Download SEMESTER 2 FINAL EXAM STUDY GUIDE MC w/Answers

S2 F1
Multiple Choice
Identify the letter of the choice that best completes the statement or answers the question.
1. Which has greater linear speed, a horse near the outside rail of a merry-go-round or a horse near the inside rail?
a. The inside horse
b. The outside horse
c. Neither—they both have the same linear speed.
2. Which has greater angular speed, a horse near the outside rail of a merry-go-round or a horse near the inside rail?
a. Neither—they both have the same angular speed.
b. The inside horse
c. The outside horse
3. A car travels in a circle with constant speed. The net force on the car
a. is zero because the car is not accelerating.
b. is directed forward, in the direction of travel.
c. is directed toward the center of the curve.
d. none of the above
4. The gravitational force between two massive spheres
a. is always an attraction.
b. depends on how massive they are.
c. depends inversely on the square of the distances between them.
d. all of the above
5. A very massive object A and a less massive object B move toward each other under the influence of mutual
gravitation. Which force, if either, is greater?
a. The force on B
b. The force on A
c. Both forces are the same.
6. Gravitational field lines show the _____.
a. direction of the field at each point
b. direction of the force on any mass
c. direction a mass would be accelerated
d. strength of the field
e. all of the above
7. If you were to weigh yourself in an elevator that is in free fall, compared to your ordinary weight, you would
weigh _____.
a. more
b. the same
c. less, but more than zero
d. zero
8. The speed of a satellite in a circular orbit is _____.
a. constant
b. not constant
c. constantly increasing
9. The source of all wave motion is a
a. region of variable high and low pressure.
b. vibration.
c. movement of matter.
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d. harmonic object.
The time needed for a wave to make one complete cycle is its
a. frequency.
b. velocity.
c. amplitude.
d. period.
e. wavelength.
The distance between successive identical parts of a wave is called its
a. frequency.
b. period.
c. velocity.
d. amplitude.
e. wavelength.
A wave created by shaking a rope up and down is called a
a. Doppler wave.
b. standing wave.
c. longitudinal wave.
d. constructive wave.
e. transverse wave.
Sound is an example of a
a. longitudinal wave.
b. constructive wave.
c. Doppler wave.
d. transverse wave.
e. standing wave.
When two or more waves are at the same place at the same time, the resulting effect is called
a. a standing wave.
b. a Doppler wave.
c. a shock wave.
d. interference.
e. a period.
The Doppler effect is the change in observed frequency due to
a. the original frequency of the source.
b. the type of medium the wave is in.
c. the motion of the source or observer.
d. the type of wave.
e. all of the above
When a sound source moves towards you, what happens to the wave speed?
a. It decreases.
b. It increases.
c. It stays the same.
If you double the frequency of a vibrating object, its period
a. halves.
b. is quartered.
c. doubles.
What happens when an airplane is flying faster than the speed of sound?
a. There is no sonic boom.
b. It becomes very quiet inside the plane.
c. Nobody can hear the plane fly overhead.
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d. A shock wave is produced.
e. none of the above
An observer on the ground hears a sonic boom that is created by an airplane flying at a speed
a. equal to the speed of sound.
b. greater than the speed of sound.
c. just below the speed of sound.
d. none of the above
The Doppler effect occurs when a source of sound moves
a. away from you.
b. toward you.
c. both A and B
d. none of the above
The period of an ocean wave is 10 seconds. What is the wave’s frequency?
a. 30.0 Hz
b. 5.0 Hz
c. 0.10 Hz
d. 20.0 Hz
e. 10.0 Hz
A certain ocean wave has a frequency of 0.08 hertz and a wavelength of 10 meters. What is the wave’s speed?
a. 1.0 m/s
b. 125 m/s
c. 0.80 m/s
d. 10 m/s
e. 0.08 m/s
A leaf on a pond oscillates up and down two complete cycles each second as a water wave passes. What is the
wave's frequency?
a. 0.5 hertz
b. 1 hertz
c. 2 hertz
d. 3 hertz
e. 6 hertz
Compared to the speed of light, sound travels
a. faster.
b. at about the same speed.
c. slower.
