to the hyperbola. (b) Equation of the tangent to the hyperbola 1 b y a x 2 2 2 2 =− at the point (a sec θ, b tan θ) is 1 b θtany a θsecx =− . Note : Point of intersection of the tangents at θ1 & θ2 is x = a 2 cos 2 cos 21 21 θ+θ θ−θ , y = b 2 cos 2 sin 21 21 θ+θ θ+θ (c) y = mx 222 bma −± can be taken as the tangent to the hyperbola 1 b y a x 2 2 2 2 =− . Note that there are two parallel tangents having the same slope m. (d) Equation of a chord joining α & β is 2 cos 2 sin b y 2 cos a x β+α = β+α − β−α NORMALS: (a) The equation of the normal to the hyperbola 1 b y a x 2 2 2 2 =− at the point P(x1, y1) on it is 22 1 2 1 2 ba y yb x xa −=+ = a2 e2. (b) The equation of the normal at the point P (a secθ, b tanθ) on the hyperbola 1 b y a x 2 2 2 2 =− is 22 ba tan by sec xa += θ + θ = a 2 e2. (c) Equation to the chord of contact, polar, chord with a given middle point, pair of tangents from an external point is to be interpreted as in ellipse. 9. DIRECTOR CIRCLE : The locus of the intersection of tangents which are at right angles is known as the DIRECTOR CIRCLE of the hyperbola. The equation to the director circle is : x2 + y2 = a2 − b2. If b2 < a2 this circle is real; if b2 = a2 the radius of the circle is zero & it reduces to a point circle at the origin. In this case the centre is the only point from which the tangents at right angles can be drawn to the curve. If b2 > a2, the radius of the circle is imaginary, so that there is no such circle & so no tangents at right angle can be drawn to the curve. 10. HIGHLIGHTS ON TANGENT AND NORMAL : H−−−−1 Locus of the feet of the perpendicular drawn from focus of the hyperbola 1 b y a x 2 2 2 2 =− upon any tangent is its auxiliary circle i.e. x2 + y2 = a2 & the product of the feet of these perpendiculars is b2 · (semi C ·A)2 H−−−−2 The portion of the tangent between the point of contact & the directrix subtends a right angle at the corresponding focus. H−−−−3 The tangent & normal at any point of a hyperbola bisect the angle between the focal radii. This spells the reflection property of the hyperbola as "An incoming light ray " aimed towards one focus is reflected from the outer surface of the hyperbola towards the other focus. It follows that if an ellipse and a hyperbola have the same foci, they cut at right angles at any of their common point. Note that the ellipse 1 b y a x 2 2 2 2 =+ and the hyperbola 1 bk y ka x 22 2 22 2 = − − − (a > k > b > 0) Xare confocal and therefore orthogonal. H−−−−4 The foci of the hyperbola and the points P and Q in which any tangent meets the tangents at the vertices are concyclic with PQ as diameter of the circle. 11. ASYMPTOTES : Definition : If the length of the perpendicular let fall from a point on a hyperbola to a straight line tends to zero as the point on the hyperbola moves to infinity along the hyperbola, then the straight line is called the Asymptote of the Hyperbola. To find the asymptote of the hyperbola : Let y = mx + c is the asymptote of the hyperbola 1 b y a x 2 2 2 2 =− . Solving these two we get the quadratic as (b2− a2m2) x2− 2a2 mcx − a2 (b2 + c2) = 0 ....(1) In order that y = mx + c be an asymptote, both roots of equation (1) must approach infinity, the conditions for which are : coeff of x2 = 0 & coeff of x = 0. ⇒ b2 − a2m2 = 0 or m = a b± & a2 mc = 0 ⇒ c = 0. ∴ equations of asymptote are 0b y a x =+ and 0 b y a x =− . combined equation to the asymptotes 0 b y a x 2 2 2 2 =− . PARTICULAR CASE : When b = a the asymptotes of the rectangular hyperbola. x2 − y2 = a2 are, y = ± x which are at right angles. Note : (i) Equilateral hyperbola ⇔ rectangular hyperbola. (ii) If a hyperbola is equilateral then the conjugate hyperbola is also equilateral. (iii) A hyperbola and its conjugate have the same asymptote. (iv) The equation of the pair of asymptotes differ the hyperbola & the conjugate hyperbola by the same constant only. (v) The asymptotes pass through the centre of the hyperbola & the bisectors of the angles between the asymptotes are the axes of the hyperbola. (vi) The asymptotes of a hyperbola are the diagonals of the rectangle formed by the lines drawn through the extremities of each axis parallel to the other axis. (vii) Asymptotes are the tangent to the hyperbola from the centre. (viii) A simple method to find the coordinates of the centre of the hyperbola expressed as a general equation of degree 2 should be remembered as: Let f (x, y) = 0 represents a hyperbola. Find x f ∂ ∂ & y f ∂ ∂ . Then the point of intersection of x f ∂ ∂ = 0 & y f ∂ ∂ = 0 gives the centre of the hyperbola. 12. HIGHLIGHTS ON ASYMPTOTES: H−−−−1 If from any point on the asymptote a straight line be drawn perpendicular to the transverse axis, the product of the segments of this line, intercepted between the point & the curve is always equal to the square of the semi conjugate axis. H−−−−2 Perpendicular from the foci on either asymptote meet it in the same points as the corresponding directrix & the common points of intersection lie on the auxiliary circle. H−−−−3 The tangent at any point P on a hyperbola 1 b y a x 2 2 2 2 =− with centre C, meets the asymptotes in Q and R and cuts off a ∆ CQR of constant area equal to ab from the asymptotes & the portion of the tangent intercepted between the asymptote is bisected at the point of contact. This implies that locus of the centre of the circle circumscribing the ∆ CQR in case of a rectangular hyperbola is the hyperbola itself & for a standard hyperbola the locus would be the curve, 4(a2x2 − b2y2) = (a2 + b2)2. H−−−−4 If the angle between the asymptote of a hyperbola 1 b y a x 2 2 2 2 =− is 2θ then e = secθ. 13. RECTANGULAR HYPERBOLA : Rectangular hyperbola referred to its asymptotes as axis of coordinates. (a) Equation is xy = c2 with parametric representation x = ct, y = c/t, t ∈ R – {0}. (b) Equation of a chord joining the points P (t1) & Q(t2) is x + t1t2y = c(t1 + t2) with slope m = – 21tt 1 . (c) Equation of the tangent at P (x1, y1) is 2y y x x 11 =+ & at P (t) is t x + ty = 2c. (d) Equation of normal : y – t c = t2(x – ct) (e) Chord with a given middle point as (h, k) is kx + hy = 2hk. Suggested problems from Loney: Exercise-36 (Q.1 to 6, 16, 22), Exercise-37 (Q.1, 3, 5, 7, 12) EXERCISE–7 Q.1 Find the equation to the hyperbola whose directrix is 2x + y = 1, focus (1, 1) & eccentricity 3 . Find also the length of its latus rectum. Q.2 The hyperbola 1 b y a x 2 2 2 2 =− passes through the point of intersection of the lines, 7x + 13y – 87 = 0 and 5x – 8y + 7 = 0 & the latus rectum is 32 2 /5. Find 'a' & 'b'. Q.3 For the hyperbola 1 25 y 100 x 22 =− , prove that (i) eccentricity = 2/5 (ii) SA. S′A = 25, where S & S′ are the foci & A is the vertex. Q.4 Find the centre, the foci, the directrices, the length of the latus rectum, the length & the equations of the axes & the asymptotes of the hyperbola 16x2 − 9y2 + 32x + 36y −164 = 0. Q.5 The normal to the hyperbola 1 b y a x 2 2 2 2 =− drawn at an extremity of its latus rectum is parallel to an asymptote. Show that the eccentricity is equal to the square root of ( ) /1 5 2+ . Q.6 If a rectangular hyperbola have the equation, xy = c2, prove that the locus of the middle points of the chords of constant length 2d is (x2 + y2)(x y − c2) = d2xy. Q.7 A triangle is inscribed in the rectangular hyperbola xy = c2. Prove that the perpendiculars to the sides at the points where they meet the asymptotes are concurrent. If the point of concurrence is (x1, y1) for one asymptote and (x2, y2) for the other, then prove that x2y1= c2. Q.8 The tangents & normal at a point on 1 b y a x 2 2 2 2 =− cut the y − axis at A & B. Prove that the circle on AB as diameter passes through the foci of the hyperbola. Q.9 Find the equation of the tangent to the hyperbola x2 − 4y2 = 36 which is perpendicular to the line x − y + 4 = 0. Q.10 Ascertain the co-ordinates of the two points Q & R, where the tangent to the hyperbola 1 20 y 45 x 22 =− at the point P(9, 4) intersects the two asymptotes. Finally prove that P is the middle point of QR. Also compute the area of the triangle CQR where C is the centre of the hyperbola. Q.11 If θ1 & θ2 are the parameters of the extremities of a chord through (ae, 0) of a hyperbola 1 b y a x 2 2 2 2 =− , then show that 1e 1e 2 tan· 2 tan 21 + − + θθ = 0. Q.12 If C is the centre of a hyperbola 1 b y a x 2 2 2 2 =− , S, S′ its foci and P a point on it. Prove that SP. S′P = CP2 − a2 + b2. Q.13 Tangents are drawn to the hyperbola 3x2 − 2y2 = 25 from the point (0, 5/2). Find their equations. Q.14 If the tangent at the point (h, k) to the hyperbola 1 b y a x 2 2 2 2 =− cuts the auxiliary circle in points whose ordinates are y1 and y2 then prove that k 2 y 1 y 1 21 =+ . Q.15 Tangents are drawn from the point (α, β) to the hyperbola 3x2 − 2y2 = 6 and are inclined at angles θ and φ to the x −axis. If tan θ. tan φ = 2, prove that β2 = 2α2 − 7. Q.16 If two points P & Q on the hyperbola 1 b y a x 2 2 2 2 =− whose centre is C be such that CP is perpendicular to CQ & a < b, then prove that 2222 b 1 a 1 QC 1 PC 1 −=+ . Q.17 The perpendicular from the centre upon the normal on any point of the hyperbola 1 b y a x 2 2 2 2 =− meets at R. Find the locus of R. Q.18 If the normal to the hyperbola 1 b y a x 2 2 2 2 =− at the point P meets the transverse axis in G & the conjugate axis in g & CF be perpendicular to the normal from the centre C, then prove thatPF. PG= b2 & PF. Pg = a2 where a & b are the semi transverse & semi-conjugate axes of the hyperbola. Q.19 If the normal at a point P to the hyperbola 1 b y a x 2 2 2 2 =− meets the x − axis at G, show that SG = e. SP,, S being the focus of the hyperbola. Q.20 An ellipse has eccentricity 1/2 and one focus at the point P (1/2, 1). Its one directrix is the common tangent, nearer to the point P, to the circle x2 + y2 = 1 and the hyperbola x2 − y2 = 1. Find the equation of the ellipse in the standard form. Q.21 Show that the locus of the middle points of normal chords of the rectangular hyperbola x2 − y2 = a2 is (y2 − x2)3 = 4 a2x2y2. Q.22 Prove that infinite number of triangles can be inscribed in the rectangular hyperbola, x y = c2 whose sides touch