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1 Electric Circuits
Simple Resistive Circuits
Qi Xuan Zhejiang University of Technology
September 2015
Structure
• Resistors in Series • Resistors in Parallel • The Voltage/Current-‐Divider Circuit • Voltage/Current Division • Measuring Voltage and Current
• Measuring Resistance-‐The Wheatstone Bridge
• Delta-‐to-‐Wye (Pi-‐to-‐Tee) Equivalent Circuit
2 Electric Circuits
A Rear Window Defroster
Electric Circuits 3
A Rear Window Defroster A resisEve circuit
Resistors in Series
Electric Circuits 4
Electric Circuits 5
In general, if k resistors are connected in series, the equivalent single resistor has a resistance equal to the sum of the k resistances, or
Resistors in Parallel
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Electric Circuits 7
Conductance
Typical Cases
• If k = 2, we have
• If R1 =R2 =…… = Rk = R, we have 1/Req = k/R Req = R/k
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Example #1
• For the circuit shown, find (a) the voltage v, (b) the power delivered to the circuit by the current source, and (c) the power dissipated in the 10 Ω resistor.
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i1 i2
R1 v1
R1 = (10+6)×64 / (10+6+64) = 12.8 Ω
R = (7.2+12.8)×30 / (7.2+12.8+30) = 12 Ω v = 5R = 60 V
i1 = v / (7.2+R1) = 60 / (7.2+12.8) = 3 A
v1 = i1×R1 = 3×12.8 = 38.4 V
i2 = v1 / (6+10) = 38.4 / 16 = 2.4 A
p = i22×10 = 2.4×2.4×10 = 57.6 W
Solu5on for Example #1
The Voltage-‐Divider Circuits
Electric Circuits 11
The current-‐Divider Circuit
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Example #2 a) Find the value of R that will cause 4 A of current to
flow through the 80 Ω resistor in the circuit shown. b) How much power will the resistor R from part (a)
need to dissipate? c) How much power will the current source generate
for the value of R from part (a)?
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Solu5on for Example #2
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i vR
For (a), we have i = 20R / (40+80+R) = 4 A
R = 30 Ω
For (b), we have vR = (40+80)i = 120×4 = 480 V
pR = vR2 / R= 4802 / 30 = 7680 W
For (c), we have v = 60×20+vR = 1200+480 = 1680 V
p = 20v = 20×1680 = 33600 W
Voltage/Current Division
Electric Circuits 15
Example #3 a) Use voltage division to determine the voltage v0 across the
40 Ω resistor in the circuit shown. b) Use v0 from part (a) to determine the cur-‐ rent through the
40 Ω resistor, and use this current and current division to calculate the current in the 30 Ω resistor.
c) How much power is absorbed by the 50 Ω resistor?
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Solu5on for Example #3
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For (a), we have Req = 40+(20||30||(50+10))+70 = 40+10+70=120 Ω
vo = 60×40 / Req = 20 V
For (b), we have i = vo / 40 = 20 / 40 = 0.5 A
i1 = i Rp / 30 = 0.5×10 / 30 A = 166.67 mA
i
i1 i2
For (c), we have i2 = i Rp / 60 = 0.5×10 / 60 A = 1/12 A
p2 = 50i22 = 50 / 144 W = 347.22 mW
Rp
Measuring Voltage and Current
Electric Circuits 18
An ammeter is an instrument designed to measure current; A voltmeter is an instrument designed to measure voltage
An ideal ammeter has an equivalent resistance of 0 Ω and funcEons as a short circuit in series with the element whose current is being measured. An ideal voltmeter has an infinite equivalent resistance and thus funcEons as an open circuit in parallel with the element whose voltage is being measured.
Digital and Analog Meters
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d’Arsonval Meter Movement
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d'Arsonval meter movement consists of a movable coil placed in the field of a permanent magnet. When current flows in the coil, it creates a torque on the coil, causing it to rotate and move a pointer across a calibrated scale. By design, the deflec5on of the pointer is directly propor5onal to the current in the movable coil. The coil is characterized by both a voltage raEng and a current raEng.