Sound waves are produced by
a. radio stations.
b. vibrating objects.
c. soft objects.
d. objects under pressure.
e. none of the above
Sound waves cannot travel in
a. steel.
b. air.
c. a vacuum.
d. water.
e. Sound can travel in all of the above.
Resonance occurs when
a. sound changes speed in going from one medium to another.
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b. sound makes multiple reflections.
c. the amplitude of a wave is amplified.
d. an object is forced to vibrate at its natural frequency.
e. all of the above
A singer shattering crystal glass with her voice is a demonstration of
a. beats.
b. sound refraction.
c. an echo.
d. interference.
e. resonance.
The phenomenon of beats results from sound
a. interference.
b. reflection.
c. refraction.
d. all of the above
e. none of the above
A 340-Hz sound wave travels at 340 m/s in air, with a wavelength of
a. 1 m.
b. 10 m.
c. 100 m.
d. 1000 m.
e. none of the above
Electromagnetic waves are
a. transverse waves.
b. longitudinal waves.
Electromagnetic waves
a. need a medium to travel through.
b. can travel through a vacuum.
Compared to the wavelength of ultraviolet waves, the wavelength of infrared waves is
a. the same.
b. shorter.
c. longer.
Compared to the velocity of radio waves, the velocity of visible light waves is
a. slower.
b. faster.
c. the same.
The source of all electromagnetic waves is
a. magnetic fields.
b. heat.
c. electric fields.
d. vibrating charges.
e. none of the above
The main difference between a radio wave and a sound wave is its
a. basic nature.
b. amplitude.
c. energy.
d. frequency.
e. wavelength.
If the sun were to disappear right now, we wouldn't know about it for 8 minutes because it takes 8 minutes
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a. to operate receiving equipment in the dark.
b. for light to travel from the sun to Earth.
c. for the sun to disappear.
d. all of the above
e. none of the above
Compared to its speed in air, the speed of light in water is
a. slower.
b. the same.
c. faster.
Electromagnetic waves with higher frequencies have wavelengths that are
a. shorter.
b. longer.
If an electron vibrates up and down 1000 times each second, it generates an electromagnetic wave having a
a. frequency of 1000 Hz.
b. speed of 1000 m/s.
c. period of 1000 s.
d. wavelength of 1000 m.
After randomly polarized light passes through a polarizer, it is
a. totally blocked.
b. totally polarized.
c. randomly polarized.
d. partially polarized.
If two polarizing filters are held with their polarization axes at right angles to each other, the amount of light
transmitted compared to when their axes are parallel is
a. zero.
b. half as much.
c. the same.
d. twice as much.
The color of an object we see is determined by the
a. colors of light reflected by the object.
b. frequencies of light absorbed by the object.
c. colors of light shining on the object.
d. frequencies of light reflected by the object.
e. all of the above
Sunlight contains all colors of light, but much of it is
a. orange.
b. blue.
c. violet.
d. yellow.
e. red.
Earth receives a lot of ultraviolet radiation from the sun. Luckily most of it doesn't reach the ground, because it is
a. scattered by the upper atmosphere.
b. Actually there isn't enough UV radiation coming from the sun to harm us.
c. absorbed by the large amount of air in the atmosphere.
d. absorbed by a protective layer of ozone gas in the upper atmosphere.
Different colors of light correspond to different light
a. frequencies.
b. polarities.
c. intensities.
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d. velocities.
e. none of the above
The color of an opaque object is determined by the light that is
a. absorbed.
b. reflected.
c. transmitted.
d. all of the above
e. none of the above
If sunlight were green instead of white, the most comfortable color to wear on a hot day would be
a. yellow.
b. blue.
c. green.
d. magenta.
e. none of the above
The reason the sky is blue is that air molecules
a. are blue.
b. reflect blue light.
c. absorb yellow light.
d. absorb and then reemit blue light, scattering it in all directions.
e. absorb green light.
Sunsets are red because
a. the longest path of sunlight through the atmosphere is at sunset or sunrise.
b. a lot of high-frequency light is scattered by the atmosphere.
c. blue light from the sun is scattered by Earth's atmosphere.
d. all of the above
e. none of the above
The three primary colors of light for additive color mixing are_____.
a. red, green, and blue.
b. yellow, green, and blue.
c. red, yellow, and blue.
d. red, yellow, and green.
e. yellow, cyan, and red.