the parabola, y2 = 4ax. Q.23 A point P divides the focal length of the hyperbola 9x² − 16y² = 144 in the ratio S′P : PS = 2 : 3 where S & S′ are the foci of the hyperbola. Through P a straight line is drawn at an angle of 135° to the axis OX. Find the points of intersection of this line with the asymptotes of the hyperbola. Q.24 Find the length of the diameter of the ellipse 1 9 y 25 x 22 =+ perpendicular to the asymptote of the hyperbola 1 9 y 16 x 22 =− passing through the first & third quadrants. Q.25 The tangent at P on the hyperbola 1 b y a x 2 2 2 2 =− meets one of the asymptote in Q. Show that the locus of the mid point of PQ is a similiar hyperbola. EXERCISE–8 Q.1 The chord of the hyperbola 1 b y a x 2 2 2 2 =− whose equation is x cos α + y sin α = p subtends a right angle at the centre. Prove that it always touches a circle. Q.2 If a chord joining the points P (a secθ, a tanθ) & Q (a secφ, a tanφ) on the hyperbola x2 − y2 = a2 is a normal to it at P, then show that tan φ = tan θ (4 sec2θ − 1). Q.3 Prove that the locus of the middle point of the chord of contact of tangents from any point of the circle x2 + y2 = r2 to the hyperbola 1 b y a x 2 2 2 2 =− is given by the equation 2 222 2 2 2 2 r )yx( b y a x + = − . Q.4 A transversal cuts the same branch of a hyperbola 1 b y a x 2 2 2 2 =− in P, P' and the asymptotes in Q, Q'. Prove that (i) PQ = P'Q' & (ii) PQ' = P'Q Q.5 Find the asymptotes of the hyperbola 2x2 − 3xy − 2y2 + 3x − y + 8 = 0. Also find the equation to the conjugate hyperbola & the equation of the principal axes of the curve. Q.6 An ellipse and a hyperbola have their principal axes along the coordinate axes and have a common foci separated by a distance 132 , the difference of their focal semi axes is equal to 4. If the ratio of their eccentricities is 3/7. Find the equation of these curves. Q.7 The asymptotes of a hyperbola are parallel to 2x + 3y = 0 & 3x + 2y = 0. Its centre is (1, 2) & it passes through (5, 3). Find the equation of the hyperbola. Q.8 Tangents are drawn from any point on the rectangular hyperbola x2 − y2 = a2 − b2 to the ellipse 1 b y a x 2 2 2 2 =+ . Prove that these tangents are equally inclined to the asymptotes of the hyperbola. Q.9 The graphs of x2 + y2 + 6 x − 24 y + 72 = 0 & x2 − y2 + 6 x + 16 y − 46 = 0 intersect at four points. Compute the sum of the distances of these four points from the point (− 3, 2). Q.10 Find the equations of the tangents to the hyperbola x2 − 9y2 = 9 that are drawn from (3, 2). Find the area of the triangle that these tangents form with their chord of contact. Q.11 A series of hyperbolas is drawn having a common transverse axis of length 2a. Prove that the locus of a point P on each hyperbola, such that its distance from the transverse axis is equal to its distance from an asymtote, is the curve (x2 – y2)2 = 4x2(x2 – a2). Q.12 A parallelogram is constructed with its sides parallel to the asymptotes of the hyperbola 1 b y a x 2 2 2 2 =− , and one of its diagonals is a chord of the hyperbola ; show that the other diagonal passes through the centre. Q.13 The sides of a triangle ABC, inscribed in a hyperbola xy = c2, makes angles α, β, γ with an asymptote. Prove that the nomals at A, B, C will meet in a point if cot2α + cot2β + cot2γ = 0 Q.14 A line through the origin meets the circle x2 + y2 = a2 at P & the hyperbola x2 − y2 = a2 at Q. Prove that the locus of the point of intersection of the tangent at P to the circle and the tangent at Q to the hyperbola is curve a4(x2 − a2) + 4 x2 y4 = 0. Q.15 A straight line is drawn parallel to the conjugate axis of a hyperbola 1 b y a x 2 2 2 2 =− to meet it and the conjugate hyperbola in the points P & Q. Show that the tangents at P & Q meet on the curve 2 2 2 2 2 2 4 4 a x4 a x b y b y = − and that the normals meet on the axis of x. Q.16 A tangent to the parabola x2 = 4 ay meets the hyperbola xy = k2 in two points P & Q. Prove that the middle point of PQ lies on a parabola. Q.17 Prove that the part of the tangent at any point of the hyperbola 1 b y a x 2 2 2 2 =− intercepted between the point of contact and the transverse axis is a harmonic mean between the lengths of the perpendiculars drawn from the foci on the normal at the same point. Q.18 Let 'p' be the perpendicular distance from the centre C of the hyperbola 1 b y a x 2 2 2 2 =− to the tangent drawn at a point R on the hyperbola. If S & S′ are the two foci of the hyperbola, then show that (RS + RS′)2 = 4 a2 + 2 2 p b1 . Q.19 P & Q are two variable points on a rectangular hyperbola xy = c2 such that the tangent at Q passes through the foot of the ordinate of P. Show that the locus of the point of intersection of tangent at P & Q is a hyperbola with the same asymptotes as the given hyperbola. Q.20 Chords of the hyperbola 1 b y a x 2 2 2 2 =− are tangents to the circle drawn on the line joining the foci as diameter. Find the locus of the point of intersection of tangents at the extremities of the chords. Q.21 From any point of the hyperbola 1 b y a x 2 2 2 2 =− , tangents are drawn to another hyperbola which has the same asymptotes. Show that the chord of contact cuts off a constant area from the asymptotes. Q.22 The chord QQ′ of a hyperbola 1 b y a x 2 2 2 2 =− is parallel to the tangent at P. PN, QM & Q′ M′ are perpendiculars to an asymptote. Show that QM · Q′ M′ = PN2. Q.23 If four points be taken on a rectangular hyperbola xy = c2 such that the chord joining any two is perpendicular to the chord joining the other two and α, β, γ, δ be the inclinations to either asymptotes of the straight lines joining these points to the centre. Then prove that ; tanα · tanβ · tanγ · tanδ = 1. Q.24 The normals at three points P, Q, R on a rectangular hyperbola xy = c2 intersect at a point on the curve. Prove that the centre of the hyperbola is the centroid of the triangle PQR. Q.25 Through any point P of the hyperbola 1 b y a x 2 2 2 2 =− a line QPR is drawn with a fixed gradient m, meeting the asymptotes in Q & R. Show that the product, (QP) · (PR) = 222 222 mab )m1(ba − + . EXERCISE–9 Q.1 Find the locus of the mid points of the chords of the circle x2 + y2 = 16, which are tangent to the hyperbola 9x2 − 16y2 = 144. [ REE '97, 6 ] Q.2 If the circle x2 + y2 = a2 intersects the hyperbola xy = c2 in four points P(x1, y1), Q(x2, y2), R(x3, y3), S(x4, y4), then(A) x1 + x2 + x3 + x4 = 0 (B) y1 + y2 + y3 + y4 = 0(C) x1 x2 x3 x4 = c4 (D) y1 y2 y3 y4 = c4 [ JEE '98, 2 ] Q.3(a) The curve described parametrically by, x = t2 + t + 1, y = t2 − t + 1 represents: (A) a parabola (B) an ellipse (C) a hyperbola (D) a pair of straight lines (b) Let P (a sec θ, b tan θ) and Q (a sec φ, b tan φ), where θ + φ = 2 pi , be two points on the hyperbola 1 b y a x 2 2 2 2 =− . If (h, k) is the point of intersection of the normals at P & Q, then k is equal to: (A) a ba 22 + (B) − + a ba 22 (C) b ba 22 + (D) − + b ba 22 (c) If x = 9 is the chord of contact of the hyperbola x2 − y2 = 9, then the equation of the corresponding pair of tangents, is : (A) 9x2 − 8y2 + 18x − 9 = 0 (B) 9x2 − 8y2 − 18x + 9 = 0 (C) 9x2 − 8y2 − 18x − 9 = 0 (D) 9x2 − 8y2 + 18x + 9 = 0 [ JEE '99, 2 + 2 + 2 (out of 200)] Q.4 The equation of the common tangent to the curve y2 = 8x and xy = –1 is (A) 3y = 9x + 2 (B) y = 2x + 1 (C) 2y = x + 8 (D) y = x + 2 [JEE 2002 Screening] Q.5 Given the family of hyperbols α2 2 cos x – α2 2 sin y = 1 for α ∈ (0, pi/2) which of the following does not change with varying α? (A) abscissa of foci (B) eccentricity (C) equations of directrices (D) abscissa of vertices [ JEE 2003 (Scr.)] Q.6 The line 2x + 6 y = 2 is a tangent to the curve x2 – 2y2 = 4. The point of contact is (A) (4, – 6 ) (B) (7, – 2 6 ) (C) (2, 3) (D) ( 6 , 1) [JEE 2004 (Scr.)] Q.7 Tangents are drawn from any point on the hyperbola 4 y 9 x 22 − = 1 to the circle x2 + y2 = 9. Find the locus of midpoint of the chord of contact. [JEE 2005 (Mains), 4] Q.8(a) If a hyperbola passes through the focus of the ellipse 1 16 y 25 x 22 =+ and its transverse and conjugate axis coincides with the major and minor axis of the ellipse, and product of their eccentricities is 1, then (A) equation of hyperbola 1 16 y 9 x 22 =− (B) equation of hyperbola 1 25 y 9 x 22 =− (C) focus of hyperbola (5, 0) (D) focus of hyperbola is ( )0,35 [JEE 2006, 5] Comprehension: (3 questions) Let ABCD be a square of side length 2 units. C2 is the circle through vertices A, B, C, D and C1 is the circle touching all the sides of the square ABCD. L is a line through A (a) If P is a point on C1 and Q in another point on C2, then 2222 2222 QDQCQBQA PDPCPBPA +++ +++ is equal to (A) 0.75 (B) 1.25 (C) 1 (D) 0.5 (b) A circle touches the line L and the circle C1 externally such that both the circles are on the same side of the line, then the locus of centre of the circle is (A) ellipse (B) hyperbola (C) parabola (D) parts of straight line (c) A line M through A is drawn parallel to BD. Point S moves such that its distances from the line BD and the vertex A are equal. If locus of S cuts M at T2 and T3 and AC at T1, then area of ∆T1T2T3 is(A) 1/2 sq. units (B) 2/3 sq. units (C) 1 sq. unit (D) 2 sq. units [JEE 2006, 5 marks each] ANSWER KEY PARABOLA EXERCISE–1 Q.2 (a, 0) ; a Q.3 2x − y + 2 = 0, (1, 4) ; x + 2y + 16 = 0, (16, −16) Q.5 3x − 2y + 4 = 0 ; x − y + 3 = 0 Q.6 (4 , 0) ; y2 = 2a(x – 4a) Q.8 y = −4x + 72, y = 3x − 33 Q.9 7y ± 2(x + 6a) = 0 Q.15 x2 + y2 + 18 x − 28 y + 27 = 0 Q.18 x − y = 1; 8 2 sq. units Q.19 −= − 9 2 x 9 4 9 8y 2 , vertex 9 8 , 9 2 Q.20 15a2/ 4 Q.21 (2a, 0) Q.23 a2 > 8b2 EXERCISE–2 Q.3 [a(t²o + 4), − 2ato] Q.5 (ax + by) (x2 + y2) + ( bx − ay)2 = 0 Q.10 (a) − 4 1 , 2 1 ; (b) y = – (x2 + x) Q.12 ( (x1 – 2a), 2y1 ) Q.21 y2 = 8 ax Q.16 Q(4, −8) Q.18 (x2 + y2 – 4ax)2 = 16a(x3 + xy2 + ay2) EXERCISE–3 Q.1 x2 − 2 y + 12 = 0 Q.3 x y= + 3 7 18 2 2 3/ Q.4 x – 2y + 1 = 0; y = mx + 14m where m = − ±5 30 10 Q.5 (a) C ; (b) B Q.6 (x + 3)y2 + 32 = 0 Q.7 (a) C ; (b) D Q.8 C Q.9 D Q.10 (a) C ; (b) α = 2 Q.11 B Q.12 xy2 + y2 – 2xy + x – 2y + 5 = 0 Q.13 (a) D, (b) A, B, (c) (i) A, (ii) B, (iii) D, (iv) C ELLIPSE EXERCISE–4 Q.1 20x2 + 45y2 − 40x − 180y − 700 = 0 Q.4 3x2 + 5y2 = 32 Q.8 x + y − 5 = 