RMS Value of Time Varying Waveforms MCQ Quiz in मल्याळम - Objective Question with Answer for RMS Value of Time Varying Waveforms - സൗജന്യ PDF ഡൗൺലോഡ് ചെയ്യുക
Last updated on Mar 17, 2025
Latest RMS Value of Time Varying Waveforms MCQ Objective Questions
Top RMS Value of Time Varying Waveforms MCQ Objective Questions
RMS Value of Time Varying Waveforms Question 1:
For a sinusoidal waveform, the RMS value of current will be _______ times the maximum value of current.
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 1 Detailed Solution
Crest Factor ‘or’ Peak Factor is defined as the ratio of the maximum value to the R.M.S value of an alternating quantity.
C.F. ‘or’ P.F. = \(\frac{{Maximum\;Value}}{{R.M.S\;Value}}\)
For a sinusoidal waveform, the value of the crest factor is 1.41.
∴ RMS Value = \(\frac{{Maximum\;Value}}{{1.41}}=0.707\times Maximum \ value\)
Hence, For a sinusoidal waveform, the RMS value of current will be 0.707 times the maximum value of current.
Form Factor:
The form factor is defined as the ratio of the RMS value to the average value of an alternating quantity.
F.F. (Form factor) = \(\frac{{R.M.S\;Value}}{{Average\;Value}}\)
For a sinusoidal waveform, the value of the form factor is 1.11.
:
|
WAVEFORM |
SHAPE
|
MAX. VALUE |
AVERAGE VALUE |
RMS VALUE |
FORM FACTOR |
CREST FACTOR |
|
SINUSOIDAL WAVE |
|
\({A_m}\) |
\(\frac{{2{A_m}}}{\pi }\) |
\(\frac{{{A_m}}}{{\sqrt 2 }}\) |
\(\frac{{\frac{{{A_m}}}{{\sqrt 2 }}}}{{\frac{{2{A_m}}}{\pi }}} = 1.11\) |
\(\frac{{{A_m}}}{{\frac{{{A_m}}}{{\sqrt 2 }}}} = \sqrt 2 \) |
|
SQUARE WAVE |
|
\({A_m}\) |
\({A_m}\)
|
\({A_m}\)
|
\(\frac{{{A_m}}}{{{A_m}}} = 1\) |
\(\frac{{{A_m}}}{{{A_m}}} = 1\) |
|
TRIANGULAR WAVE |
|
\({A_m}\) |
\(\frac{{{A_m}}}{2}\) |
\(\frac{{{A_m}}}{{\sqrt 3 }}\) |
\(\frac{{\frac{{{A_m}}}{{\sqrt 3 }}}}{{\frac{{{A_m}}}{2}}} = \frac{2}{{\sqrt 3 }}\) |
\(\frac{{{A_m}}}{{\frac{{{A_m}}}{{\sqrt 3 }}}} = \sqrt 3 \) |
|
HALF-WAVE RECTIFIED WAVE
|
|
\({A_m}\) |
\(\frac{{{A_m}}}{\pi }\) |
\(\frac{{{A_m}}}{2}\) |
\(\frac{{\frac{{{A_m}}}{2}}}{{\frac{{{A_m}}}{\pi }}} = \frac{\pi }{2}\) |
\(2\) |
RMS Value of Time Varying Waveforms Question 2:
The rms value of a sinusoidal ac current is numerically equal to its value at an angle of _______ degrees
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 2 Detailed Solution
RMS (Root mean square) value:
- RMS value is based on the heating effect of wave-forms.
- The value at which the heat dissipated in the AC circuit is the same as the heat dissipated in the DC circuit is called the RMS value provided, both the AC and DC circuits have equal value of resistance and are operated at the same time.
-
RMS value 'or' the effective value of an alternating quantity is calculated as:
\({V_{rms}} = \sqrt{\frac{1}{T}\mathop \smallint \limits_0^T {v^2}\left( t \right)dt} \)
T = Time period
RMS value = Vm sin θ = Vm sin 45°
= 0.707 Vm
Note:
- Average or mean value of alternating current is that value of steady current which sends the same amount of charge through the circuit in a certain interval of time as is sent by alternating current through the same circuit in the same interval of time
- The ratio of the maximum value (peak value) to RMS value is known as the peak factor or crest factor.
