the fourier series expansion of a real periodic signal with fundamental frequency f0 is given by
26. The Laplace transform of i(t) is given by i(s) = 2/s(1 + s). as t the value of i(t) tends to
(a) 0
(b) 1
(c) 2
(d) 0
- The Fourier series expansion of a real periodic signal with fundamental frequency fo is given by gp(t) = c0ej2nft . it is given that c3 = 3 + j5.
(a) 5 + j3
(b) -3 – j5
(c) -5 + j3
(d) 3 – j5
- Let x(t) be the input to a linear, time-invariant system. the required output is 4x(t – 2). the transfer function of the system should be
(a) 4ej4t
(b) 2e-j8t
(c) 4e-j4t
(d) 2ej8t
- A sequence x(n) with the z-transform x(z) = z4 + z2 – 2z + 2 – 3z-4 is applied as an input to a linear, time-invariant sysyem with the impulse response h(n) = 2(n – 3), where (n) = {1, n = 0 0, otherwise
the output at n = 4 is
(a) -6
(b) zero
(c) 2
(d) -4
- Convolution of x(t + 5) with impulse function (t – 7) is equal to
(a) x(t – 12)
(b) x(t + 12)
(c) x(t – 2)
(d) x(t + 2)
- Which of the following cannot be the fourier series expansion of a periodic signal?
(a) x(t) = 2 cos t + 3 cos 3t
(b) x(t) = 2 cos t + 7 cos t
(c) x(t) = cos t + 0.5
(d) x(t) = 2 cos 1.5t + sin 3.5 t
- The fourier transform f(e-t u(t) is equal to 1/1 + j2f. therefore, f{1/1 – j2t} is
(a) ef u(f)
(b) e-f u(f)
(c) ef u(-f)
(d) e-f u(-f)
- A linear phase channel with phase delay tp and group delay tg must have
(a) tp = tg = constant
(b) tp f and tg f
(c) tp = constanf and tg f
(d) tp f and tg = constant
- Conider a sampled signal :
y(t) = 5 x 10-6 x(t) (t – nts),
where, x(t) = 10 cos (8 x 103) t
and ts = 100 us. when y(t) is passed through an ideal low-pass filter with a cut-off frequency of 5 khz, the output of the filter is
(a) 5 x 10-6 cos (8 x 103) t
(b) 5 x 10-5 cos (8 x 103) t
(c) 5 x 10-1 cos (8 x 103) t
(d) 10 cos (8 x 103) t
- The transfer function of a system is given by h(s) = 1/s2 (s – 2) . the impulse response of the system is (* denotes convolution, and u(t) is unit step function)
(a) (t2 * e-2t) u(t)
(b) (t * e2t) u(t)
(c) te-2t) u(t)
(d) (te-2t) u(t)
- The region of convergence of the z-transform of a unit step function is
(a) |z|>1
(b) |z|<1
(c) (real part of z)> 0
(d) (real part of z) < 0
- Let (t) denotes the delta function. the value of the integral (t) cos (3t/2) dt is
(a) 1
(b) -1
(c) 0
(d) 2
- A band limited signal is sampled at the nyquist rate. the signal can be recovered by passing the samples through
(a) an R-C filter
(b) an envelope detector
(c) a PLL
(d) an ideal low-pass filter with appropriate bandwidth
- A linear time-invariant system has an impulse response e2t, t > 0. if the initial conditions are zero and the input is e3t, the output for t > 0 is
(a) e3t – e2t
(b) e5t
(c) e3t + e3t
(d) none of these
- Given that l[f(t)] = s + 2/s2 + 1, l[g(t)] = s2 + 1/(s + 3) (s + 2). h(t) = f(r) g(t) d. l[h(t)] is
(a) s2 + 1/s + 3
(b) 1/s + 3
(c) s2 + 1/(s + 3) (s + 2) + s + 2/s2 + 1
(d) none of these
- The fourier transform of the signal x(t) = e-3t2 is of the following form, where A and B are constants
(a) Ae-5(t)
(b) Ae-bf2
(c) A + B |F|2
(d) Ae-bf
- A system with an input x(t) and output y(t) is described by the relation y(t) = tx(t). this system is
(a) linear and time-invariant
(b) linear and time-variant
(c) non-linear and time-invariant
(d) non-linear and time-variant
- The n-point discrete fourier transform of a signal x[n] is xdft [k]. if DFT of another discrete sequence y[n] is given as ydft [k] = x*dft [k], then which of the following is true?
(a) y[n] = x* [n]
(b) y[n] = nx* [n]
(c) y[n] = 1/n x* [n]
(d) y[n] = – x* [n]
- Discrete fourier transform of a real sequence {x[n]} is given as
xdft[k] = {0, a, 2 + j, – 1,b,j}
then, a and b are
(a) 2 – j, j
(b) j, -j
(c) -j, 2 – j
(d) j, 2 + j
- The 4-point discrete fourier transform of a discrete time sequence (1,2,1,2) is
(a) {0, -2, 0, 6}
(b) {6, -4j, 6 – 4j}
(c) {-4j , 6 – 4j, 6}
(d) {6, 0, -2, 0}
- Consider a band-pass signal xc (t) is shown below. the minimum sampling rate required for this signal to prevent loss of information is
(a) 4 kHz
(b) 12 kHz
(c) 20 kHz
(d) 2 kHz
- Two signals x1(t) are band-limited to 2 kHz and 3kHz respectively, then nyquist rate for the signal x1(t)* x2(t) is
(a) 5 kHz
(b) 6 kHz
(c) 4 kHz
(d) 10 kHz
- Which one is most appropriate dynamic system out of the following?