0, x + y + 5 = 0 Q.9 θ = pi3 or 5 3 pi ; 4x ± 33 y − 32 = 0 Q.10 24 sq.units Q.11 2 1 , 2 1 Q.14 55 2 sq. units Q.19 24 2 4 2 c 1 b y a x =+ EXERCISE–5 Q.1 (a2 − b2)2 x2y2 = a2 (a2 + b2)2 y2 + 4 b6x2 Q.5 bx + a 3 y = 2ab Q.13 r b2 2− Q.15 12 x + 5 y = 48 ; 12 x − 5 y = 48 EXERCISE–6 Q.1 φ = pi − tan−1 2, t = − 1 5 ; φ = pi + tan−12, t = 1 5 ; φ = ± pi 2 , t = 0 Q.3 (i) C ; (ii) C Q.4 (a) A ; (b) B, D ; (c) 25 y2 + 4 x2 = 4 x2 y2 Q.5 (x − 1)2 + y2 = 113 Q.7 Locus is an ellipse with foci as the centres of the circles C1a nd C2. Q.8 a2p2 + b2q2 = r2sec2 pi 8 = (4 – 2 2 )r2 Q.10 (a) C ; (b) A Q.11C Q.12 (a) A, (b) AB = 3 14 HYPERBOLA EXERCISE–7 Q.1 7 x2 + 12xy − 2 y2 − 2x + 4y − 7 = 0 ; 48 5 Q.2 a2 = 25/2 ; b2 = 16 Q.4 (−1, 2) ; (4, 2) & (−6, 2) ; 5x − 4 = 0 & 5x + 14 = 0 ; 3 32 ; 6 ; 8 ; y − 2 = 0 ; x + 1 = 0 ; 4x − 3y + 10 = 0 ; 4x + 3y − 2 = 0. Q.9 x + y ± 3 3 = 0 Q.10 (15, 10) and (3, − 2) and 30 sq. units Q.13 3x + 2y − 5 = 0 ; 3x − 2y + 5 = 0 Q.17 (x2 + y2)2 (a2y2 − b2x2 ) = x2y2 (a2 + b2)2 Q.20 ( ) ( ) 11yx 12 1 2 9 1 2 3 1 = − + − Q.23 (− 4, 3) & − − 4 7 3 7 , Q.24 150481 Q.25 4 x a y b 2 2 2 2− = 3 EXERCISE–8 Q.5 x − 2y + 1 = 0 ; 2x + y + 1 = 0 ; 2x2 − 3xy − 2y2 + 3x − y − 6 = 0 ; 3x − y + 2 = 0 ; x + 3y = 0 Q.6 1 36 y 49 x 22 =+ ; 1 4 y 9 x 22 =− Q.7 6x2 + 13xy + 6y2 − 38x − 37y − 98 = 0 Q.9 40 Q.10 y x= +512 3 4 ; x − 3 = 0 ; 8 sq. unit Q.19 xy = 2c 9 8 Q.20 224 2 4 2 ba 1 b y a x + =+ Q.21 ab EXERCISE–9 Q.1 (x2 + y2)2 = 16 x2 − 9 y2 Q.2 A, B, C, D Q.3 (a) A ; (b) D ; (c) B Q.4 D Q.5 A Q.6 A Q.7 4 y 9 x 22 − = 222 9 yx + Q.8 (a) A, (b) C, (c) C EXERCISE–10 Part : (A) Only one correct option 1. If (2, 0) is the vertex & y − axis the directrix of a parabola, then its focus is: (A) (2, 0) (B) (− 2, 0) (C) (4, 0) (D) (− 4, 0) 2. A parabola is drawn wi th i ts focus at (3, 4) and v ertex at the focus of the parabola y2 − 12 x − 4 y + 4 = 0. The equation of the parabola is: (A) x2 − 6 x − 8 y + 25 = 0 (B) y2 − 8 x − 6 y + 25 = 0 (C) x2 − 6 x + 8 y − 25 = 0 (D) x2 + 6 x − 8 y − 25 = 0 3. The length of the chord of the parabola, y2 = 12x passing through the vertex & making an angle of 60º with the axis of x is: (A) 8 (B) 4 (C) 16/3 (D) none 4. The length of the side of an equilateral triangle inscribed in the parabola, y2 = 4x so that one of its angular point is at the vertex is: (A) 8 3 (B) 6 3 (C) 4 3 (D) 2 3 5. The circles on focal radii of a parabola as diameter touch: (A) the tangent at the vertex (B) the axis (C) the directrix (D) none of these 6. The equation of the tangent to the parabola y = (x − 3)2 parallel to the chord joining the points (3, 0) and (4, 1) is: (A) 2 x − 2 y + 6 = 0 (B) 2 y − 2 x + 6 = 0 (C) 4 y − 4 x + 11 = 0 (D) 4 x − 4 y = 11 7. The angle between the tangents drawn from a point ( – a, 2a) to y2 = 4 ax is (A) 4 pi (B) 2 pi (C) 3 pi (D) 6 pi 8. An equation of a tangent common to the parabolas y2 = 4x and x2 = 4y is (A) x – y + 1 = 0 (B) x + y – 1 = 0 (C) x + y + 1 = 0 (D) y = 0 9. The line 4x − 7y + 10 = 0 intersects the parabola, y2 = 4x at the points A & B. The co-ordinates of the point of intersection of the tangents drawn at the points A & B are: (A) 7 2 5 2 , (B) − − 5 2 7 2 , (C) 5 2 7 2 , (D) − − 7 2 5 2 , 10. AP & BP are tangents to the parabola, y2 = 4x at A & B. If the chord AB passes through a fixed point (− 1, 1) then the equation of locus of P is (A) y = 2 (x − 1) (B) y = 2 (x + 1) (C) y = 2 x (D) y2 = 2 (x − 1) 11. Equation of the normal to the parabola, y2 = 4ax at its point (am2, 2 am) is: (A) y = − mx + 2am + am3 (B) y = mx − 2am − am3 (C) y = mx + 2am + am3 (D) none 12. At what point on the parabola y2 = 4x the normal makes equal angles with the axes? (A) (4, 4) (B) (9, 6) (C) (4, – 1) (D) (1, 2) 13. If on a given base, a triangle be described such that the sum of the tangents of the base angles is a constant, then the locus of the vertex is: (A) a circle (B) a parabola (C) an ellipse (D) a hyperbola 14. A point moves such that the square of its distance from a straight line is equal to the difference between the square of its distance from the centre of a circle and the square of the radius of the circle. The locus of the point is: (A) a straight line at right angles to the given line (B) a circle concentric with the given circle (C)a parabola with its axis parallel to the given line(D) a parabola with its axis perpendicular to the given line. 15. P is any point on the parabola, y2 = 4ax whose vertex is A. PA is produced to meet the directrix in D & M is the foot of the perpendicular from P on the directrix. The angle subtended by MD at the focus is: (A) pi/4 (B) pi/3 (C) 5pi/12 (D) pi/2 16. If the distances of two points P & Q from the focus of a parabola y2 = 4ax are 4 & 9, then the distance of the point of intersection of tangents at P & Q from the focus is: (A) 8 (B) 6 (C) 5 (D) 13 17. Tangents are drawn from the point (− 1, 2) on the parabola y2 = 4 x. The length of intercept made by these tangents on the line x = 2 is: (A) 6 (B) 6 2 (C) 2 6 (D) none of these 18. From the point (4, 6) a pair of tangent lines are drawn to the parabola, y2 = 8x. The area of the triangle formed by these pair of tangent lines & the chord of contact of the point (4, 6) is: (A) 8 (B) 4 (C) 2 (D) none of these 19. Locus of the intersection of the tangents at the ends of the normal chords of the parabola y2 = 4ax is (A)(2a + x) y2 + 4a3 = 0 (B) (2a + x) + y2 = 0 (C) (2a + x) y2 + 4a = 0 (D) none of these 20. If the tangents & normals at the extremities of a focal chord of a parabola intersect at (x1, y1) and (x2, y2) respectively, then:(A) x1 = x2 (B) x1 = y2 (C) y1 = y2 (D) x2 = y121. Tangents are drawn from the points on the line x − y + 3 = 0 to parabola y2 = 8x. Then all the chords of contact passes through a fixed point whose coordinates are: (A) (3, 2) (B) (2, 4) (C) (3, 4) (D) (4, 1) 22. The distance between a tangent to the parabola y2 = 4 A x (A > 0) and the parallel normal with gradient 1 is: (A) 4 A (B) 2 2 A (C) 2 A (D) 2 A 23. A variable parabola of latus ractum �, touches a fixed equal parabola, then axes of the two curves being parallel. The locus of the vertex of the moving curve is a parabola, whole latus rectum is: (A) � (B) 2 � (C) 4 � (D) none 24. Length of the focal chord of the parabola y2 = 4ax at a distance p from the vertex is: (A) 2 2a p (B) a p 3 2 (C) 4 3 2 a p (D) p a 2 25. AB is a chord of the parabola y2 = 4ax with vertex at A. BC is drawn perpendicular to AB meeting the axis at C. The projection of BC on the axis of the parabola is (A) a (B) 2a (C) 4a (D) 8a 26. The locus of the foot of the perpendiculars drawn from the vertex on a variable tangent to the parabola y2 = 4ax is: (A) x (x2 + y2) + ay2 = 0 (B) y (x2 + y2) + ax2 = 0 (C) x (x2 − y2) + ay2 = 0 (D) none of these 27. T is a point on the tangent to a parabola y2 = 4ax at its point P. TL and TN are the perpendiculars on the focal radius SP and the directrix of the parabola respectively. Then: (A) SL = 2 (TN) (B) 3 (SL) = 2 (TN) (C) SL = TN (D) 2 (SL) = 3 (TN) 28. The point of contact of the tangent to the parabola y2 = 9x which passes through the point (4, 10) and makes an angle θ with the axis of the parabola such that tan θ > 2 is (A) (4/9, 2) (B) (36, 18) (C) (4, 6) (D) (1/4, 3/2) 29. If the parabolas y2 = 4x and x2 = 32 y intersect at (16, 8) at an angle θ, then θ is equal to (A) tan–1 5 3 (B) tan–1 5 4 (C) pi (D) 2 pi 30. From an external point P, pair of tangent lines are drawn to the parabola, y2 = 4x. If θ1 & θ2 are the inclinations of these tangents with the axis of x such that, θ1 + θ2 = pi 4 , then the locus of P is:(A) x − y + 1 = 0 (B) x + y − 1 = 0 (C) x − y − 1 = 0 (D) x + y + 1 = 0 31. Locus of the point of intersection of the normals at the ends of parallel chords of gradient m of the parabola y2 = 4ax is: (A) 2 xm2 − ym3 = 4a (2 + m2) (B) 2 xm2 + ym3 = 4a (2 + m2) (C) 2 xm + ym2 = 4a (2 + m) (D) 2 xm2 − ym3 = 4a (2 − m2) 32. The equation of the other normal to the parabola y2 = 4ax which passes through the intersection of those at (4a, − 4a) & (9a, − 6a) is: (A) 5x − y + 115 a = 0 (B) 5x + y − 135 a = 0 (C) 5x − y − 115 a = 0 (D) 5x + y + 115 = 0 33. The point(s) on the parabola y2 = 4x which are closest to the circle, x2 + y2 − 24y + 128 = 0 is/are: (A) (0, 0) (B) ( )2 2 2, (C) (4, 4) (D) none 34. If P1 Q1 and P2 Q2 are two focal chords of the parabola y2 = 4ax, then the chords P1P2 and Q1Q2 intersect onthe (A) directrix (B) axis (C) tangent at the vertex (D) none of these 35. If x + y = k, is the normal to y2 = 12x, then k is [IIT - 2000] (A) 3 (B) 9 (C) –9 (D) – 3 36. The equation of the common tangent touching the circle (x – 3)2 + y2 = 9 and the parabola y2 = 4x above the x-axis is [IIT - 2001] (A) y3 = 3x + 1 (B) y3 = –(x + 3) (C) y3 =x + 3 (D) y3 = –(3x + 1) 37. The focal chord to y2 = 16 x is tangent to (x − 6)2 + y2 = 2, then the possible values of the slope of this chord are: [IIT - 2003] (A) {− 1, 1} (B) {− 2, 2} (C) {− 2, 1/2} (D) {2, − 1/2} 38. The normal drawn at a point (at12, –2at1) of the parabola y2 = 4ax meets it again in the point (at22, 2at2), then[IIT - 2003] (A) t2 = t1 + 1t 2 (B) t2 = t1 – 1t 2 (C) t2 = –t1 + 1t 2 (D) t2 – t1 – 1t 2 39. The angle between the tangents drawn from the point (1, 4) to the parabola y2 = 4x is [IIT - 2004] (A) 2 pi (B) 3 pi (C) 4 pi (D) 6 pi 40. Let P be the point (1, 0) and Q a point of the locus y2 = 8x. The locus of mid point of PQ is [IIT - 2005] (A) x2 + 4y + 2 = 0 (B) x2 – 4y + 2 = 0 (C) y2 – 4x + 2 = 0 (D) y2 + 4x + 2 = 0 41. A parabola has its vertex and focus in the first quadrant and axis along the line y = x. If the distances of the vertex and focus from the origin are respectively 2 and 2 2 , then an equation of the parabola is [IIT - 2006] (A) (x + y)2 = x – y + 2 (B) (x – y)2 = x + y – 2 (C) (x – y)2 = 8(x + y – 2) (D) (x + y)2 = 8(x – y + 2) Comprehension [IIT - 2006] Let ABCD be a square of side length 2 units. C2 is the circle through vertices A, B, C, D and C1 is the circletouching all the sides of the square ABCD. L is a line through A. 42. If P is a point on C1 and Q in another point on C2, 2222 2222 QDQCQBQA PDPCPBPA +++ +++ is equal