DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R...

47
DC Circuits Resistance Review Following the potential around a circuit Multiloop Circuits RC Circuits Homework for tomorrow: Chapter 27 Questions 1, 3, 5 Chapter 27 Problems 7, 19, 49 WileyPlus assignment: Chapters 26, 27 Homework for today: Read Chapters 26, 27 Chapter 26 Questions 1, 3, 10 Chapter 26 Problems 1, 17, 35, 77

Transcript of DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R...

Page 1: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

DC Circuits• Resistance Review

• Following the potential around a circuit

• Multiloop Circuits

• RC Circuits

Homework for tomorrow:

Chapter 27 Questions 1, 3, 5

Chapter 27 Problems 7, 19, 49

WileyPlus assignment: Chapters 26, 27

Homework for today:

Read Chapters 26, 27

Chapter 26 Questions 1, 3, 10

Chapter 26 Problems 1, 17, 35, 77

Page 2: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Review: Series and Parallel Resistors

321 /1/1/1/1 RRRR ++++++++====

Parallel:

Series:

321 RRRR ++=

Why?

Why?

Page 3: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Following the Potential

Study Fig. 27-4 in the text to see how the potential

changes from point to point in a circuit.

Note the net change around the loop is zero.

Page 4: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Following the Potential

Note the net change around the loop is zero.

Page 5: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-1

With the current i flowing as

shown, which is at the higher

potential, point b or point c?

1) B is higher

2) C is higher

3) They are the same

4) Not enough

information

Page 6: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Solution

With the current i flowing as shown, which is

at the higher potential, point b or point c?

(1) b is higher (2) c is higher

(3) they’re the same (4) not enough info

Solution: Current flows from high to low

potential just like water flows down hill.

Page 7: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Example: Problem 27-30

ΩΩΩΩ====

ΩΩΩΩ========

ΩΩΩΩ========

75

50

1000.6

4

32

1

R

RR

RVεεεε

(a) Find the equivalent resistance of the network.

(b) Find the current in each resistor.

Page 8: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Problem 27-30 (part a)

ΩΩΩΩ====

ΩΩΩΩ========

ΩΩΩΩ========

75

50

1000.6

4

32

1

R

RR

RVεεεε

(a) Find the equivalent resistance of the network.

ΩΩΩΩ========

====++++++++====

1916/300

300/16/1/1/1/1

234

432234

RSo

RRRR

ΩΩΩΩ====ΩΩΩΩ++++ΩΩΩΩ====++++==== 119191002341

2341

RRR

soseriesinareRandRNow

eq

mARi eq 50/1 ========εεεε(b) Now current

234R

i1

Page 9: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Problem 27-30 (part b)(b) Find the current in each resistor.

First note that i2R2 = i3R3 = i4R4.

mARVi

mARVi

mARVi

1275/95./

1950/95./

1950/95./

44

33

22

============

============

============

VV

A

iRV

95.0

19050.

234

====

ΩΩΩΩ××××====

====

SoCheck: These

three add up

to i1 = 50 mA.

Page 10: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-2

?

6

3

2

3

2

3

2

====

====

ΩΩΩΩ====

ΩΩΩΩ====

i

Ai

R

R

?

Calculate i3, find the closest single-digit number (0-9).

Page 11: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-2

?

6

3

2

3

2

3

2

====

====

ΩΩΩΩ====

ΩΩΩΩ====

i

Ai

R

R?

1) 1 A

2) 2 A

3) 3 A

4) 4 A

5) 5 A

6) 6 A

7) 7 A

8) 8 A

9) 9 A

Page 12: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-2

Ai

R

R

6

3

2

2

3

2

====

ΩΩΩΩ====

ΩΩΩΩ==== ?

AiR

Rii

RiRiVV cb

43

22

3

223

3322

============∴∴∴∴

========−−−−

4

Page 13: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

More Complicated Circuits

How do we solve a problem with more

than one emf and several loops? We

can’t do it just by series and parallel

resistor combinations.

?

Page 14: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Rules for Multiloop Circuits

• The net voltage change around any loop is zero.

• The net current into any junction is zero.

Using these two rules we can always get

enough equations to solve for the currents if

we are given the emfs and resistances.

“Energy conservation”

“Charge conservation”

Page 15: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Example

Ω==

Ω=

=

=

30

5

12

24

32

1

2

1

RR

R

V

V

εε

Find all currents!