(a) y(n) = y(n – 1) + y(n + 1)
(b) y(n) = y(n – 1)
(c) y(n) = x(n)
(d) y(n) + y(n – 1) + y(n + 3) = 0
- Which one is causal system?
(a) y(n) = 3x(n) – 2x(n – 1)
(b) y(n) = 3x(n) + 2x(n + 1)
(c) y(n) = 3x(n + 1) + 2x(n – 1)
(d) y(n) = 3x(n + 1) + 2x(n – 1) + x (n)
- For the signal given below
y(t) = 2 sin (2/3 t) + 4sin (1/4 t 4) + 6 sin (1/3 t 5) + 8 sin (1/2 t 7)
the common period of y(t) is given by
(a) 12
(b) 24
(c) 8
(d) 16
- (c)
from final value theorem,
lim I(t) = lim sI (s)
= lim s x 2/s (1 + s)
= 2
- (d)
the coefficients cn and c-n in the fourier series are complex conjugate.
C-N = CN*
|C-N |= |CN|
<C-N = – <CN
C3 = 3 + J5
C-3 = C3* = 3 – J5
- (c)
transfer function h(s) = FT of output/FT if input
= 4e-j20 x(s)/x(s) = 4e-j2o
h(s) = 4e-j4f
- (b)
y(z) = h(z) x(z)
given, x(z) = z4 + z2 – 2z + 2 – 3z-4
h(n) = [n – 3]
h(z) = z-3
y(z) = z-3 [z4 + z2 – 2z + 2 – 3z-4]
= z + z-1 + 2z-2 + 2z-3 – 3z-7
taking inverse z-transform,
by inspection,
y[n] = [n + 1] + [n – 1] – 2[n – 2] + 2 [n – 3] – 3 [n – 7]
putting n = 4
y[4] = 0
- (c)
from shifting property of impulse function,
(t)* (t – to) = (t – t0)
hence, x(t + 5)* (t – 7) = x(t + 5 – 7)
= x(t – 2)
- (b)
signal x(t) = 2 cos t + 7 cos t
period of 2 cos t = t1 = 2/0
= 2 = 2
period of 7 cos t = t2 = 2/0
= 2/1 = 2
for signal x(t) to be periodic t1/t2 not be rational.
t1/t2 = 2/2 = 1 = irrational
periodic waveform is sufficient condition for existence of fourier series. hence, x(t) = 2 cos t + 7 cos t is not a periodic signal hence, fourier series expansion is not possible.
- (c)
from duality property of fourier transform.
x(t) – x(f)
x(t) – x(-f)
f{1/1 + j2t} = ef u(-f)
- (a)
let VI = x(t) cos t is applied in linear phase channel.
where, Tg = group delay
Tp = phase delay
in liear phase channel, transmission is distrtionless.
hence, TP = TG = constant
- (c)
given that sampling interval ts = 100 us
sampling frequency fs = 1/ts = 10 kHz
bandwidth of LPF = fc = 5 kHz
fs = 2 B
hence, sampled output not overlap.
filter output = y(t)/ts
= 5 x 10-6 x x(t)/100 x 10-6
given, x(t) = 10 cos (8 x 103) t
output = 5 x 10-6 x 10 cos (8 x 103) t/100 x 10-6
= 5 x 10-1 cos (8 x 103) t
- (b)
transfer function h(s) = 1/s2(s – 2)
lmpulse response h(t) = l-1 [h(s)]
= l-1 [1/s2(s – 2)]
we know that
l-1 [f1 (t). f2(t)] = l-1 [f1(t)* l-1[f2(t)]
hence, h(t) = l-1 [1/s2]* l-1|1/s – 2]
= t u(t)* e2t u(t)
= (t* e2t) u(t)
- (a)
x[n] = u[n]
x[z] = x[k] z-k
u[k] z-k = z-k
x[z] = 1/1 – z-1
for x[z] to converge,
|z-1|< 1
|z|> 1
- (a)
from sampling property of unit impulse function,
(t) (t) dt = (0)
(t) cos (3t/2) dt = cos (0) = 1
- (d)
As band limited signal is sampled at nyquist rate. hence, replicated spectra do not overlap and the original sepctrum can be generated by passing 0s (t) through ideal low-pass filter that has cut-off frequency.
(bandwidth fc = fs/2 ; where fs is sampling frequency.
