Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) PDF Download

Q31: The mean thickness and variance of silicon steel laminations are 0.2 mm and 0.02 respectively. The varnish insulation is applied on both the sides of the laminations. The mean thickness of one side insulation and its variance are 0.1 mm and 0.01 respectively. If the transformer core is made using 100 such varnish coated laminations, the mean thickness and variance of the core respectively are       (SET-3(2014))
(a) 30 mm and 0.22
(b) 30 mm and 2.44
(c) 40 mm and 2.44
(d) 40 mm and 0.24
Ans:
(d)

Q32: Integration of the complex function Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)in the counterclockwise direction, around |z - 1| = 1, is     (SET-3(2014))
(a) −πi
(b) 0
(c) πi
(d) 2πi
Ans:
(c)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Poles of f(z)
z2−1 = 0
[z = +1, 1]
So, −1 → Outside circle +1 → Inside circle
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)as it lies outside from counter.

Q33: Let ▽⋅(fv) = x2y + y2z + z2x, where f and v are scalar and vector fields respectively. If v = yi + zj + xk, then v⋅▽f is       (SET-3 (2014))
(a) x2y + y2z + z2x
(b) 2𝑥𝑦+2𝑦𝑧+2𝑧𝑥2xy + 2yz + 2zx
(c) x + y + z
(d) 0
Ans:
(a)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q34: A particle, starting from origin at t = 0s, is traveling along x-axis with velocity Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
At t = 3s, the difference between the distance covered by the particle and the magnitude of displacement from the origin is_____      (SET-3(2014))
(a) 1
(b) 2
(c) 3
(d) 4
Ans:
(b)

Q35: The minimum value of the function f(x) = x− 3x− 24x + 100 in the interval [-3, 3] is     (SET-2 (2014))
(a) 20
(b) 28
(c) 16
(d) 32
Ans:
(b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Critical points are [-3, -2, 3]
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Hence f(x) has minimum value at x = 3 which is 28.

Q36: To evaluate the double integral Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) we make the substitution Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)The integral will reduce to      (SET-2(2014))
(a) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

(b) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(c) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(d) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Ans: (b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Thus, integral becomes Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
v = y/2
dv = dy/2
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q37: Minimum of the real valued function f(x) = (x − 1)2/3 occurs at x equal to      (SET-2(2014))
(a) −∞
(b) 0
(c) 1
(d) ∞
Ans: 
(c)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)As f(x) is square of Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) hence its minimum value be 0 where at x = 1.

Q38: The line integral of function F = yzi, in the counterclockwise direction, along the circle x+ y2 = 1 at z = 1 is      (SET-1(2014))
(a) -2π
(b) -π
(c) π
(d) 2π
Ans:
  (b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)By strokes theoram,
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)where S is surface area of x2 + y2 = 1
∴ S = π(1)= π

Q39: Let f(x) = xe−x. The maximum value of the function in the interval (0, ∞) is     (SET-1(2014))
(a) e-1
(b) e
(c) 1 - e-1
(d) 1 + e-1
Ans:
(a)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Hence f(x) has maximum value at x = 1
f(1) = 1⋅e−1= e−1

Q40: A function y = 5x+ 10x is defined over an open interval x = (1, 2). Atleast at one point in this interval, dy/dx is exactly       (2013)
(a) 20
(b) 25
(c) 30
(d) 35
Ans:
(b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)∵ x is defined open interval x = (1, 2)
∴ 1 < x < 2
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q41. Given a vector field F = y2xa− yza− x2az, the line integral ∫F⋅dl evaluated along a segment on the x-axis from x = 1 to x = 2 is     (2013)
(a) -2.33
(b) 0
(c) 2.33
(d) 7
Ans: 
(b)
Sol: To find: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) along a segment on the x-axis from x = 1 and x = 2.
i.e. Y = 0, z = 0, dy = 0 and dz = 0
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Putting y = 0, z = 0, dy = 0 and dz = 0, we get Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

Q42: The curl of the gradient of the scalar field defined by V = 2x2y + 3y2z + 4z2x is      (2013)
(a) 4xyax + 6yzax + 8zxaz
(b) 4ax + 6ax + 8az 
(c) (4xy + 4z2)a+ (2x+ 6yz)a+ (3y+ 8zx)az
(d) 0
Ans:
(d)
Sol: Curl of gradient of a scalar field is always zero.
▽ × ▽V = 0

Q43: The maximum value of f(x) = x− 9x+ 24x + 5 in the interval [1, 6] is       (2012)
(a) 21
(b) 25
(c) 41
(d) 46
Ans:
(c)
Sol: We need absolute maximum of
f(x) = x− 9x+ 24x + 5 in the interval of [1, 6]
First find local maximum if any by putting f'(x) = 0.
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)x = 2, 4
Now
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Now tabulate the value of f at end point of interval and at local maximum point, to find absolute maximum in given range, as shown below
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Clearly the absolute maxima is at x=6 and absolute maximum value is 41.

Q44: The two vectors [1, 1, 1] and [1, a, a2] where 𝑎 = Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) are      (2011)
(a) Orthonormal
(b) Orthogonal
(c) Parallel
(d) Collinear
Ans:
(b)
Sol: Given [1, 1, 1] and [1, a, a2]
hence Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
a= ω2
So the vectors we have
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)So u and v are orthogonal.

Q45: The function f(x) = 2x − x+ 3 has      (2011)
(a) a maxima at x = 1 and minimum at x = 5
(b) a maxima at x = 1 and minimum at x =- 5
(c) only maxima at x = 1
(d) only a minimum at x = 5
Ans:
(c)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)So at x = 1 we have a relative maxima.