First define unknowns: i1 , i2 , i3

i1

i3 i2

Page 16: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Example (continued)

011331 =−− RiRiεLeft-hand loop:

i1

i3 i2

011222 =−− RiRiεRight-hand loop:

Junction:

321 iii +=

Algebra: solve 3 equations for 3 unknowns i1 , i2 , i3

Page 17: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

011331 =−− RiRiε011222 =−− RiRiε

321 iii +=Loop and junction equations:

Put in the given numbers and also replace i1 by i2+i3:

24355305 3231 =+=+ iiii

12535305 3221 =+=+ iiii

Solve two equations in two unknowns to get:

mAimAi 650250 32 ==

Add to get mAiii 900321 =+=

Page 18: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Check by using outer loop:

i1

i3 i2

0

1212

40.3012

12)25.65(.3024

=

−=

×−=

−−−

?0

222331

=

−+− εε RiRi

Page 19: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Repeat with a different R1

ΩΩΩΩ========

ΩΩΩΩ====

====

====

30

40

12

24

32

1

2

1

RR

R

V

V

εεεεεεεε

i1

i3 i2

Exercise for the student: Same equations give

negative i2 in this case! This means current

going downward through right-hand battery.

Page 20: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Back to Basics

• Examples that don’t involve so much algebra,

but focus on the ideas of current and voltage.

• Even though you have a multiloop circuit so

you need to write down the equations from the

loop rule and the junction rule, you may not

have to actually solve simultaneous equations.

Page 21: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Simpler Examples

Textbook homework

problem 27-19

Both these problems can be solved for one

unknown at a time, without messy algebra.

Page 22: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

AII 5.00189 22 −−−−========××××++++

AII 4.25

120359 11 ============++++××××−−−−

AIII 9.2213 ====−−−−====

WIIPWIIP outin 3.331853.33392

2

2

113 ====++++========++++====

Check:

Page 23: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Discharging a Capacitor

Capacitor has charge Q0.

At time t=0, close switch.

What is charge q(t) for t>0?

Obviously q(t) is a function which decreases gradually,

approaching zero as t approaches infinity.

What function would do this? ττττ/0)( teQtq −−−−====

But what is the time constant ?

RC====ττττAnalyze circuit equation: find

Page 24: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Charging a

Capacitor

V)(tq

For large t, q=CV and i=0.

For small t, q=0 and i=V/R.

[[[[ ]]]]RC

eCVtq t

====

−−−−==== −−−−

ττττ

ττττ/1)(

Page 25: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

DC Circuits II

• Circuits Review

• RC Circuits

• Exponential growth and decay

Page 26: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Circuits review so far

• Resistance and resistivity

• Ohm’s Law and voltage drops

• Power and Joule heating

• Resistors in series and parallel

• Loop and junction rules

iRV −−−−====∆∆∆∆

AlR /ρρρρ====

iVP ====

Page 27: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Review: Series and Parallel Resistors

321 /1/1/1/1 RRRR ++++++++====

Parallel:

Series:

321 RRRR ++=

Why?

Why?

Page 28: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Review: Rules for Multiloop Circuits

• The net voltage change around any loop is zero.

• The net current into any junction is zero.

Using these two rules we can always get

enough equations to solve for the currents if

we are given the emfs and resistances.

“Energy conservation”

“Charge conservation”

Page 29: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Review example

011331 =−− RiRiεLeft-hand loop:

i1

i3 i2

011222 =−− RiRiεRight-hand loop:

Junction:

321 iii +=Algebra: solve 3 equations for 3 unknowns i1 , i2 , i3

If any i < 0, current flows the opposite direction.

Page 30: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Simpler Examples

Textbook homework

problem 27-19

Both these problems can be solved for one

unknown at a time, without messy algebra.

Page 31: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-3

1. R > R2

2. R2 > R > R1

3. R1 > R

4. None of the above

Resistors R1 and R2 are connected in series.

If R2 > R1, what can you say about the

resistance R of the combination?

Page 32: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-3

• Resistors R1 and R2 are connected in series.

• R2 > R1.

• What can you say about the resistance R of

this combination?

abovetheofNoneRR

RRRRR

)4()3(

)2()1(

1

122

>>>>

>>>>>>>>>>>>

Solution:

221 RRsoRRR >>>>++++====

Page 33: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-4

1. R > R2

2. R2 > R > R1

3. R1 > R

4. None of the above

Resistors R1 and R2 are connected in parallel.

If R2 > R1, what can you say about the

resistance R of the combination?

Page 34: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Q.27-4

• Resistors R1 and R2 are connected in parallel.

• R2 > R1.

• What can you say about the resistance R of

this combination?

abovetheofNoneRR

RRRRR

)4()3(

)2()1(

1

122

>>>>

>>>>>>>>>>>>

Solution:

121

11111

RRso

RRR>>>>++++====

Page 35: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Discharging a Capacitor

Capacitor has charge Q0.

At time t=0, close switch.

What is charge q(t) for t>0?

Obviously q(t) is a function which decreases gradually,

approaching zero as t approaches infinity.

What function would do this? ττττ/0)( teQtq −−−−====

But what is the time constant ?