to [IIT - 2006 ] (A) 0.75 (B) 1.25 (C) 1 (D) 0.5 43. A circle touch the line L and the circle C1 externally such that both the circles are on the same side of theline, then the locus of centre of the circle is [IIT - 2006 ] (A) ellipse (B) hyperbola (C) parabola (D) parts of straight line 44. A line M through A is drawn parallel to BD. Point S moves such that its distances from the line BD and the vertex A are equal. If locus of S cuts M at T2 and T3 and AC at T1, then area of ∆T1T2T3 is [IIT - 2006)] (A) 2 1 sq. units (B) 3 2 sq. units (C) 1 sq. units (D) 2 sq. units Part : (B) May have more than one options correct 45. If one end of a focal chord of the parabola y2 = 4x is (1, 2), the other end lies on (A) x2 y + 2 = 0 (B) xy + 2 = 0 (C) xy – 2 = 0 (D) x2 + xy – y – 1 = 0 46. The tangents at the extremities of a focal chord of a parabola (A) are perpendicular (B) are parallel (C) intersect on the directrix (D) intersect at the vertex 47. If from a variable point 'P' pair of perpendicular tangents PA and PB are drawn to any parabola then (A) P lies on directrix of parabola (B) chord of contact AB passes through focus (C) chord of contact AB passes through of fixed point (D) P lies on director circle 48. A normal chord of the parabola subtending a right angle at the vertex makes an acute angle θ with the x − axis, then θ = (A) arc tan 2 (B) arc sec 3 (C) arc cot 2 (D) pi 2 − arc cot 2 49. Variable chords of the parabola y2 = 4ax subtend a right angle at the vertex. Then: (A) locus of the feet of the perpendiculars from the vertex on these chords is a circle (B) locus of the middle points of the chords is a parabola (C) variable chords passes through a fixed point on the axis of the parabola (D) none of these 50. Two parabolas have the same focus. If their directrices are the x − axis & the y − axis respectively, then the slope of their common chord is: (A) 1 (B) − 1 (C) 4/3 (D) 3/4 51. P is a point on the parabola y2 = 4ax (a > 0) whose vertex is A. PA is produced to meet the directrix in D and M is the foot of the perpendicular from P on the directrix. If a circle is described on MD as a diameter then it intersects the x−axis at a point whose co−ordinates are: (A) (− 3a, 0) (B) (− a, 0) (C) (− 2a, 0) (D) (a, 0) EXERCISE–11 1. Find the vertex, axis, focus, directrix, latusrectum of the parabola x2 + 2y – 3x + 5 = 0. 2. Find the set of values of α in the interval [pi/2, 3pi/2], for which the point (sinα, cosα) does not lie outside the parabola 2y2 + x – 2 = 0. 3. Two perpendicular chords are drawn from the origin ‘O’ to the parabola y = x2, which meet the parabola at P and Q Rectangle POQR is completed. Find the locus of vertex R. 4. Find the equation of tangent & normal at the ends of the latus rectum of the parabola y2 = 4a (x – a). 5. Prove that the straight line �x + my + n = 0 touches the parabola y2 = 4ax if �n = am2. 6. If tangent at P and Q to the parabola y2 = 4ax intersect at R then prove that mid point of R and M lies on the parabola, where M is the mid point of P and Q. 7. Find the equation of normal to the parabola x2 = 4y at (9, 6). 8. Find the equation of the chord of y2 = 8x which is bisected at (2, – 3) 9. Find the locus of the mid-points of the chords of the parabola y2 = 4ax which subtend a right angle at the vertex of the parabola. 10. Find the equation of the circle which passes through the focus of the parabola x2 = 4 y & touches it at the point (6, 9). 11. Prove that the normals at the points, where the straight line �x + my = 1 meets the parabola y2 = 4ax, meet on the normal at the point �� am4 , am4 2 2 of the parabola. 12. If the normals at three points P, Q, and R on parabola y2 = 4ax meet in a point O and S be the focus, prove that SP. SQ . SR = a. SO2. 13. Show that the locus of the point of intersection of the tangents to y2 = 4ax which intercept a constant length d on the directrix is (y2 – 4ax) (x + a)2 = d2 x2. 14. Show that the distance between a tangent to the parabola y2 = 4ax and the parallel normal is a sec2θ cosec θ, where θ is the inclination of the either with the axis of the parabola. 15. P and Q are the point of contact of the tangents drawn from a point R to the parabola y2 = 4ax. If PQ be a normal to the parabola at P, prove that PR is bisected by the directrix. 16. A circle is described whose centre is the vertex and whose diameter is three-quarters of the latus rectum of the parabola y2 = 4ax. If PQ is the common chord of the circle and the parabola and L1 L2 is the latus rectum, then prove that the area of the trapezium PL1 L2Q is 2 2 2 + a 2 . 17. If the normals from any point to the parabola x2 = 4y cuts the line y = 2 in points whose abscissa are in A.P., then prove that slopes of the tangents at the 3 conormal points are in GP. 18. Prove that the length of the intercept on the normal at the point (at2, 2at) made by the circle which is described on the focal distance of the given point as diameter is a 2t1+ . 19. A parabola is drawn to pass through A and B, the ends of a diameter of a given circle of radius a, and to have as directrix a tangent to a concentric circle of radius b; then axes being AB and a perpendicular diameter, prove that the locus of the focus of the parabola is 2 2 b x + 22 2 ab y − =1 20. PNP′ is a double ordinate of the parabola then prove that the locus of the point of intersection of the normal at P and the straight l ine through P′ paral lel to the axis is the equal parabola y2 = 4a (x – 4a). 21. Find the locus of the point of intersection of those normals to the parabola x2 = 8 y which are at right angles to each other. [IIT - 1997] 22. Let C1 and C2 be respectively, the parabolas x2 = y – 1 and y2 = x – 1. Let P be any point on C1 and Qbe any point on C2. Let P1 and Q1 be the reflections of P and Q, respectively, with respect to the liney = x. Prove that P1 lies on C2, Q1 lies on C1 and PQ ≥ min {PP1 , QQ1}. Hence or otherwise determinepoints P0 and Q0 on the parabolas C1 and C2 respectively such that P0 Q0 ≤ PQ for all pairs of points(P, Q) with P on C1 and Q on C2. [IIT - 2000] 23. Normals are drawn from the point P with slopes m1, m2, m3 to the parabola y2 = 4x. If locus of P with m2 m2 = α is a part of the parabola itself then find α. [IIT - 2003] EXERCISE–10 1. C 2. A 3. A 4. A 5. A 6. D 7. B 8. C 9. C 10. A 11. A 12. D 13. B 14. D 15. D 16. B 17. B 18. C 19. A 20. C 21. C 22. B 23. B 24. C 25. C 26. A 27. C 28. A 29. A 30. C 31. A 32. B 33. C 34. A 35. B 36. C 37. A 38. A 39. B 40. C 41. C 42. A 43. C 44. C 45. ABD 46. AC 47. ABCD 48. BD 49. ABC 50. AB 51. AD EXERCISE–11 1. vertex ≡ − 8 29 , 2 3 , focus − 8 33 , 2 3 axis x = 3, directrix y = – 3 29 . Latus rectum = 2. 2. α ∈ [pi/2, 5pi/6] ∪ [pi, 3pi/2] 3. y2 = x – 2 4. Tangent y = x, y = – x, Normal x + y = 4a, x – y = 4a 7. 2x + 9y = 72 8. 4x + 3y + 1 = 0 9. y2 – 2ax + 8a2 = 0 10. x2 + y2 + 18x – 28y + 27 = 0 21. x2 − 2 y + 12 = 0 23. α = 2 EXERCISE–12 Part : (A) Only one correct option 1. The eccentricity of the ellipse 4x2 + 9y2 + 8x + 36y + 4 = 0 is (A) 6 5 (B) 5 3 (C) 3 2 (D) 3 5 2. The equation of the ellipse with its centre at (1, 2), focus at (6, 2) and passing through the point (4, 6) is (A) 120 )2y( 45 )1x( 22 = − + − (B) 20 )1x( 2− + 45 )2y( 2− = 1 (C) 116 )2y( 25 )1x( 22 = − + − (D) 125 )2y( 16 )1x( 22 = − + − 3. The eccentricity of the ellipse which meets the straight line 7 x + 2 y = 1 on the axis of x and the straight line 3 x – 5 y = 1 on the axis of y and whose axes lie along the axes of coordinates, is (A) 7 23 (B) 7 62 (C) 7 3 (D) none of these 4. The curve represented by x = 3 (cos t + sin t), y = 4 (cos t – sin t), is (A) ellipse (B) parabola (C) hyperbola (D) circle 5. Minimum area of the triangle by any tangent to the ellipse 2 2 a x + 2 2 b y = 1 with the coordinate axes is (A) 2 ba 22 + (B) 2 )ba( 2+ (C) ab (D) 2 )ba( 2− 6. A circle has the same centre as an ellipse & passes through the focii F1 & F2 of the ellipse, such that the two curves intersect in 4 points. Let 'P' be any one of their point of intersection. If the major axis of the ellipse is 17 & the area of the triangle PF1F2 is 30, then the distance between the focii is : (A) 11 (B) 12 (C) 13 (D) 15 7. Q is a point on the auxiliary circle corresponding to the point P of the ellipse 2 2 2 2 b y a x + = 1. If T is the foot of the perpendicular dropped from the focus S onto the tangent to the auxiliaryy circle at Q then the ∆ SPT is : (A) isosceles (B) equilateral (C) right angled (D) right isosceles 8. x − 2y + 4 = 0 is a common tangent to y2 = 4x & 2 22 b y 4 x + = 1. Then the value of ‘b’ and the other common tangent are given by : (A) b = 3 ; x + 2y + 4 = 0 (B) b = 3; x + 2y + 4 = 0 (C) b = 3 ; x + 2y − 4 = 0 (D) b = 3 ; x − 2y − 4 = 0 9. The locus of point of intersection of tangents to an ellipse 2 2 a x + 2 2 b y = 1 at the points whose the sum of eccentric angles is constant, is : (A) a hyperbola (B) an ellipse (C) a circle (D) a straight line 10. A tangent having slope of − 3 4 to the ellipse 18 x2 + 32 y2 = 1 intersects the major & minor axes in points A & B respectively. If C is the centre of the ellipse, then the area of the triangle ABC is : (A) 12 sq. units (B) 24 sq. units (C) 36 sq. units (D) 48 sq. units 11. The normal at a variable point P on an ellipse 2 2 2 2 b y a x + = 1 of eccentricity ‘e’ meets the axes of the ellipse in Q and R then the locus of the mid-point of QR is a conic with an eccentricity e′ such that : (A) e ′ is independent of e (B) e′ = 1 (C) e′ = e (D) e′ = 1/e 12. y = mx + c is a normal to the ellipse, 2 2 2 2 b y a x + = 1, if c2 is equal to : (A) 222 222 bma )ba( + − (B) 22 222 ma )ba( − (C) 222 2222 mba m)ba( + − (D) 222 2222 bma m)ba( + − 13. An arc of a bridge is semi-elliptical with major axis horizontal. The length of the base is 9 meter and the highest part of the bridge is 3 meter from the horizontal. The best approximation of the Pillar 2 meter from the centre of the base is : (A) 11/4 m (B) 8/3 m (C) 7/2 m (D) 2 m 14. Point 'O' is the centre of the ellipse with major axis AB & minor axis CD. Point F is one focus of the ellipse. If OF = 6 & the diameter of the inscribed circle