For example, one commercially available meter movement is rated at 50 mV and 1 mA. This means that when the coil is carrying 1 mA, the voltage drop across the coil is 50 mV and the pointer is deflected to its full-scale position.
DC Ammeter/Voltage Circuit
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Example #4 a) A 50 mV, 1 mA d'Arsonval movement (le^) is to be used in an
ammeter with a full-‐scale reading of 10 mA. Determine RA. b) Find the current in the circuit shown (right). c) If the ammeter (le^) is used to measure the current in the
circuit (right), what will it read?
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Solu5on for Example #4
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i iB iA vA
For (a) (left), we have iA = I - iB=10 mA -1mA = 9 mA
RA = vA / iA = 50 / 9 =5.56 Ω
For (b) (right), we have i = 1 / 100 A = 10 mA
For (c), we have Req = vA / i = 50 / 10 = 5 Ω
i = 1 / (100+Req) = 1 / 105 A= 9.524 mA
Req
Req
Measuring Resistance: The Wheatstone Bridge
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ig = 0 i1 = i3 i2 = ix
i3R3 = ixRx i1R1 = i2R2
R1 / R2 = i2 / i1
R3 / Rx = ix / i3 = i2 / i1
Rx = R2R3 / R1
In a commercial Wheatstone bridge, R1 and R2 consist of decimal values of resistances that can be switched into the bridge circuit.
Ba`ery
Example #5 The bridge circuit shown is balanced when R1=100 Ω, R2 =1000 Ω, and R3 =150 Ω. The bridge is energized from a 5 V dc source. a) What is the value of Rx? b) Suppose each bridge resistor is capable of dissipaEng 250
mW. Can the bridge be le^ in the balanced state without exceeding the power-‐dissipaEng capacity of the resistors, thereby damaging the bridge?
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Solu5on for Example #5
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For (a), we have Rx = R2R3 / R1 = 1000×150 / 100 = 1500
For (b), we have i1= v / (R1+R3)= 5 / 250 = 0.02 A i2= v / (R2+Rx)= 5 / 2500 = 0.002 A
p1=i12R1 = 0.022×100 =0.04 W
p2=i22R2 = 0.0022×1000 =0.004 W
p3=i12R3 = 0.022×150 =0.06 W
px=i22Rx = 0.0022×1500 =0.006 W
i1 i2
Delta-‐to-‐Wye (Pi-‐to-‐Tee) Equivalent Circuits
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Δ π
Y T
The Δ-‐to-‐Y Transforma5on
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R1 = (Rab+Rca-Rbc) / 2 = RbRc / (Ra+Rb+Rc) R2 = (Rab+Rbc-Rca) / 2 = RcRa / (Ra+Rb+Rc) R3 = (Rbc+Rca-Rab) / 2 = RaRb / (Ra+Rb+Rc)
How about Y-‐to-‐Δ?
The Y-‐to-‐Δ Transforma5on
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Example #6
Use a Y-‐to-‐Δ transformaEon to find the voltage v in the circuit shown.
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Solu5on for Example #6
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a
b
c
a b
c
Rc
Rb Ra
Ra = (20×10+20×5+10×5) / 20 =17.5 Ω Rb = (20×10+20×5+10×5) / 5 = 70 Ω Rc = (20×10+20×5+10×5) / 10 = 35 Ω
Electric Circuits 32
35Ω
a
b
c
28Ω 70Ω
105Ω 17.5Ω
2A v
Req = 35||[(28||70)+105||17.5] = 35||(20+15) = 17.5 Ω
v = 2Req = 35 V
Summary
• Series/Parallel resistors • Voltage/Current division • Digital/Analog voltmeter/ammeter • Wheatstone bridge • Δ-‐to-‐Y/Y-‐to-‐Δ transformaEon
Electric Circuits 33