RC====ττττAnalyze circuit equation: find

Page 36: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Discharging a Capacitor

ττττ/0)( teQtQ −−−−====

Where is the time constant RC====ττττ

Sum voltage changes

around loop:

RC

QiiRCQ ========−−−− ,0/

Get differential

equation for Q(t):RC

Q

dt

dQ−−−−====

dt

dQi

But

−−−−====

i++++

−−−−

Solution:

Page 37: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Charging a

Capacitor

εεεε)(tq

For large t, i=0 and

For small t, q=0 and

)(),( titq

Ri /εεεε====εεεεCq ====

But what are ?

Page 38: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Charging a

Capacitor

Sum voltage changes:

i(t) →

+Q(t)

-Q(t)

dt

dQi

CQiR

====

====−−−−−−−− 0/εεεεεεεε

RC

teCtQ

====

−−−−−−−−====

ττττ

ττττεεεε /1)(

RC

Q

Rdt

dQ−=

εGet diff. eq.:

Solution

Page 39: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Charging a Capacitor

∞∞∞∞→→→→→→→→

→→→→→→→→

−−−−−−−−====

tasC

tas

teCtQ

εεεε

εεεε ττττ

00

/1)(

See solution gives desired behavior:

Page 40: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Exponential Growth and Decay

This simple differential equation occurs in

many situations:QConst

dt

dQ.)(====

If dQ/dt = +KQ, we have the “snowball” equation:

growth rate proportional to size. Population growth.

If dQ/dt = -KQ, we have rate of decrease proportional

to size. For example radioactive decay.

KQdt

dQ++++====

KteQQ++++==== 0

KQdt

dQ−−−−==== KteQQ

−−−−==== 0

Page 41: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Try Exponential Solution

ττττ/0)(

teQtQtryKQ

dt

dQsolveTo ========

We know we want a result which increases faster and faster. One function which does this is the exponential function. So try that:

Questions:

1. Is this a solution?

2. If so, what is the “time constant” τ ?

Exponential Growth

0

50

100

150

200

0 20 40 60

t

Q

Page 42: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

ττττ/0)(

teQtQtryKQ

dt

dQsolveTo ========

ττττττττττττττττ

ττττ

Qe

Qe

dt

dQ

dt

dQ

eQtQ

tt

t

============

====

//

/

00

0)(

But we want KQdt

dQ====

So we DO have a solution IF K/1====ττττ

Page 43: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Doubling Time

ττττ/0)( teQtQ ====If

how long does it take for Q to double?

ττττττττττττ

ττττττττ

ττττ

7.0

693.0)2ln(/2

)(

)(

/

//

/)(

≅≅≅≅∆∆∆∆

========∆∆∆∆====

========∆∆∆∆++++

∆∆∆∆

∆∆∆∆∆∆∆∆++++

tSo

tifeAnd

ee

e

tQ

ttQ

t

tt

tt

Page 44: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Radioactive Decay

For an unstable isotope, a certain fraction of the

atoms will disintegrate per unit time.

ττττ/0)(

teQtQuseKQ

dt

dQFor

−−−−====−−−−====

Now τ is called the mean life, and the half-life

is T1/2 = τ ln(2) = time for half the remaining

atoms to disintegrate, and

ττττ7.02/1 ≅≅≅≅T

Page 45: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Discharge of a Capacitor

Back to electricity. From the loop rule we got

KQRC

Q

dt

dQ−−−−====−−−−====

So the solution is ττττ/0)( teQtQ −−−−====

But what are Q0 and τ?

)0(0 QQ ====

RCK ======== /1ττττTime constant:

Initial condition:

Page 46: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Example

A 40 pF capacitor with a charge of 20 nC is

discharged through a 50 MΩ resistor.

( a ) What is the time constant?

( b ) At what time will ½ the charge remain?

( c ) How much charge will remain after 5 ms?

sRC3612

100.210501040−−−−−−−− ××××====××××××××××××========ττττ

mssT 4.1100.27.07.03

2/1 ====××××××××======== −−−−ττττ

nCeeQtQt

64.120)(5.2/

0 ====××××======== −−−−−−−− ττττ

Page 47: DC Circuits - utoledo.eduastro1.panet.utoledo.edu/~vkarpov/L07S.ch27.pdf · 6.0 100 4 2 3 1 R R R εεεε V R (a) Find the equivalent resistance of the network. (b) Find the current

Circuits Summary

Things to remember about DC circuits:

• Resistance and resistivity

• Ohm’s Law and voltage drops

• Power and Joule heating

• Resistors in series and parallel

• Loop and junction rules

• RC circuits: charging and discharging a capacitor

• RC time constant

iRV −−−−====∆∆∆∆AlR /ρρρρ====

ττττ/0)(

teQtQ−−−−==== RC====ττττ

iVP ====

Quiz tomorrow on Chapters 26,27.