of triangle OCF is 2, then the product (AB) (CD) is (A) 64 (B) 12 (C) 65 (D) 3 15. An ellipse is such that the length of the latus rectum is equal to the sum of the lengths of its semi principal axes. Then: (A) Ellipse bulges to a circle (B) Ellipse becomes a line segment between the two foci (C) Ellipse becomes a parabola (D) none of these 16. A line of fixed length (a + b) moves so that its ends are always on two fixed perpendicular straight lines. The locus of the point which divided this line into portions of lengths a & b is: (A) an ellipse (B) an hyperbola (C) a circle (D) none of these 17. The line 2x + y = 3 cuts the ellipse 4x2 + y2 = 5 at P and Q. If θ be the angle between the normals at these points, then tanθ = (A) 1/2 (B) 3/4 (C) 3/5 (D) 5 18. The focal chord of y2 = 16x is tangent to (x – 6)2 + y2 = 2, then the possible values of the slope of this chord are [IIT – 2003] (A) {– 1, 1} (B) {– 2, 2} (C) − 2 1 ,2 (D) − 2 1 ,2 19. A tangent is drawn to ellipse x2 + 2y2 = 2. Then the locus of mid point of portion of the tangent intercepted between coordinate axes. [IIT - 2004 ] (A) 22 y4 1 x2 1 + = 1 (B) 22 y2 1 x4 1 + = 1 (C) 1 4 y 2 x 22 =+ (D) 1 2 y 4 x 22 =+ 20. The locus of mid point of the intercept of the tangent drawn from an external point to the ellipse x2 + 2y2 = 2 between the coordinate axes, is [IIT - 2004] (A) 2x 1 + 2y2 1 = 1 (B) 2x4 1 + 2y2 1 = 1 (C) 2x2 1 + 2y4 1 = 1 (D) 2x2 1 + 2y 1 =1 21. An ellipse has OB as semi-minor axis, F and F′ its foci and the angle FBF′ is a right angle. Then, the eccentricity of the ellipse is [IIT - 2005] (A) 4 1 (B) 3 1 (C) 2 1 (D) 2 1 Part : (B) May have more than one options correct 22. The tangent at any point ‘P’ on the standard ellipse with focii as S & S′ meets the tangents at the vertices A & A′ in the points V & V′, then : (A) (AV) (A′ V′) = b2 (B) (AV) (A′ V′) = a2 (C) ∠V′ SV = 90º (D) V′ S′ VS is a cyclic quadrilateral 23. Identify the statements which are True. (A) the equation of the director circle of the ellipse, 5x2 + 9y2 = 45 is x2 + y2 = 14. (B) the sum of the focal distances of the point (0, 6) on the ellipse x 2 25 + y2 36 = 1 is 10. (C) the point of intersection of any tangent to a parabola & the perpendicular to it from the focus lies on the tangent at the vertex. (D) the line through focus and (at21, 2 at1) on y2 = 4ax, meets it again in the point (at22, 2 at2) ifft1t2 = − 1. 24. The Cartesian equation of the curve whose parametric equation is x = 2t – 3 and y = 4t2 – 1 is given by (A) (x + 3)2 – y – 1 = 0 (B) x2 + 6x – y + 8 = 0 (C) (y + 1)2 + x + 3 = 0 (D) y2 + 6x – 2y + 4 = 0 25. If P is a point of the ellipse 2 2 a x + 2 2 b y = 1, whose focii are S and S′. Let ∠PSS′ = α and ∠PS′S = β, then (A) PS + PS′ = 2a, if a > b (B) PS + PS′ = 2b, if a < b (C) tan 2 α tan 2 β = e1 e1 + − (D) tan 2 α tan 2 β = 2 22 b ba − [a – 22 ba − ] when a > b 26. If the distance between the focii of an ellipse is equal to the length of its latus rectum, the eccentricity of the ellipse is : (A) 2 15 + (B) 2 15 − (C) 2 25 − (D) 15 2 + EXERCISE–13 1. Let use consider an ellipse whose major and minor axis are 3x + 4y – 7 = 0 and 4x – 3y – 1 = 0 respectively 'P' be a variable point on the ellipse at any instance, it is given that distance of 'P' from major and minor axis are 4 and 5 respectively. It is also given that maximum distance of 'P' from minor axis is 5 2 , then find its eccentricity.. 2. Prove that the area of the triangle formed by the three points on an ellipse, whose eccentric angle are θ, φ, and ψ, is 2 ab sin 2sin2sin2 φ−θθ−ψψ−φ . 3. Find the equation of tangents to the ellipse 50 x2 + 32 y2 = 1 which passes through a point (15, – 4). 4. If 'P' be a moving point on the ellipse 25 x2 + 16 y2 = 1 in such a way that tangent at 'P' intersect x = 3 25 at Q then circle on PQ as diameter passes through a fixed point. Find that fixed point. 5. Any tangent to an ellipse is cut by the tangents at the ends of major axis in the points T and T ′. Prove that the circle, whose diameter is T T ′ will pass through the foci of the ellipse. 6. If 3x + 4y = 12 intersect the ellipse 25 x2 + 16 y2 = 1 at P and Q, then find the point of intersection of tangents at P and Q. 7. Find the equation of the largest circle with centre (1, 0) that can be inscribed in the ellipse x2 + 4y2 = 16. 8. If P is a variable point on the ellipse 2 2 a x + 2 2 b y = 1 whose foci are S and S′, then prove that the locus of the incentre of ∆PSS′ is an ellipse whose eccentricity is ′+ e1 e2 where e is the eccentricity of the given ellipse. 9. The tangent at a point P (a cosθ, b sinθ) of an ellipse 2 2 a x + 2 2 b y = 1, meets its auxiliary circle in two points, the chord joining which subtends a right angle at the centre. Show that the eccentricity of the ellipse is (1 + sin2θ)–1/2. 10. A circle of radius r is concentric with the ellipse 2 2 a x + 2 2 b y = 1. Prove that the common tangent is inclined to the major axis at an angle tan–1 − − 22 22 ra br . 11. ‘O’ is the origin & also the centre of two concentric circles having radii of the inner & the outer circle as ‘a’ & ‘b’ respectively. A line OPQ is drawn to cut the inner circle in P & the outer circle in Q. PR is drawn parallel to the y− axis & QR is drawn parallel to the x− axis. Prove that the locus of R is an ellipse touching the two circles. If the focii of this ellipse lie on the inner circle, find the ratio of inner : outer radii & find also the eccentricity of the ellipse. 12. If any two chords be drawn through two points on the major axis of an ellipse equidistant from the centre, show that 1 2 tan. 2 tan. 2 tan. 2 tan =δγβα , where α, β, γ, δ are the eccentric angles of the extremities of the chords. 13. The tangent at a point P on the ellipse 1 b y a x 2 2 2 2 =+ intersects the major axis in T & N is the foot of the perpendicular from P to the same axis. Show that the circle on NT as diameter intersects the auxiliary circle orthogonally. 14. Show that the equation of the tangents to the ellipse x a y b 2 2 2 2+ = 1 at the points of intersection with the line, p x + q y + 1 = 0 is, −+ 1 b y a x 2 2 2 2 (p2 a2 + q2 b2 − 1) = (p x + q y + 1)2. 15. Common tangents are drawn to the parabola y2 = 4x & the ellipse 3x2 + 8y2 = 48 touching the parabola at A & B and the ellipse at C & D. Find the area of the quadrilateral. 16. A tangent to the ellipse 1 b y a x 2 2 2 2 =+ meets the ellipse bab y a x 22 +=+ in the points P and Q; prove that the tangents at P and Q are at right angles. 17. Let P be a point on the ellipse 2 2 a x + 2 2 b y = 1 for which the area of the ∆PON is the maximum where O is the origin and N is the foot of the perpendicular from O to the tangent at P. Find the maximum area and eccentric angle of point P. 18. Find the equation of the largest circle with centre (1, 0) that can be inscribed in the ellipse x2 + 4 y2 = 16. [IIT - 1999] 19. Let P be point on the ellipse x a 2 2 + y b 2 2 = 1, 0 < b < a. Let the line parallel to y−axis passing through P meet the circle x2 + y2 = a2 at the point Q such that P and Q are on the same side of x−axis. For two positive real numbers r and s. Find the locus of the point R on PQ such that PR : RQ = r : s as P varies over the ellipse. [IIT - 2001] 20. Prove that in an ellipse, the perpendicular from a focus upon any tangent and the line joining the centre of the ellipse to the point of contact meet on the corresponding directrix. [IIT - 2002] EXERCISE–12 1. D 2. A 3. B 4. A 5. C 6. C 7. A 8. A 9. D 10. B 11. C 12. C 13. B 14. C 15. A 16. A 17. B 18. A 19. A 20. B 21. C 22. ACD 23. ACD 24. AB 25. ABD 26. BD EXERCISE–13 1. = 5 3 e 3. 4x + 5y = 40, 4x – 35y = 200. 4. (3, 0) 6. 3 16 , 4 25 11. 1 2 1 2 , 18. (x − 1)2 + y2 = 113 19. x a 2 2 + y r s ra sb 2 2 2 ( ) ( ) + + = 1 EXERCISE–14 Part : (A) Only one correct option 1. An ellipse and a hyperbola have the same centre origin, the same foci and the minor-axis of the one is the same as the conjugate axis of the other. If e1, e2 be their eccentricities respectively, then 1 1 1 2 2 2e e + = (A) 1 (B) 2 (C) 4 (D) none 2. The line 5x + 12y = 9 touches the hyperbola x2 – 9y2 = 9 at the point (A) (– 5, 4/3) (B) (5, – 4/3) (C) (3, – 1/2) (D) none of these 3. If the foci of the ellipse x y b 2 2 225 + = 1 & the hyperbola x y2 2 144 81 − = 1 25 coincide then the value of b 2 is : (A) 4 (B) 9 (C) 16 (D) none 4. The tangents from (1, 2 2 ) to the hyperbola 16x2 – 25y2 = 400 include between them an angle equal to: (A) 6 pi (B) 4 pi (C) 3 pi (D) 2 pi 5. If P(x1, y1), Q(x2, y2), R(x3, y3) and S(x4, y4) are four concyclic points on the rectangular hyperbola xy = c2, the coordinates of orthocentre of the ∆PQR are (A) (x4, y4) (B) (x4, – y4) (C) (–x4, – x4) (D) (– x4, – y4) 6. The asymptotes of the hyperbola xy = hx + ky are : (A) x − k = 0 & y − h = 0 (B) x + h = 0 & y + k = 0 (C) x − k = 0 & y + h = 0 (D) x + k = 0 & y − h = 0 7. The combined equation of the asymptotes of the hyperbola 2x2 + 5xy + 2y2 + 4x + 5y = 0 is (A) 2x2 + 5xy + 2y2 + 4x +5y + 2 = 0 (B) 2x2 + 5xy + 2y2 + 4x +5y – 2 = 0 (C) 2x2 + 5xy + 2y2 = 0 (D) none of these 8. If the hyperbolas, x2 + 3 x y + 2 y2 + 2 x + 3 y + 2 = 0 and x2 + 3 x y + 2 y2 + 2 x + 3 y + c = 0 are conjugate of each other, then the value of ‘c‘ is equal to : (A) − 2 (B) 4 (C) 0 (D) 1 9. P is a point on the hyperbola x a y b 2 2 2 2− = 1, N is the foot of the perpendicular from P on the transverse axis. The tangent to the hyperbola at P meets the transverse axis at T. If O is the centre of the hyperbola, then OT. ON is equal to : (A) e2 (B) a2 (C) b2 (D)b2/a2 10. The locus of the foot of the perpendicular from the centre of the hyperbola xy = c2 on a variable tangent is : (A) (x2 − y2)2 = 4c2 xy (B) (x2 + y2)2 = 2c2 xy (C) (x2 + y2) = 4x2 xy (D) (x2 + y2)2 = 4c2 xy 11. If the chords of contact of tangents from two points (x1, y1) and (x2, y2) to the hyperbola 2 2 a x – 2 2 b y = 1 are at right angles, then 21 21 yy xx is equal to (A) – 2 2 b a (B) – 2 2 a b (C) – 4 4 a b (D) – 4 4 b a 12. The equations of the transverse and conjugate axes of a hyperbola are respectively x + 2y – 3 = 0, 2x – y + 4 = 0, and their respective lengths are 2 and 2/ 3 . The equation of the hyperbola is (A) 5 2 (x + 2y – 3)2 – 5 3 (2x – y + 4)2 = 1 (B) 5 2 (2x – y + 4)2 – 5 3 (x + 2y – 3)2 = 1 (C) 2(2x – y + 4)2 – 3 (x + 2y – 3)2 = 1 (D) 2(x + 2y – 3)2 – 3 (2x – y + 4)2 = 1 13. The chord PQ of the rectangular hyperbola xy = a2 meets the x-axis at A; C is the mid point of PQ & 'O' is the origin. Then the ∆ ACO is : (A) equilateral (B) isosceles (C) right angled (D) right isosceles. 