The law of reflection says that
a. the angle of reflection from a mirror equals the angle of incidence.
b. waves incident on a mirror are partially reflected.
c. all waves incident on a mirror are reflected.
d. the angle a ray is reflected from a mirror is random.
When a virtual image is created in a plane mirror
a. the image is upright.
b. the image is located behind the mirror.
c. reflected rays diverge.
d. all of the above
e. none of the above
The reason we can read print from any direction is that
a. the white part of a page reflects light in all directions.
b. letters emit black light in all directions.
c. letters absorb black light from all directions.
d. all of the above
e. none of the above
55. Refraction occurs
a. when a wave changes speed.
b. only at a wave front.
c. at any unpredictable time.
d. only with light waves.
e. all of the above
56. The critical angle for a light from the bottom of a swimming pool shining upward toward the pool's surface is the
angle
a. where light is refracted so it just skims the pool surface.
b. 43 degrees.
c. at which all light is refracted out of the pool.
d. 42 degrees.
e. at which some light is reflected from the surface.
57. A beam of light emerges from water into air at an angle. The beam is bent
a. away from the normal.
b. not at all.
c. 48 degrees upward.
d. 96 degrees upward.
e. towards the normal.
58. The effect that we call a mirage has most to do with
a. reflection.
b. refraction.
c. diffraction.
d. interference.
e. scattering.
59. Different colors of light travel at different speeds in a transparent medium. In a vacuum, different colors of light
travel at
a. the same speed.
b. different speeds.
60. The spectrum produced by a prism or a raindrop is evidence that the average speed of light in the material depends
on the light's
a. transmission qualities.
b. color.
c. wave nature.
d. particle nature.
61. A beam of light travels fastest in
a. air.
b. water.
c. plastic.
d. glass.
e. Its average speed is the same in each of the above.
62. An image of a distant object formed by a single converging lens
a. is upside down.
b. can be focused on a screen.
c. is real.
d. can be projected on a wall.
e. all of the above
63. An image formed by a single diverging lens
a. is upside down.
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b. can be projected on a wall.
c. is virtual.
d. is larger than the object.
e. all of the above
Ray diagrams are used to
a. figure out where an image will be located.
b. find the focal point of a lens.
c. draw pretty pictures.
d. figure out what kind of lens is being used.
e. all of the above
All lenses rely on light having a
a. slower speed in the lens.
b. consistent speed everywhere.
c. wavelength and frequency, the product of which equals c.
d. none of the above
The image your eye receives is
a. upside down.
b. right-side up.
On a bright day, the iris of the eye changes so the pupil
a. stays the same as always.
b. becomes larger.
c. becomes smaller.
An interference pattern is produced when
a. two or more light waves meet.
b. the crests of two waves meet.
c. the troughs of two waves meet.
d. light passes through two narrow slits.
e. all of the above
Constructive interference occurs when
a. the crest of one wave meets the trough of another wave.
b. two waves of the same color overlap.
c. the crests of two waves overlap.
d. all of the above
e. none of the above
Destructive interference occurs when
a. the crests of two waves overlap.
b. two waves of the same color overlap.
c. the crest of one wave meets the trough of another wave.
d. all of the above
e. none of the above
The charge of an electron is
a. positive.
b. negative.
c. Electrons have no charge.
Atomic nuclei of almost all elements consist of
a. only neutrons.
b. protons and electrons.
c. neutrons and electrons.
d. only protons.
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e. protons and neutrons.
Two like charges
a. neutralize each other.
b. repel each other.
c. must be neutrons.
d. attract each other.
e. have no effect on each other.
Protons and electrons
a. attract each other.
b. repel each other.
c. do not interact.
Electrical forces between charges are strongest when the charges are
a. far apart.
b. close together.
c. The electrical force is constant everywhere.
Two charges are separated by a certain distance. If the magnitude of each charge is doubled, the force on each
charge is
a. halved.
b. doubled.
c. tripled.
d. quadrupled.