- \(Peak\;factor = \frac{{maximum\;value}}{{rms\;value}}\)
- The ratio of RMS value to the average value is known as the form factor.
- \(Form\;factor = \frac{{rms\;value}}{{average\;value}}\)
RMS Value of Time Varying Waveforms Question 3:
An alternating voltage has the equation V(t) = 200 sin 377t V. What is the value of r.m.s. voltage and frequency?
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 3 Detailed Solution
Concept:
A general sinusoidal voltage is expressed as:
v(t) = Vm sin (ωt + ϕ) ---(1)
Vm = Maximum amplitude of the wave
ϕ = Phase angle
ω = angular frequency, given by:
\(ω = 2πf = \frac{2π}{T}\)
T = Time period of the wave
The rms value of any general expression is calculated as:
\({V_{rms}} = \sqrt{\frac{1}{T}\mathop \smallint \limits_0^T {v^2}\left( t \right)dt} \;\;\)
For the general sinusoidal wave of equation (1), the RMS value is:
\(V_{rms}=\frac{V_m}{√2}\)
Calculation:
V(t) = 200 sin 377t V
Comparing this with the general expression of Equation (1), we get:
Vm = 200
ω = 377
2πf = 377
\(f=\frac{377}{2\pi }\)
= 60 Hz
The time period will be:
\(T=\frac{1}{f}=\frac{1}{60}\)
T = 0.0167 s
The RMS value will be:
\(V_{rms}=\frac{V_m}{√2}=\frac{200}{√2}\)
The correct answer is RMS voltage = 200/√2 V and frequency = 60 Hz
RMS Value of Time Varying Waveforms Question 4:
What is the peak to peak voltage of 500 V AC RMS voltage?
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 4 Detailed Solution
Concept:
For a sinusoidal alternating waveform
- Peak to peak value of voltage (Vp-p) = 2 (Peak value)
- The peak value of voltage (Vp) = √2 Vrms
- RMS value of voltage \(\left( {{V_{rms}}} \right) = \frac{{{V_p}}}{{\surd 2}}\)
- The average value of voltage \(\left( {{V_{avg}}} \right) = \frac{{2{V_p}}}{\pi }\)
Calculation:
Vrms = 500 V
Vp = √2 × 500 V
Vp-p = 2 × √2 × 500
∴ Vp-p = 1414 V
RMS Value of Time Varying Waveforms Question 5:
An ac current is given as:
i = 10 + 10 sin 314t
The average and rms values of the current, respectively, are.
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 5 Detailed Solution
Concept:
To find the average and RMS (root mean square) values of the given AC current, we'll use the following formulas,
\(\begin{align*} I_{avg} &= \frac{1}{T} \int_0^T i(t) dt \\ \end{align*} \)
\(\begin{align*} I_{rms} &= \sqrt{\frac{1}{T} \int_0^T [i(t)]^2 dt} \end{align*} \)
The integral of \(sin(wt)\) over one complete cycle is zero, resulting in \(I_{avg}=0\) for a DC signal, the average value is equal to the amplitude of the signal.
Calculation:
\(i = 10 + 10 sin 314t\)
\(\therefore\ I_{avg} =10+0=10A\)
For a sinusoidal signal, : \(RMS=\frac{A}{\sqrt2}=\frac{10}{\sqrt2}=7.07\)
\(\therefore\ I_{rms} =\sqrt{10^2+{7.07}^2}=12.24 ~A\).
RMS Value of Time Varying Waveforms Question 6:
The AC current flowing through a 10 Ω resistance in a closed power circuit is denoted by i (t) = 3 + 4 sin (ωt) + 4 sin (2 ωt) A. Find the rms value of the current.
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 6 Detailed Solution
Concept:
RMS value of current for different frequency functions can be determined as
\({I_{rms}} = \sqrt {I_{rms1}^2 + I_{rms2}^2 + I_{rms3}^2 + \; \ldots \ldots \ldots .} \)
Calculation:
Given-
i (t) = 3 + 4 sin (ωt) + 4 sin (2 ωt) A
\({I_{rms1}} = {3}{{}}~A\)
\({i_{rms2}} = \frac{4}{{\surd 2}} A\)
\({i_{rms2}} = \frac{4}{{\surd 2}}A\)
\({I_{rms}} = \sqrt {{{\left( {3} \right)}^2} + {{\left( {\frac{4}{{\sqrt 2 }}} \right)}^2}+{{\left( {\frac{4}{{\sqrt 2 }}} \right)}^2}} \)
\({I_{rms}} = \sqrt {{{25}}} = {5}~A\)
RMS Value of Time Varying Waveforms Question 7:
The RMS value of the voltage u(t) = 3 + 4 cos (3t) is
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 7 Detailed Solution
RMS (Root mean square) value:
- RMS value is based on the heating effect of wave-forms.