14. The number those triangles that can be inscribed in the rectangular hyperbola xy= c2 whose all sides touch the parabola y2 = 4ax is : (A) 0 (B) 1 (C) 2 (D) Infinite 15. The number of points from where a pair of perpendicular tangents can be drawn to the hyperbola, x2 sec2 α − y2 cosec2 α = 1, α ∈ (0, pi/4), is : (A) 0 (B) 1 (C) 2 (D) infinite 16. If hyperbola 2 2 b x – 2 2 a y = 1 passes through the focus of ellipse 2 2 a x + 2 2 b y = 1 then eccentricity of hyperbola is (A) 2 (B) 3 2 (C) 3 (D) None of these 17. The transverse axis of a hyperbola is of length 2a and a vertex divides the segment of the axis between the centre and the corresponding focus in the ratio 2 : 1, the equation of the hyperbola is : (A) 4x2 – 5y2 = 4a2 (B) 4x2 – 5y2 = 5a2 (C) 5x2 – 4y2 = 4a2 (D) 5x2 – 4y2 = 5a2 18. If AB is a double ordinate of the hyperbola 2 2 a x – 2 2 b y = 1 such that ∆OAB (O is the origin) is an equilateral triangle, then the eccentricity ‘e’ of the hyperbola satisfies (A) e > 3 (B) 1 < e < 2 3 2 (C) e = 3 2 (D) e > 3 2 19. If x cos α + y sin α = p, a variable chord of the hyperbola 2 2 a x – 2 2 a2 y = 1 subtends a right angle at the centre of the hyperbola, then the chords touch a fixed circle whose radius is equal to (A) 2 a (B) 3 a (C) 2 a (D) 5 a 20. Two conics 2 2 a x – 2 2 b y =1 and x2 = – b 1 y intersect if (A) 0 < b ≤ 2 1 (B) 0 < a < 2 1 (C) a2 < b2 (D) a2 > b2 21. Number of points on hyperbola 2 2 a x – 2 2 b y = 1 from where mutually perpendicular tangents can be drawn to circle x2 + y2 = a2 (a > b) is (A) 2 (B) 3 (C) infinite (D) 4 22. The normal to the rectangular hyperbola xy = c2 at the point ‘t1’ meets the curve again at the point ‘t2’.The value of t13t2 is(A) –1 (B) –|c| (C) |c| (D) 1 23. If the tangent and the normal to a rectangular hyperbola cut off intercepts x1 and x2 on one axis andy1 and y2 on the other axis, then(A) x1y1 + x2y2 = 0 (B) x1y2 + x2y1 = 0 (C) x1x2 + y1y2 = 0 (D) none of these 24. If x = 9 is the chord of contact of the hyperbola x2 – y2 = 9, then the equation of the corresponding pair of tangents is [IIT - 1999] (A) 9x2 – 8y2 + 18x – 9 = 0 (B) 9x2 – 8y2 + 18x + 9 = 0 (C) 9x2 – 8y2 – 18x – 9 = 0 (D) 9x2 – 8y2 + 18x + 9 = 0 Part : (B) May have more than one options correct 25. The value of m for which y = mx + 6 is a tangent to the hyperbola 100 x2 – 49 y2 = 1 is (A) 20 17 (B) – 20 17 (C) 17 20 (D) – 17 20 26. If (a sec θ, b tan θ) and (a secφ, b tan φ) are the ends of a focal chord of 2 2 a x – 2 2 b y = 1, then tan 2 θ tan 2 φ equals to (A) 1e 1e + − (B) e1 e1 + − (C) e1 e1 − + (D) 1e 1e − + 27. A common tangent to 9x2 – 16y2 = 144 and x2 + y2 = 9 is (A) y = 7 3 x + 7 15 (B) y = 3 7 2 x + 7 15 (C) y = 2 7 3 x + 15 7 (D) y = 3 7 2 x – 7 15 28. The equation of a hyperbola with co-ordinate axes as principal axes, if the distances of one of its vertices from the foci are 3 & 1 can be : (A) 3x2 − y2 = 3 (B) x2 − 3y2 + 3 = 0 (C) x2 − 3y2 − 3 = 0 (D) none 29. If (5, 12) and (24, 7) are the foci of a conic passing through the origin then the eccentricity of conic is (A) 386 /12 (B) 386 /13 (C) 386 /25 (D) 386 /38 30. If the normal at P to the rectangular hyperbola x2 − y2 = 4 meets the axes in G and g and C is the centre of the hyperbola, then (A) PG = PC (B) Pg = PC (C) PG = Pg (D) Gg = PC 31. The tangent to the hyperbola, x2 − 3y2 = 3 at the point ( )3 0, when associated with two asymptotes constitutes : (A) isosceles triangle (B) an equilateral triangle (C) a triangles whose area is 3 sq. units (D) a right isosceles triangle. 32. Which of the following equations in parametric form can represent a hyperbolic profile, where 't' is a parameter. (A) x = a2 t t+ 1 & y = b 2 t t − 1 (B) tx a − y b + t = 0 & x a + ty b − 1 = 0 (C) x = et + e−t & y = et − e−t (D) x2 − 6 = 2 cos t & y2 + 2 = 4 cos2 t2 33. If a hyperbola passes through the focii of the ellipse 25 x2 + 16 y2 = 1. Its transverse and conjugate axes coincide respectively with the major and minor axes of the ellipse and if the product of eccentricities of hyperbola and ellipse is 1, then [IIT - JEE ] (A) the equation of hyperbola is 9 x2 – 16 y2 = 1 (B) the equation of hyperbola is 9 x2 – 25 y2 = 1 (C) focus of hyperbola is (5, 0) (D) focus of hyperbola is (5 3 , 0) EXERCISE–15 1. For the hyperbola x2/100 − y2/25 = 1, prove that (i) eccentricity = 5 2/ (ii) SA . S′A = 25, where S & S′ are the foci & A is the vertex . 2. Chords of the hyperbola, x2 − y2 = a2 touch the parabola, y2 = 4 a x. Prove that the locus of their middle points is the curve, y2 (x − a) = x3. 3. Find the asymptotes of the hyperbola 2 x2 − 3 xy − 2 y2 + 3 x − y + 8 = 0 . Also find the equation to the conjugate hyperbola & the equation of the principal axes of the curve . 4. Given the base of a triangle and the ratio of the tangent of half the base angles. Show that the vertex moves on a hyperbola whose foci are the extremities of the base. 5. If p1 and p2 are the perpendiculars from any point on the hyperbola x a y b 2 2 2 2− = 1 on its asymptotes, then prove that, 22 21 b 1 a 1 pp 1 += . 6. If two points P & Q on the hyperbola x2/a2 − y2/b2 = 1 whose centre is C be such that CP is perpendicular to CQ & a < b, then prove that 1 1 1 12 2 2 2CP CQ a b+ = − . 7. If the normal at a point P to the hyperbola x2/a2 − y2/b2 = 1 meets the x−axis at G, show that SG = e . SP, S being the focus of the hyperbola . 8. A transversal cuts the same branch of a hyperbola x2/a2 − y2/b2 = 1 in P, P′ and the asymptotes in Q, Q′. Prove that (i) PQ = P′Q′ & (ii) PQ′ = P′Q 9. If PSP′ & QSQ′ are two perpendicular focal chords of the hyperbola x2/a2 − y2/b2 = 1 then prove that 1 1 � � � �( ) . ( ) ( ) . ( )PS SP QS SQ′ + ′ is a constant . 10. A line through the origin meets the circle x2 + y2 = a2 at P & the hyperbola x2 − y2 = a2 at Q . Prove that the locus of the point of intersection of the tangent at P to the circle and the tangent at Q to the hyperbola is curve a4 (x2 − a2) + 4 x2 y4 = 0 . 11. Prove that the part of the tangent at any point of the hyperbola x2/a2 − y2/b2 = 1 intercepted between the point of contact and the transverse axis is a harmonic mean between the lengths of the perpendiculars drawn from the foci on the normal at the same point . 12. Let 'p' be the perpendicular distance from the centre C of the hyperbola x2/a2 − y2/b2 = 1 to the tangent drawn at a point R on the hyperbola . If S & S′ are the two foci of the hyperbola, then show that (RS + RS′)2 = 4 a2 1 2 2+ b p . 13. Chords of the hyperbola x2/a2 − y2/b2 = 1 are tangents to the circle drawn on the line joining the foci as diameter . Find the locus of the point of intersection of tangents at the extremities of the chords . 14. A point P divides the focal length of the hyperbola 9x² − 16y² = 144 in the ratio S′P : PS = 2 : 3 where S & S′ are the foci of the hyperbola. Through P a straight line is drawn at an angle of 135° to the axis OX. Find the points of intersection of this line with the asymptotes of the hyperbola. 15. The angle between a pair of tangents drawn from a point P to the parabola y2 = 4ax is 45º. Show that the locus of the point P is a hyperbola. [IIT - 1998] 16. Tangents are drawn from any point on the hyperbola 9 x2 – 4 y2 = 1 to the circle x2 + y2 = 9. Find the locus of mid-point of the chord of constant. [IIT - 2005] EXERCISE–14 1. A 2. B 3. C 4. D 5. D 6. A 7. A 8. C 9. B 10. D 11. D 12. B 13. B 14. D 15. D 16. C 17. D 18. D 19. A 20. B 21. D 22. A 23. C 24. B 25. AB 26. BC 27. BD 28. AB 29. AD 30. ABC 31. BC 32. ACD 33. AC EXERCISE–15 3. x − 2y + 1 = 0 ; 2x + y + 1 = 0 ; 2x2 − 3xy − 2y2 + 3x − y − 6 = 0 ; 3x − y + 2 = 0 ; x + 3y = 0 13. x a y b a b 2 4 2 4 2 2 1 + = + 14. (− 4, 3) & − − 4 7 3 7 , 16. 4 y 9 x 22 − = 222 9 yx + 82 of 91 Some questions (Assertion–Reason type) are given below. Each question contains Statement – 1 (Assertion) and Statement – 2 (Reason). Each question has 4 choices (A), (B), (C) and (D) out of which ONLY ONE is correct. So select the correct choice : Choices are : (A) Statement – 1 is True, Statement – 2 is True; Statement – 2 is a correct explanation for Statement – 1. (B) Statement – 1 is True, Statement – 2 is True; Statement – 2 is NOT a correct explanation for Statement – 1. (C) Statement – 1 is True, Statement – 2 is False. (D) Statement – 1 is False, Statement – 2 is True. PPAARRAABBOOLLAA 286. Statement-1 : Slope of tangents drawn from (4, 10) to parabola y2 = 9x are 1 9, 4 4 . Statement-2 : Every parabola is symmetric about its directrix. 287. Statement-1 : Though (λ, λ + 1) there can’t be more than one normal to the parabola y2 = 4x, if λ < 2. Statement-2 : The point (λ, λ + 1) lies outside the parabola for all λ ≠ 1. 288. Statement-1 : If x + y = k is a normal to the parabola y2 = 12x, then k is 9. Statement-2 : Equation of normal to the parabola y2 = 4ax is y – mx + 2am + am3 = 0 289. Statement-1 : If b, k are the segments of a focal chord of the parabola y2 = 4ax, then k is equal to ab/b-a. Statement-2 : Latus rectum of the parabola y2 = 4ax is H.M. between the segments of any focal chord of the parabola 290. Statement-1 : Two parabolas y2 = 4ax and x2 = 4ay have common tangent x + y + a = 0 Statement-2 : x + y + a = 0 is common tangent to the parabolas y2 = 4ax and x2 = 4ay and point of contacts lie on their respective end points of latus rectum. 291. Statement-1 : In parabola y2 = 4ax, the circle drawn taking focal radii as diameter touches y-axis. Statement-2 : The portion of the tangent intercepted between point of contact and directix subtends 90° angle at focus. 292. Statement-1 : The joining points (8, -8) & (1/2, −2), which are lying on parabola y2 = 4ax, pass through focus of parabola. Statement-2 : Tangents drawn at (8, -8) & (1/2, -2) on the parabola y2 = 4ax are perpendicular. 