When the distance between two charges is halved, the electrical force between the charges
a. doubles.
b. reduces to one fourth.
c. halves.
d. quadruples.
e. none of the above
A difference between electrical forces and gravitational forces is that electrical forces include
a. infinite range.
b. repulsive interactions.
c. the inverse square law.
d. separation distance.
e. none of the above
In a good insulator, electrons are usually
a. not moving at all.
b. free to move around after an impurity has been added.
c. free to move around.
d. tightly bound in place.
e. semi-free to move around.
Objects can be charged by
a. induction.
b. friction.
c. touching.
d. all of the above
e. none of the above
Charge carriers in a metal are electrons rather than protons, because electrons are
a. relatively far from a nucleus.
b. loosely bound.
c. lighter.
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d. all of the above
e. none of the above
To be safe in the unlikely case of a lightning strike, it is best to be inside a building framed with
a. steel.
b. wood.
c. either A or B.
When a charged cloud passes overhead, the ground below is charged by
a. induction.
b. polarization.
c. deduction.
d. electrification.
The electrostatic force between two charges located 8 meters apart is 0.30 N. What will the force be between these
charges when they are located 2 meters apart?
a. 2.4 N
b. 0.04 N
c. 0.08 N
d. 0.3 N
e. 4.8 N
A 1-C charge and a 2-C charge attract each other with 12 N of force. How much will a 1-C charge and a 6-C
charge attract each other when placed the same distance apart?
a. 5 N
b. 36 N
c. 6 N
d. 72 N
e. 12 N
Two charges separated by a distance of 1 meter exert a 2-N force on each other. If the magnitude of each charge is
quadrupled, the force on each charge is
a. 2 N.
b. 16 N.
c. 32 N.
d. 64 N.
e. none of the above
If you walk into a region of space and suddenly feel a force, the space is said to contain a
a. charged object.
b. force field.
c. large charge.
d. black hole.
e. heavy object.
Every proton in the universe is surrounded by its own
a. gravitational field.
b. electric field.
c. both A and B
d. none of the above
The direction of electric field lines shows the
a. direction of the force on a test positive charge.
b. size of the field.
c. strength of the field.
d. all of the above
If two negative charges are held close together and then released, the charges will
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a. accelerate toward each other.
b. accelerate away from each other.
c. not move.
d. move at a constant speed away from each other.
Two parallel plates are oppositely charged. The left plate is negative and the right plate is positive. In which
direction does the electric field point?
a. to the left
b. to the right
In solid conductors, electric current is the flow of
a. positive and negative charges.
b. electrons.
c. negative ions.
d. protons.
e. none of the above
Electrons move in an electric circuit
a. by being bumped by other electrons.
b. by interacting with an established electric field.
c. by colliding with molecules.
d. because the wires are so thin.
e. none of the above
An ampere is a
a. unit of resistance.
b. unit of current.
c. type of charge.
d. voltage.
e. current.
Electrical resistance in a wire depends on the wire's
a. thickness.
b. conductivity.
c. length.
d. all of the above
e. none of the above
For most conductors, as their temperature increases, their resistance
a. decreases.
b. increases.
c. stays the same.
The primary reason a bird can perch harmlessly on bare high voltage wires is that
a. a bird's feet are close together.
b. a bird has a very large electrical resistance.
c. there is no potential difference across the bird's feet.
d. all of the above
Alternating current is made by
a. alternating current and voltage.
b. alternating the direction of voltage of the power source.
c. huge chemical batteries.
d. none of the above
Current from a battery is always
a. DC.
b. AC.
100. When we say an appliance uses up electricity, we really are saying that
a. electrons are taken out of the circuit and put somewhere else.
b. electron kinetic energy is changed into heat and other forms of energy.
c. the main power supply voltage is lowered.
d. current disappears.
e. electric charges are dissipated.
101. Power outlets in our homes typically have a potential difference of
a. 30 V.
b. 120 A.
c. 60 A.
d. 240 V.
e. 120 V.