- (a)
y(s) = x(s) h(s)
given, x(t) = e3t, h(t) = e2t
x(s) = 1/s – 3, h(s) = 1/s – 2
y(s) = x(s) h(s) = 1/(s – 3) x 1/(s – 2)
= 1/s – 3 – 1/s – 2
hence, y(t) = e3t –– e2t
- (b)
given, l[f(t)] = s + 2/s2 + 1 = f(s)
l[g(t)] = s2 + 1/(s + 3)(s + 2) = g(s)
h(t) = f g(t-) d
h(t) = f(t)* g(t)
taking laplace transform,
l[h(t) = l[f(t)* g(t)]
= l[f(t)]. l[g(t)]
= f(s). g(s)
= s + 2/s2 + 1 x s2 + 1/(s + 3) (s + 2) = 1/s + 3
- (b)
the signal x(t) = e-3t2 is an example of gaussian distribution. the fourier transform of gaussian distribution is also caussian distribution.
x(f) = A e-bf2
- (b)
let x(t) = a x1 (t) + b x2 (t)
then, a y1 (t) + b y2 (t) = at x1 (t) + bt x2(t)
= t x(t)
then system is linear.
if input is delayed by t0, i.e., x(t – t0)
then output is
y1 (t) = t x (t – to)
but output is delayed by to.
y2(t) = (t – to x (t – to)
y1 (t) = y2(t)
hence, system is not time-invariant, i.e., time varying.
- (b)
x[n] = xdft [k]
a typial DFT term XDFT[K] has the form Aejo
let = 2kn /n, the IDFT gives x[n] with terms of the form
1/n Aejo . ej = 1/n Aej(0+ 0)
if we conjugate XDFT [k], typical term becomes Ae-jo. its IDFT gives terms of the form Ae-joe-jo = Ae-j(0 + 0)
this DFT result corresponds to the signal Nx *[n].
- (c)
the DFT of a real signal shows conjugate symmetry as
XDFT[K] = XDFT [N – K]
here, N = 6
a = XDFT [1] = XDFT [6 – 1] = XDFT [5]
a = – j
B = XDFT [4] = XDFT[6 – 4] = XDFT[2]
B = 2 – J
- (d)
let x[n] = (1,2,1,2} is discrete fourier transform of x[n] is given as
XDFT [K] = X[n] e-j2nk/n
k = 0, 1,……….N – 1 and
n = 4
so, XDFT [K] = x[n] e-j2nk/2
x[n] e-jkn/2
k = 0, XDFT [0] = x[n] eo
x[0] + x[1] + x[2] + x[3]
= 1 + 2 + 1 + 2 = 6
k = 1, XDFT [1] = x[n] e-jn/2
= x1 [0] e0 + x[1] e-j/2 + x[2] e-j + x[3] ej3/2
= 1 – 2j – 1 + 2j = 0
k = 2, XDFT [2] = x[n] e-jn
= x[0] e0 + x[1] e-j + x[2] e-j2 + x[3] e-j3
= 1 – 2 + 1 – 2 = 2
k = 3, XDFT [3] = x[n] e-jn3/2
= x[10] e0 + x [1] e-j3/2 + x[2] e-j3 + x[3] e-j9/2
= 1 – 2j – 1 + 2j = 0
so, XDFT [K] = {6,0, -2, 0}
- (a)
for a band-pass signal, minimum sampling frequency is given as
fs = 2fH/N
where, N = int (fH/B)
Here, fl = 4 kHz, fh = 6 kHz
bandwidth B = FH – FL = 6 – 4 = 2 kHz
N = int (6/2) = 3
fs = 2 x 6/3 = 4 kHz
- (c)
x1 (t) * x2(t) = x1 (f) x2 (f) (product of spectrum)
so, x1(t)* x2(t) extends only to 2 kHz
nyquist rate = 2 x 2 kHz = 4 kHz
- (a)
Because present output y(n) depends upon past output y(n – 1) and future output y(n + 1).
- (a)
for causal system output must depend upon present and past, not on future.
- (b)
The periods of individual components are
01 = 2/3 2/T1 = 2/3 t1 = 3
02 = 1/4 2/t2 = 1/4 t2 = 8
03 = 1/3 2/t3 = 1/3 t2 = 6
04 = 1/2 2/t4 = 1/2 t4 = 4
Common period is LCM of the individual periods
T = LCM (3, 8, 6, 4)
= 24
हिंदी माध्यम नोट्स
Class 6
Hindi social science science maths English
Class 7
Hindi social science science maths English
Class 8
Hindi social science science maths English
Class 9
Hindi social science science Maths English
Class 10
Hindi Social science science Maths English
Class 11
Hindi sociology physics physical education maths english economics geography History
chemistry business studies biology accountancy political science
Class 12
Hindi physics physical education maths english economics
chemistry business studies biology accountancy Political science History sociology
English medium Notes
Class 6
Hindi social science science maths English
Class 7
Hindi social science science maths English
Class 8
Hindi social science science maths English
Class 9
Hindi social science science Maths English
Class 10
Hindi Social science science Maths English
Class 11
Hindi physics physical education maths entrepreneurship english economics
chemistry business studies biology accountancy
Class 12
Hindi physics physical education maths entrepreneurship english economics