293. Statement-1 : There are no common tangents between circle x2 + y2 – 4x + 3 = 0 and parabola y2 = 2x. Statement-2 : Equation of tangents to the parabola x2 = 4ay is x = my + a/m where m denotes slope of tangent. 294. Statement-1 : Three distinct normals of the parabola y2 = 12x can pass through a point (h ,0) where h > 6. Statement-2 : If h > 2a then three distinct nroamls can pass through the point (h, 0) to the parabola y2 = 4ax. 295. Statement-1 : The normals at the point (4, 4) and 1 , 1 4 − of the parabola y2 = 4x are perpendicular. Statement-2 : The tangents to the parabola at the and of a focal chord are perpendicular. 296. Statement-1 : Through (λ, λ + 1) there cannot be more than one-normal to the parabola y2 = 4x if λ < 2. Statement-2 : The point (λ, λ + 1) lines out side the parabola for all λ ≠ 1. 297. Statement-1 : Slope of tangents drawn from (4, 10) to parabola y2 = 9x are 1/4, 9/4 Statement-2 : Every parabola is symmetric about its axis. 298. Statement-1 : If a parabola is defined by an equation of the form y = ax2 + bx + c where a, b, c ∈R and a > 0, then the parabola must possess a minimum. Statement-2 : A function defined by an equation of the form y = ax2 + bx + c where a, b, c∈R and a ≠ 0, may not have an extremum. 299. Statement-1 : The point (sin α, cos α) does not lie outside the parabola 2y2 + x − 2 = 0 when 5 3 , , 2 6 2 pi pi pi α ∈ ∪ pi Statement-2 : The point (x1, y1) lies outside the parabola y2 = 4ax if y12 − 4ax1 > 0. 300. Statement-1 : The line y = x + 2a touches the parabola y2 = 4a(x + a). Statement-2 : The line y = mx + c touches y2 = 4a(x + a) if c = am + a/m. 301. Statement-1 : If PQ is a focal chord of the parabola y2 = 32x then minimum length of PQ = 32. Statement-2 : Latus rectum of a parabola is the shortest focal chord. 302. Statement-1 : Through (λ, λ + 1), there can’t be more than one normal to the parabola y2 = 4x if λ < 2. Statement–2 : The point (λ, λ + 1) lies outside the parabola for all λ ∈ R ~ {1}. 303. Statement–1 : Perpendicular tangents to parabola y2 = 8x meets on x + 2 = 0 Statement–2 : Perpendicular tangents of parabola meets on tangent at the vertex. 83 of 91 304. Let y2 = 4ax and x2 = 4ay be two parabolas Statement-1: The equation of the common tangent to the parabolas is x + y + a = 0 Statement-2: Both the parabolas are reflected to each other about the line y = x. 305. Let y2 = 4a (x + a) and y2 = 4b (x + b) are two parabolas Statement-1 : Tangents are drawn from the locus of the point are mutually perpendicular State.-2: The locus of the point from which mutually perpendicular tangents can be drawn to the given comb is x + y + b = 0 EELLLLIIPPSSEE 306. Tangents are drawn from the point (-3, 4) to the curve 9x2 + 16y2 = 144. STATEMENT -1: The tangents are mutually perpendicular. STATEMENT-2: The locus of the points from which mutually perpendicular tangents can be drawn to the given curve is x2 + y2 = 25. 307. Statement–1 : Circle x2 + y2 = 9, and the circle (x – 5) ( 2x 3)− + y ( 2y 2)− = 0 touches each other internally. Statement–2 : Circle described on the focal distance as diameter of the ellipse 4x2 + 9y2 = 36 touch the auxiliary circle x2 + y2 = 9 internally 308. Statement–1 : If the tangents from the point (λ, 3) to the ellipse 2 2 x y 1 9 4 + = are at right angles then λ is equal to ± 2. Statement–2 : The locus of the point of the intersection of two perpendicular tangents to the ellipse 2 2 2 2 x y a b + = 1, is x2 + y2 = a2 + b2. 309. Statement–1 : x – y – 5 = 0 is the equation of the tangent to the ellipse 9x2 + 16y2 = 144. Statement–2 : The equation of the tangent to the ellipse 2 2 2 2 x y 1 a b + = is of the form y = mx ± 2 2 2a m b+ . 310. Statement–1 : At the most four normals can be drawn from a given point to a given ellipse. Statement–2 : The standard equation 2 2 2 2 x y 1 a b + = of an ellipse does not change on changing x by – x and y by – y. 311. Statement–1 : The focal distance of the point ( )4 3, 5 on the ellipse 25x2 + 16y2 = 1600 will be 7 and 13. Statement–2 : The radius of the circle passing through the foci of the ellipse 2 2x y 1 16 9 + = and having its centre at (0, 3) is 5. 312. Statement-1 : The least value of the length of the tangents to 2 2 2 2 x y 1 a b + = intercepted between the coordinate axes is a + b. Statement-2 : If x1 and x2 be any two positive numbers then 1 2 1 2 x x x x 2 + ≥ + 313. Statement-1 : In an ellipse the sum of the distances between foci is always less than the sum of focal distances of any point on it. Statement-2 : The eccentricity of any ellipse is less than 1. 314. Statement-1 : Any chord of the conic x2 + y2 + xy = 1, through (0, 0) is bisected at (0, 0) Statement-2 : The centre of a conic is a point through which every chord is bisected. 315. Statement-1 : A tangent of the ellipse x2 + 4y2 = 4 meets the ellipse x2 + 2y2 = 6 at P & Q. The angle between the tangents at P and Q of the ellipse x2 + 2y2 = 6 is pi/2 Statement-2 : If the two tangents from to the ellipse x2/a2 + y2/b2 = 1 are at right angle, then locus of P is the circle x2 + y2 = a2 + b2. 84 of 91 316. Statement-1 : The equation of the tangents drawn at the ends of the major axis of the ellipse 9x2 + 5y2 – 30y = 0 is y = 0, y = 7. Statement-1 : The equation of the tangent drawn at the ends of major axis of the ellipse x 2/a2 + y2/b2 = 1 always parallel to y-axis 317. Statement-1 : Tangents drawn from the point (3, 4) on to the ellipse 2 2x y 1 16 9 + = will be mutually perpendicular Statement-2 : The points (3, 4) lies on the circle x2 + y2 = 25 which is director circle to the ellipse 2 2x y 1 16 9 + = . 318. Statement-1 : For ellipse 2 2x y 1 5 3 + = , the product of the perpendicular drawn from focii on any tangent is 3. Statement-2 : For ellipse 2x y 1 5 3 2 + = , the foot of the perpendiculars drawn from foci on any tangent lies on the circle x2 + y2 = 5 which is auxiliary circle of the ellipse. 319. Statement-1 : If line x + y = 3 is a tangent to an ellipse with foci (4, 3) & (6, y) at the point (1, 2), then y = 17. Statement-2 : Tangent and normal to the ellipse at any point bisects the angle subtended by foci at that point. 320. Statement-1 : Tangents are drawn to the ellipse 2 2x y 1 4 2 + = at the points, where it is intersected by the line 2x + 3y = 1. Point of intersection of these tangents is (8, 6). Statement-2 : Equation of chord of contact to the ellipse 2 2 2 2 x y 1 a b + = from an external point is given by 1 1 2 2 xx yy 1 0 a b + − = 321. Statement-1 : In an ellipse the sum of the distances between foci is always less than the sum of focal distances of any point on it. Statement-2 : The eccentricity of any ellipse is less than 1. 322. Statement-1 : The equation x2 + 2y2 + λxy + 2x + 3y + 1 = 0 can never represent a hyperbola Statement-2 : The general equation of second degree represent a hyperbola it h2 > ab. 323. Statement-1 : The equation of the director circle to the ellipse 4x2 + 9x2 = 36 is x2 + y2 = 13. Statement-2 : The locus of the point of intersection of perpendicular tangents to an ellipse is called the director circle. 324. Statement-1 : The equation of tangent to the ellipse 4x2 + 9y2 = 36 at the point (3, −2) is x y 1 3 2 − = . Statement-2 : Tangent at (x1, y1) to the ellipse 2 2 2 2 x y 1 a b + = is 1 12 2 xx yy 1 a b − = 325. Statement-1 : The maximum area of ∆PS1 S2 where S1, S2 are foci of the ellipse 2 2 2 2 x y 1 a b + = and P is any variable point on it, is abe, where e is eccentricity of the ellipse. Statement-2 : The coordinates of pare (a sec θ, b tan θ). 326. Statement-1 : In an ellipse the sum of the distances between foci is always less than the sum of focal distance of any point on it. Statement-2 : The eccentricity of ellipse is less than 1. HHYYPPEERRBBOOLLAA 327. Let Y = ± 2 2 x 9 3 − x∈ [3, ∞) and Y1 = ± 2 2 x 9 3 − be x∈ (-∞, -3] two curves. Statement 1: The number of tangents that can be drawn from 105, 3 − to the curve Y1 = ± 2 2 x 9 3 − is zero 85 of 91 Statement 2: The point 105, 3 − lies on the curve Y = ± 2 2 x 9 3 − . 328. Statement–1 : If (3, 4) is a point of a hyperbola having focus (3, 0) and (λ, 0) and length of the transverse axis being 1 unit then λ can take the value 0 or 3. Statement–2 : S P SP 2a′ − = , where S and S′ are the two focus 2a = length of the transverse axis and P be any point on the hyperbola. 329. Statement–1 : The eccentricity of the hyperbola 9x2 – 16y2 – 72x + 96y – 144 = 0 is 5 4 . Statement–2 : The eccentricity of the hyperbola 2 2 2 2 x y 1 a b − = is equal to 2 2 b1 a + . 330. Let a, b, α ∈ R – {0}, where a, b are constants and α is a parameter. Statement–1 : All the members of the family of hyperbolas 2 2 2 2 2 x y 1 a b + = α have the same pair of asymptotes. Statement–2 : Change in α, does not change the slopes of the asymptotes of a member of the family 2 2 2 2 2 x y 1 a b + = α . 331. Statement–1 : The slope of the common tangent between the hyperbola 2 2 2 2 x y 1 a b − = and 2 2 2 2 x y 1 b a − + = may be 1 or – 1. Statement–2 : The locus of the point of inteeersection of lines x y m a b − = and x y 1 a b m + = is a hyperbola (where m is variable and ab ≠ 0). 332. Statement–1 : The equation x2 + 2y2 + λxy + 2x + 3y + 1 = 0 can never represent a hyperbola. Statement–2 : The general equation of second degree represents a hyperbola if h2 > ab. 333. Statement–1 If a point (x1, y1) lies in the region II of 2 2 2 2 x y 1, a b − = shown in the figure, then 2 2 1 1 2 2 x y 0 a b − < Y I II III III X I II by x a = by x a = − Statement–2 If (P(x1, y1) lies outside the a hyperbola 2 2 2 2 x y 1 a b − = , then 2 2 1 1 2 2 x y 1 a b − < 334. Statement–1 Equation of tangents to the hyperbola 2x2 − 3y2 = 6 which is parallel to the line y = 3x + 4 is y = 3x − 5 and y = 3x + 5. Statement–2 y = mx + c is a tangent to x2/a2 − y2/b2 = 1 if c2 = a2m2 + b2. 335. Statement–1 : There can be infinite points from where we can draw two mutually perpendicular tangents on to the hyperbola 2 2x y 1 9 16 − = 86 of 91 Statement–2 : The director circle in case of hyperbola 2 2x y 1 9 16 − = will not exist because a2 < b2 and director circle is x2 + y2 = a2 – b2. 