102. When a 15-V battery is connected to a resistor, 2 A of current flows in the resistor. What is the resistor's value?
a. 2 ohms
b. 7.5 ohms
c. 15 ohms
d. 30 ohms
e. more than 30 ohms
103. The current through a 10-ohm resistor connected to a 150-V power supply is
a. 1A.
b. 10 A.
c. 15 A.
d. 150 A.
e. none of the above
104. A 15-ohm resistor has a 2-A current in it. What is the voltage across the resistor?
a. 2 V
b. 15 V
c. 17 V
d. 22 V
e. more than 22 V
105. How much power is used by a 6.0-V flashlight battery that draws 1.5 A of current?
a. 1.5 W
b. 6 W
c. 9 W
d. 30 W
e. 4 W
106. When plugged into a 120-V wall outlet, how much current is used by a lightbulb rated at 100 W?
a. 12,000 A
b. 100 A
c. 120 A
d. 0.8 A
e. none of the above
107. A power line with a resistance of 3 ohms has a current of 70 A in it. The power dissipated in the line is
a. 105 W.
b. 210 W.
c. 420 W.
d. 14,700 W.
e. none of the above
108. In order for current to flow in a circuit, you must have
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a. a switch that is open.
b. a complete path for the current.
c. two light bulbs in parallel.
d. two light bulbs in series.
e. all of the above
A closed circuit is a circuit in which charge
a. can flow.
b. is prevented from flowing.
When resistors are put in series next to each other, their overall resistance is
a. the same as the resistance of one of the resistors.
b. larger than the resistance of any individual resistor.
c. smaller than the resistance of any of the resistors.
When resistors are put in parallel with each other their overall resistance is
a. smaller than the resistance of any of the resistors.
b. larger than the resistance of any other resistor.
c. the same as the resistance of one of the resistors.
As more lamps are put into a series circuit, the overall current in the circuit
a. stays the same.
b. increases.
c. decreases.
As more lamps are put into a parallel circuit, the overall current in the circuit
a. increases.
b. stays the same.
c. decreases.
When one light bulb in a series circuit containing several light bulbs burns out
a. none of the other bulbs will light up.
b. nothing changes in the rest of the circuit.
c. the other light bulbs burn brighter.
When one light bulb in a parallel circuit containing several light bulbs burns out, the other light bulbs
a. do not burn at all.
b. burn brighter.
c. burn the same as before.
In a simple parallel circuit
a. current through each branch is always the same.
b. voltage across each branch is always the same.
c. the value of each resistor is the same.
d. the circuit won't work unless there is a fuse in it.
e. none of the above
A 40-W light bulb is connected to a 12-V car battery. When another 40-W bulb is connected in parallel with the
first bulb, the battery's output energy
a. remains the same.
b. halves.
c. doubles.
The total resistance of a 8-ohm resistor and a 5-ohm resistor in series is
a. 40 ohms.
b. 13 ohms.
c. 2 ohms.
d. 5 ohms.
e. 3 ohms.
119. The total resistance of a 6-ohm resistor and a second 6-ohm resistor in parallel is
a. 12 ohms.
b. 3 ohms.
c. 6 ohms.
d. 20 ohms.
e. 37 ohms.
120. The source of all magnetism is
a. moving electric charges.
b. ferromagnetic materials.
c. tiny domains of aligned atoms.
d. tiny pieces of iron.
e. none of the above
121. Surrounding every moving electron is
a. an electric field.
b. a magnetic field.
c. both A and B
d. none of the above
122. If the north pole of one magnet is brought near the south pole of another magnet, the poles will
a. repel each other.
b. attract each other.
c. not interact with each other at all.
123. If you break a bar magnet in half, each half
a. becomes a bar magnet with two poles.
b. becomes unmagnetized.
c. contains one magnetic pole.
124. Magnetic field strength is
a. strongest close to a magnet.
b. constant everywhere around a magnet.
c. strongest far from a magnet.
125. Magnetic domains are
a. regions that may or may not be magnetized.
b. clusters of atoms randomly aligned.
c. regions of atoms magnetically aligned.
d. blocks of material.
126. When current passes through a wire, a magnetic field is created around the wire only if the
a. wire is absolutely straight.
b. wire is curved in a loop.
c. current makes a complete loop.
d. current comes from a battery.
e. A magnetic field is always created around the wire.
