mems 0031 electric circuits - university of pittsburgh
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Department of Mechanical Engineering
MEMS 0031 Electric Circuits
Chapter 1 Circuit variables
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Department of Mechanical Engineering
Chapter/Lecture Learning ObjectivesAt the end of this lecture and chapter, you should able to: Represent the current and voltage of an electric circuit element,
paying particular attention to the reference direction of the current and to the reference direction or polarity of the voltage
Calculate the power and energy supplied or received by a circuit element
Use the passive convention to determine whether the product of the current and voltage of a circuit element is the power supplied by that element or the power received by the element
Use scientific notation to represent electrical quantities with a wide range of magnitudes
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Department of Mechanical Engineering
A general two-terminal electric circuit element Circuit element
Circuit
Circuit variables
Resistor Switch capacitor Inductor Sources
o Voltage sourceo Current sources
Transducer
A simple circuitAn electric circuit or electric network is an interconnection of electrical elements linked together in a closed path so that an electric current may flow continuously
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Department of Mechanical Engineering
Circuit variables
dtdQi =
21 ii −=
Charge: the quantity of electrically responsible for electric phenomena
Current: time rate of flow of the electric charge past a given point
18
19
1 6.24 10 electron charge
1 e =- 1.602 10
C x
x C−
=
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Department of Mechanical Engineering
Current: Net Positive Charge Flow
( ) ( )
et + charge;
Instantaneous current:
( )
R R L L
avg
Q Q Q Q QQN Q it
dqi tdt
+ − + −∆ = − − −∆
= =∆
=
LQ −RQ −
RQ +
LQ +
Unit of Current : Ampere (A); Unit of Charge: Coulomb (C); 1 A = 1 Coulomb per second
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Department of Mechanical Engineering
Circuit variables
A direct current (DC) of magnitude of I
Time-varying current i
A Ramp, slope=M
A Sinusoid, ω = angular frequency
An exponential, I, b= constant
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Department of Mechanical Engineering
dtdqi =
( )∫∫ +==∝−
ttqiddiq
00ττ
Circuit variables
If the charge is known, the current can be find from
If the current is known, the charge can be find by
( )0q is the charge at t=0
2 1
2 1
,
( )
i islope Mt t
i t Mt b
−=
−= +
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Department of Mechanical Engineering
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Department of Mechanical Engineering
Circuit variables
( ) 2
2 3 2 3 20 0 0
8 4 A8 8( ) (0) (8 4 ) 0 2 2 C3 3
tt t
i t t t
q t i d q d t tτ τ τ τ τ τ
= −
= + = − + = − = −∫ ∫
( )
( )
4sin 3 C
4sin 3 12cos3 A
q t tdq di t t tdt dt
=
= = =
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Department of Mechanical Engineering
Example: Charge is given, q(t), find current, i(t)
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Department of Mechanical Engineering
dtdqi = Divide q(t) into sections to get q(t)
expressions at each section
( )( 0) ( )
(1) 1, ( ) 0, ( ) 0(2 )1 3 , ( ) 1, ( ) 1(3)3 5 , ( ) 1.5 6.5, ( ) 1.5(4 )5 6 , ( ) 1, ( ) 0(5)6 7 , ( ) 7 ,( ) 1(6)7 , ( ) 0, ( ) 0
m slopeq t mt b
b q t q t mtt q t i t
s t s q t t i ts t s q t t i ts t s q t i ts t s q t t i ts t q t i t
== + = = = −
−∞ < ≤ = =< ≤ = + =< ≤ = − + = −< ≤ = − =< ≤ = − =≤ = =
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Department of Mechanical Engineering
Example : From known current, find charge q(t)
The current in a circuit element is i(t) = 3 sin (5t + 30) when t ≥ 0 and i(t) = 0 when t < 0. Determine the total charge that entered a circuit element for t ≥ 0
dtdqi = ( )∫∫ +==
∝−
ttqiddiq
00ττ
( )0
0
( ) 3 sin (5 + 30) 0
3 3 3 3cos(5 30) cos(5 30) .5 5 5 2
3 3cos(5 30)5 10
t t
t
q t id d q
t
t
τ τ τ
τ
−∝= = +
= − + = − + +
= − + +
∫ ∫
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Department of Mechanical Engineering
Example : Find the charge and sketch its waveform for the given current entering a terminal of element as shown in P1.2-7
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Department of Mechanical Engineering
Circuit variablesVoltage is the basic circuit variable describing energy (w) required to cause charge (q) to flow.
Voltage across an element is the work (energy) required to move a unit positive charge q from –to + terminal of the element dwv
dq=
Energy is capacity to perform work; Unit of voltage is the volt (V). 1V = 1J/C
voltage at b wrt aVoltage directions= terminal polarities (-,+)
ab bav v= −
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Department of Mechanical Engineering
Power Absorbed by element
Power Supplied by the element
Circuit variables
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Department of Mechanical Engineering
Circuit variables
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Department of Mechanical Engineering
Power and EnergyPower is time rate of expending or absorbing
energy (w)
For an electric circuit element, power absorbed or supplied by the element is:
dwpdt
=
. .
. instantaneous power
dw dqp v idq dt
p v i
= =
= =
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Department of Mechanical Engineering
The energy absorbed by an element for a given power:
If the element only receives power for t ≥ to, and Let to =0
t
dw pdt
w pdt−∞
=
= ∫
0 0
t
t
w pdt=
= ∫
Power and Energy
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Department of Mechanical Engineering
+ -abv
( )i t→
- +bav
( )i t→
Power Absorbed by element
Power Supplied by the element
Passive Convention (Passive sign Convention):
Current enters terminal of higher voltage, element absorbed power
Passive Convention
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Department of Mechanical Engineering
Passive Convention
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Department of Mechanical Engineering
Lumped –Circuit elementsConsider current i(t) and v(t) of a circuit
element as shown:– Passive Convention – Current enters terminal of higher voltage– Element absorbed power
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Department of Mechanical Engineering
Example :
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Department of Mechanical Engineering
Example :
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Department of Mechanical Engineering
Example :
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Department of Mechanical Engineering