336. Statement–1 : The average point of all the four intersection points of the rectangular hyperbola xy = 1 and circle x2 + y2 = 4 is origin (0, 0). Statement–2 : If a rectangular hyperbola and a circle intersect at four points, the average point of all the points of intersection is the mid point of line-joining the two centres. 337. Statement–1 : No tangent can be drawn to the hyperbola 2 2x y 1, 2 1 − = which have slopes greater than 1 2 Statement–2 : Line y = mx + c is a tangent to hyperbola 2 2 2 2 x y 1 a b − = . If c2 = a2m2 – b2 338. Statement–1 : Eccentricity of hyperbola xy – 3x – 3y = 0 is 4/3 Statement–2 : Rectangular hyperbola has perpendicular asymptotes and eccentricity = 2 339. Statement–1 : The equation x2 + 2y2 + λxy + 2x + 3y + 1 = 0 can never represent a hyperbola Statement–2 : The general equation of second degree represent a hyperbola it h2 > ab. 340. Statement–1 : The combined equation of both the axes of the hyperbola xy = c2 is x2 – y2 = 0. Statement–2 : Combined equation of axes of hyperbola is the combined equation of angle bisectors of the asymptotes of the hyperbola. 341. Statement–1 : The point (7, −3) lies inside the hyperbola 9x2 − 4y2 = 36 where as the point (2, 7) lies outside this. Statement–2 : The point (x1, y1) lies outside, on or inside the hyperbola 2 2 2 2 x y 1 a b − = according as 2 2 1 1 2 2 x y 1 a b − − < or = or > 0 342. Statement–1 : The equation of the chord of contact of tangents drawn from the point (2, −1) to the hyperbola 16x2 − 9y2 = 144 is 32x + 9y = 144. Statement–2 : Pair of tangents drawn from (x1, y1) to 2 2 2 2 x y 1 a b − = is SS1 = T2 2 2 2 2 x yS 1 a b = − = 2 2 1 1 1 2 2 x yS 1 a b = − − 343. Statement–1 : If PQ and RS are two perpendicular chords of xy = xe, and C be the centre of hyperbola xy = c2. Then product of slopes of CP, CQ, CR and CS is equal to 1. Statement–2 : Equation of largest circle with centre (1, 0) and lying inside the ellipse x2 + 4y2 16 is 3x2 + 3y2 − 6x − 8 = 0. Answer 286. C 287. B 288. A 289. C 290. B 291. B 292. B 293. C 294. A 295. A 296. B 297. A 298. C 299. B 300. A 301. A 302. B 303. C 304. B 305. A 306. A 307. A 308. A 309. A 310. B 311. C 312. B 313. A 314. A 315. A 316. C 317. A 318. B 319. A 320. D 321. A 322. A 323. A 324. C 325. C 326. A 327. A 328. D 329. A 330. A 331. B 332. D 333. D 334. C 335. D 336. A 337. A 338. D 339. A 340. A 341. A 342. B 343. B Solution 286. Option (C) is correct. y = mx + a m 10 = 4m – 1. 9 / 4 m ⇒ 16m2 – 40m + 9 = 0 ⇒ m1 = 2 1 9 , m 4 4 = Every m1 = 2 1 9 ,m 4 4 = Every parabola is symmetric about its axis. 287. Option (B) is correct Any normal to y2 = 4x is 87 of 91 Y + tx = 2t + t3 If this passes through (λ, λ + 1), we get λ + 1 + λ = 2t + t3 ⇒ t3 + t(2 - λ) - λ - 1 = 0 = f(t) (say) If λ < 2, then f′(t) = 3t2 + (2 - λ) > 0 ⇒ f(t) = 0 will have only one real root. So A is true. Statement 2 is also true b′ coz (λ + 1)2 > 4λ is true ∀ λ ≠ 1. The statement is true but does not follow true statement-2. 288. For the parabola y2 = 12x, equation of a normal with slope -1 is y = -x -2. 3(-1) -3 (-1) 3 ⇒ x + y = 9, ⇒ k = 9 Ans. (A). 289. SP = a + at12 = a(1 + t12) SQ = a + a/t12 = 2 1 2 1 a(1 t ) t + = 1 1 SP SQ+ = 2 1 2 1 (1 t ) 1 a(1 t ) a + = + 1 1 1 , , SP 2a SQ are in A.P. ⇒ 2a is H.M. between SP & SQ Hence 1 1 1 b k a + = ⇒ 1 1 1 k a b = − ⇒ k = ab/b-a = b a ab − Ans. (C) 290. y2 = 4ax equation of tangent of slope ‘m’ y = mx + a m If it touches x2 = 4ay then x2 = 4a (mx + a/m) x2 – 4amx - 24a 0 m = will have equal roots D = 0 16a2 m2 + 216a 0 m = m3 = -1 ⇒ m = -1 So y = -x – a ⇒ x + y + a = 0 (a, -2a) & (-2a, a) lies on it ‘B’ is correct. 291. (x – a) (x – at2) + y (y – 2at) = 0 Solve with x = 0 a2t2 + y (y – 2at) = 0 y2 – 2aty + a2t2 = 0 If it touches y-axis then above quadratic must have equal roots. SO, D = 0 4a2t2 – 4a2t2 = 0 which is correct. ‘B’ is correct. (at , 2at)2 S(a, 0) 296. (B) Any normal to the parabola y2 = 4x is y + tx = 2t + t3 It this passes through (λ, λ + 1) ⇒ t3 + t(2 - λ) - λ - 1 = 0 = f(t) say) λ < 2 than f′(t) = 3t2 + (2 - λ) > 0 ⇒ f(t) = 0 will have only one real root ⇒ A is true The statement-2 is also true since (λ+ 1)2 > 4λ is true for all λ ≠ 1. The statement-2 is true but does not follow true statement-2. 88 of 91 297. y = mx + a m 10 = 4m + 9 / 4 m ⇒ 16m2 − 40m + 9 = 0 m1 = 1/4, m2 = 9/4 Every parabola is symmetric about its axis. 298. (C) Statement-1 is true but Statement-2 is false. 299. (B) If the point (sin α, cos α) lies inside or on the parabola 2y2 + x − 2 = 0 then 2cos2α + sin α − 2 ≤ 0 ⇒ sin α(2 sin α − 1) ≥ 0 ⇒ sin α ≤ 0, or 1sin 2 α ≥ . 300. (A) y = (x + a) + a is of the form y = m(x + a) + a/m where m = 1. Hence the line touches the parabola. 302. Any normal to the parabola y2 = 4x is y + xt = 2t + t3 If this passes through (λ, λ + 1). We get λ + 1 + λ t = 2t + t3. ⇒ t3 + t (2 - λ) – (λ + 1) = 0 = f(t) (let) if λ < 2, then, f ′ (t) = 3t2 + (2 - λ) > 0 ⇒ f(t) = 0 will have only one real root. ⇒ statement–I is true. Statement–II is also true since (λ + 1)2 > 4λ is true for all λ∈R ~ {1}. Statement – I is true but does ot follow true statement – II. Hence (b) is the correct answer. 304. (B) Because the common tangent has to be perpendicular to y = x. Its slope is -1. 307. Ellipse is 2 2 x y 1 9 4 + = focus ≡ ( 5,0) , e = 5 3 , Any point an ellipse ≡ ( 3 2, 2 2 equation of circle as the diameter, joining the points ( )3/ 2, 2 / 2 and focus ( 5,0) is ( x 5− ) ( 2 x 3) y ( 2.y 2) 0− + − = (A) is the correct option. 308. (a) (λ, 3) should satisfy the equation x2 + y2 = 13 ∴ λ = ± 2. 309. (A) Here a = 4, b = 3 and m = 1 ∴ equation of the tangent is y = x ± 16 9+ y = x ± 5. 310. Statement – I is true as it is a known fact and statement – II is obviously true. However statement – II is not a true reasoning for statement – I, as coordinate system has nothing to do with statement – I. 311. Given ellipse is 2 2x y 1 64 100 + = ⇒ a2 = 64; b2 = 100 ⇒ e = ( )3 a b 5 89 of 91 Hence (c) is the correct answer. 313. Option (A) is correct Sum of the distance between foci = 2ae Sum of the focal distances = 2a e ae < a e b′coz e < 1. Both are true and it is correct reason. 314. Option (A) is true. Let y = mx be any chord through (0, 0). This will meet conic at points whose x-coordinates are given by x2 + m2x2 + mx2= 1 ⇒ (1 + m + m2) x2 – 1 = 0 ⇒ x1 + x2 = 0 ⇒ 1 2 x x 0 2 + = Also y1 = mx1, y2 = mx2 ⇒ y1 + y2 = m (x1 + x2) = 0 ⇒ 1 2 y y 0 2 + = ⇒ mid-point of chord is (0, 0) ∀m. 315. Equation of PQ (i.e., chord of contact) to the ellipse x2 + 2y2 = 6 hx ky 1 6 3 + = ... (1) Any tangent to the ellipse x2 + 4y2 = 4 is i.e., x/2 cosθ + ysinθ = 1 ... (2) ⇒ (1) & (2) represent the same line h = 3cosθ, k = 3sinθ Locus of R (h, k) is x2 + y2 = 9 Ans. (A) 316. x2/5 + (y-3)2/9 =1 Ends of the major axis are (0, 6) and (0, 0) Equation of tangent at (0, 6) and (0, 0) is y = 6, and y = 0 Anc. (C) 317. 2 2x y 1 16 9 + = will have director circle x2 + y2 = 16 + 9 ⇒ x2 + y2 = 25 and we know that the locus of the point of intersection of two mutually perpendicular tangents drawn to any standard ellipse is its director circle. ‘a’ is correct. 318. By formula p1p2 = b2 = 3. also foot of perpendicular lies on auxiliary circle of the ellipse. ‘B’ is correct. 321. Sum of distances between foci = 2ae sum of the focal distances = 2a/e ae < a/e since e < 1. (A) 322. The statement-1 is false. Since this will represent hyperbola if h2 > ab ⇒ 2 2 4 λ > ⇒ |λ| > 2 2 Thus reason R being a standard result is true. (A) 323. (a) Both Statement-1 and Statement-2 are True and Statement-2 is the correct explanation of Statement-1. 324. (C) Required tangent is 3x 2y x y1 or 1 9 4 3 2 − = − = 90 of 91 325. (C) area of ∆PS1 S2 = abe sin θ clearly its maximum value is abe. S (–ae, 0)1 S (ae, 0)2 P(a cos , b sin )θ θ 327. Tangents cannot be drawn from one branch of hyperbola to the other branch. Ans. (A) 328. (d) ( )23 16 4 1λ − + − = ⇒ λ = 0 or 6. 329. (A) Hyperbola is ( ) ( ) 2 2 x 4 y 3 1 16 9 − − − = ∴ e = 9 51 16 4 + = . 330. Both statements are true and statement – II is the correct reasoning for statement – I, as for any member, semi transverse and semi – conjugate axes are a α and b α respectively and hence asymptoters are always y = b x a ± . Hence (a) is the correct answer 331. If y = mx + c be the common tangent, then c2 =a2 m2 – b2 . . . (i) and c2 = - b2 m2 + a2 . . . (ii) on eliminating c2, we get m2 = 1 ⇒ m = ± 1. Now for statement – II, On eliminating m, we get 2 2 2 2 x y 1 a b − = , Which is a hyperbola. Hence (b) is the correct answer. 332. Option (D) is correct. The statement-1 is false b′coz this will represent hyperbola if h2 > ab ⇒ 2 2 4 λ > ⇒ |λ| > 2 2 The statmenet-2, being a standard result, is true. 333. The statement-1 is false b′coz points in region II lie below the line y = b/a x ⇒ 2 2 1 1 2 2 x y 0 a b − > The region-2 is true (standard result). Indeed for points in region II 0 < 2 2 1 1 2 2 x y 1 a b − < . 334. x2/a2 − y2/b2 = 1 if c2 = a2m2 − b2 ⇒ c2 = 3.32 − 2 = 25 c = ± 5 91 of 91 real tangents are y = 3x + 5 Ans (C) 335. The locus of point of intersection of two mutually perpendicular tangents drawn on to hyperbola 2 2 2 x y 1 a b 2 − = is its director circle whose equation is x2 + y2 = a2 – b2 . For 2 2 x y 1 9 16 − = , x 2 + y2 = 9 – 16 So director circle does not exist. So ‘d’ is correct. 336. 1 2 3 4 x x x x 0 4 + + + = 1 2 3 4y y y y 0 4 + + + = So (0, 0) is average point which is also the mid point of line joining the centres of circle & rectangular hyperbola ‘a’ is correct. 339. The statement-1 is false. Since this will represent hyperbola if h2 > ab ⇒ 2 2 4 λ > ⇒ |λ| > 2 2 Thus reason R being a standard result is true. (A) 340. (a) Both Statement-1 and Statement-2 are True and Statement-2 is the correct explanation of Statement-2. 341. (A) 2 27 ( 3) 1 0 4 9 − − − > and 2 22 7 1 0 4 9 − − < 342. (B) Required chord of contact is 32x + 9y = 144 obtained from 1 12 2 xx yy 1 a b − = . for 34 Yrs. Que. of IIT-JEE & 10 Yrs. Que. of AIEEE we have distributed 92 of 91 chp19(part1).pdf chp19(part2).pdf chp19(part3).pdf chp19(part4).pdf chp19(part5).pdf chp19(part6).pdf chp19(part7).pdf