- The value at which the heat dissipated in AC circuit is the same as the heat dissipated in DC circuit is called RMS value provided, both the AC and DC circuits have equal value of resistance and are operated at the same time.
-
RMS value 'or' the effective value of an alternating quantity is calculated as:
V = a0 + a1 sin (ω1t + θ1) + a2 sin (ω2t + θ2) + a3 sin (ω3t + θ3) +...........
Here a0 = DC value = average value of current
RMS value Vrms = \( \sqrt {a_0^2 + \frac{1}{2}\left( {a_1^2 + a_2^2 + a_3^2 + \ldots } \right)} \)
Calculation:
For the given
u(t) = 3 + 4 cos (3t)
urms = \( \sqrt {a_0^2 + \frac{1}{2}\left( {a_1^2 + a_2^2 + a_3^2 + \ldots } \right)} \)
Rms value of given voltage is,
\( = \sqrt {9 + {{\left( {\frac{4}{{\sqrt 2 }}} \right)}^2}} = \sqrt {9 + 8} = \sqrt {17} \;V\)
RMS Value of Time Varying Waveforms Question 8:
What will be the average value of given waveform:
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 8 Detailed Solution
Average Value: The average value of any waveform is the ratio of the area under the curve to the time or length of the base (X-axis).
\(A_v=\frac{Area}{t}\)
Method 1: Calculating by using Conventional Method:
Here, total area under one cycle = Area 1 + Area 2
Total Time = 0.6 sec
Area 1 = (15 × 0.2) = 3 Vsec
Area 2 = (-3 × 0.4) = -1.2 Vsec
Total Area = (3 - 1.2) = 1.8 Vsec
Hence, Average value = \(\frac{Area}{t}=\frac{1.8}{0.6}=3\ V\)
Method 2: Calculating by using Method of integration:
Area = \(\int_0^{0.2}15dt+\int_{0.2}^{0.6}-3dt\) = 1.8 Vsed
Hence, Average value = \(\frac{Area}{t}=\frac{1.8}{0.6}=3\ V\)
RMS Value of Time Varying Waveforms Question 9:
The rms value of the resultant current in a wire which carries a dc current of 20 A and a sinusoidal alternating current of peak value 20 A is
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 9 Detailed Solution
Given
DC current / Average current = 20 A.
Peak value of sinusoidal current = 20 A
Calcualation:
RMS value of resultant current = \(\sqrt{I^{2}_{0}\;+I_{1rms}^{2}\;+I_{2rms}^{2}\;+I_{3rms}^{2}.....}\)
I1rms = \(\frac{20}{\sqrt{2}}\) A.
\({{\rm{I}}_{{\rm{rms \;resultant}}}} = \sqrt {{{20}^2} + {{\left( {\frac{{20}}{{\sqrt 2 }}} \right)}^2}} = \sqrt {400 + 200} = 24.5{\rm{A}}\)
RMS Value of Time Varying Waveforms Question 10:
Which of the following statement is CORRECT?
Answer (Detailed Solution Below)
RMS Value of Time Varying Waveforms Question 10 Detailed Solution
Different Forms of Alternating Voltage:
The standard form of an alternating voltage is given by:
v = Vm sin θ = Vm sin ωt = Vm sin (2πft) = Vm sin \(\frac{2\pi}{T}\)t
Where,
v is the instantaneous value of voltage
Vm is the maximum value of voltage
(θ = ωt = 2πft = \(\frac{2\pi}{T}\)t) is Co-efficient of sine of time angle
From the above equation following point can be noted:
- The maximum value of alternating voltage is given by the co-efficient of sine of the time angle i.e. Maximum value of voltage = Co-efficient of sine of time angle
- The frequency f of alternating voltage is given by dividing the co-efficient of time in the angle by 2π i.e.,
f = Co-efficient of time in the angle/2π