Q46: Roots of the algebraic equation 𝑥3+𝑥2+𝑥+1=0x+ x+ x + 1 = 0 are      (2011)
(a) (+1, +j, -j)
(b) (+1, -1, +1)
(c) (0, 0, 0)
(d) (-1, +j, -j)
Ans: 
(d)
Sol: −1 is one of the root since
(−1)3+(−1)2+(−1) + 1 = 0
 By polynomial division
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)So root are (-1, +j, -j)

Q47: At t = 0, the function f(t) = (sint/t) has      (2010)
(a) a minimum
(b) a discontinuity
(c) a point of inflection
(d) a maximum
Ans: 
(d)

Q48: Divergence of the three-dimensional radial vector field 𝑟Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) (2010)
(a) 3
(b) 1/r
(c) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

(d) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Ans: (a)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q49: The value of the quantity P, where Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) is equal to      (2010 )
(a) 0
(b) 1
(c) e
(d) 1/e
Ans:
(b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Integrating by parts:
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q50: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)It's line integral over the straight line from (x, y) = (0, 2) to (x, y) = (2, 0) evaluates to    (2009)
(a) -8
(b) 4
(c) 8
(d) 0
Ans:
(d)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q51: A cubic polynomial with real coefficients      (2009)
(a) Can possibly have no extrema and no zero crossings
(b) May have up to three extrema and upto 2 zero crossings
(c) Cannot have more than two extrema and more than three zero crossings
(d) Will always have an equal number of extrema and zero crossings
Ans:
(c)

Q52: f(x, y) is a continuous function defined over (x, y) ∈ [0, 1] × [0, 1]. Given the two constraints, x > yand y > x2, the volume under f(x, y) is      (2009)
(a) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

(b) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(c) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(d) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Ans: (a)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q53: Consider function f(x) = (x2−4)2 where x is a real number. Then the function has      (2008)
(a) only one minimum
(b) only tw0 minima
(c) three minima
(d) three maxima
Ans:
(b)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Therefore, there is only one maxima and only two minima for this function.

Q54: The integral Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)       (2007)
(a) sin t cos t
(b) 0
(c) (1/2)cos t
(d) (1/2) sin t
Ans:
(b)
Sol: By property of infinite integral, Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q55: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)are three Vectors.
The following vector is linearly dependent upon the orthogonal set of vectors having a span that contains p, q, r is      (2006)
(a) [8 9 3]T
(b) [−2 −17 30]T
(c) [4 4 5]T
(d) [1323]𝑇[13 2 −3]T 
Ans:
(d)

Q56: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)are three Vectors.
An orthogonal set of vectors having a span that contains p, q, r is      (2006)
(a) [636]𝑇,[423]𝑇[−6 −3 6]T, [4 −2 3]T
(b) [−4 2 4]T, [5 7 −11]T, [8 2 −3]T
(c) [6 7 −1] T, [−3 12 −2] T , [3 9 −4]T
(d) [4 3 11] T, [1 31 3] T, [5 3 4] T
Ans:
(d)

Q57: A surface S(x, y) = 2x + 5y - 3 is integrated once over a path consisting of the points that satisfy (x+1)2+(y−1)2 = √2 . The integral evaluates to      (2006)
(a) 17√2
(b) 17/√2
(c) √2/17
(d) 0
Ans:
(d)

Q58: The expression Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) for the volume of a cone is equal to      (2006)
(a) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

(b) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(c) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
(d) Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Ans: (d)
Sol: We have consider option (A) and (D) only because which contains variable r.
By integrating (D), we get
(1/3) πr2H, which is volume of cone.

Q59: For the scalar field Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) magnitude of the gradient at the point (1, 3) is      (2005)
(a) √13/9
(b) √9/2
(c) √5
(d) 9/2
Ans:
(c)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)
Q60:  For the function f(x) = x2ex, the maximum occurs when x is equal to     (2005)
(a) 2
(b) 1
(c) 0
(d) -1
Ans: 
(a)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)x = 0 or x = 2 are the stationary points.
Now,
Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)∴ At x = 2 we have a maxima.

Q61:  If Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)then S has the value      (2005)
(a) -(1/3)
(b) 1/4
(c) 1/2
(d) 1
Ans:
(c)
Sol: Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

The document Previous Year Questions- Calculus - 2 | Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Engineering Mathematics for Electrical Engineering.
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FAQs on Previous Year Questions- Calculus - 2 - Engineering Mathematics for Electrical Engineering - Electrical Engineering (EE)

1. What is the fundamental theorem of calculus?
Ans. The fundamental theorem of calculus states that if a function is continuous on a closed interval and differentiable on an open interval, then the definite integral of the function over that interval can be calculated by finding an antiderivative of the function and evaluating it at the endpoints of the interval.
2. How is the concept of limits used in calculus?
Ans. In calculus, limits are used to determine the behavior of functions near a certain point. They help in calculating derivatives, integrals, and finding the values of functions at specific points by approaching those points infinitely closely.
3. What is the chain rule in calculus?
Ans. The chain rule in calculus is a formula used to find the derivative of a composite function. It states that if a function is composed of two other functions, the derivative of the composite function is the product of the derivative of the outer function and the derivative of the inner function.
4. How is the concept of optimization used in calculus?
Ans. In calculus, optimization involves finding the maximum or minimum value of a function within a given domain. This is done by finding critical points of the function (points where the derivative is zero or undefined) and determining whether they correspond to maximum, minimum, or saddle points.
5. What is the significance of integrals in electrical engineering?
Ans. Integrals play a crucial role in electrical engineering, especially in the analysis of electric circuits and signals. They are used to calculate properties such as voltage, current, power, and energy consumption in electrical systems, making them essential for designing and analyzing electrical circuits and devices.
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