127. Loops of wire in a motor rotate because a
a. battery effectively pushes a loop around in the field.
b. current exerts a force on the loop, causing it to rotate.
c. magnetic field exerts forces on moving electrons in the loop.
d. magnet attracts stationary electrons in the wire.
e. none of the above
128. Earth's magnetic field is most likely due to
a. millions of small magnets buried in Earth.
b. a magnetized solid inner core of Earth.
c. convection currents in the molten part of Earth's interior.
d. the rotation of Earth acting on all of Earth's electrons.
e. none of the above
129. The force on an electron moving in a magnetic field will be the largest when its direction
a. is at an angle other than 90 degrees to the magnetic field direction.
b. is perpendicular to the magnetic field direction.
c. is the same as the magnetic field direction.
d. is exactly opposite to the magnetic field direction.
e. none of the above
130. Magnetic field lines surrounding a magnet are conventionally drawn
a. from south to north.
b. from north to south.
c. either way.
131. A transformer transforms
a. magnetic field lines.
b. generators into motors.
c. voltage.
d. unsafe forms of energy into safe forms.
True/False
Indicate whether the sentence or statement is true or false.
132. Polarization occurs when waves vibrate in a single direction.
a. True
b. False
133. Light sometimes acts as a wave and sometimes as a particle.
a. True
b. False
134. The distance light travels in one year is called a light-year.
a. True
b. False
135. Material in an object that selectively absorbs colored light is called a pigment.
a. True
b. False
136. When you look at the image of a candle in a plane mirror, you see a real image.
a. True
b. False
137. A real image can be projected onto a screen.
a. True
b. False
138. The eye contains a converging lens that focuses light.
a. True
b. False
139. Nearsighted people can clearly see objects that are close to them.
a. True
b. False
140. A real image formed by a single converging lens is always upside down.
a. True
b. False
141. Light entering the eye focuses at the back of the eye on a layer of light-sensitive tissue at the back of the eye called
the retina.
a. True
b. False
142. Electrical forces are strong, but in comparison, gravitational forces are stronger.
a. True
b. False
143. The reason electrons are attracted to protons is that electrons and protons have the same amount of charge.
a. True
b. False
144. Charge flows from low potential to high potential.
a. True
b. False
145. In solid conductors, positive current is the flow of protons in the conductor.
a. True
b. False
146. Most of the electricity we buy through power companies is direct current.
a. True
b. False
147. When you turn on a light, electrons move at speeds near the speed of light in order to light up the light bulb.
a. True
b. False
148. When light bulbs are connected in series, all carry the same current regardless of their resistances.
a. True
b. False
149. Magnetic poles are similar to electric charges in that they both can repel and attract one another.
a. True
b. False
150. There is a magnetic field around a current-carrying wire.
a. True
b. False
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9. ANS:
STO:
10. ANS:
STO:
11. ANS:
STO:
12. ANS:
STO:
13. ANS:
STO:
14. ANS:
STO:
15. ANS:
STO:
16. ANS:
STO:
17. ANS:
STO:
18. ANS:
STO:
19. ANS:
STO:
20. ANS:
OBJ:
21. ANS:
STO:
22. ANS:
B
DIF:
Ph.1.l
A
DIF:
9.2
STO:
C
DIF:
Ph.1.f, Ph.1.g
D
DIF:
12.4
STO:
C
DIF:
Ph.1.e, Ph.1.m
E
DIF:
Ph.1.e, Ph.1.m
D
DIF:
Ph.1.m
A
DIF:
Ph.1.f
B
DIF:
Ph.4.f
D
DIF:
Ph.4.f
E
DIF:
Ph.4.f
E
DIF:
Ph.4.b
A
DIF:
Ph.4.b
D
DIF:
Ph.4.f
C
DIF:
Ph.4.f
C
DIF:
Ph.4.f
A
DIF:
Ph.4.f
D
DIF:
Ph.4.f
B
DIF:
Ph.4.f
C
DIF:
25.9
STO:
C
DIF:
Ph.4.f
C
DIF:
2
REF: p. 123
2
Ph.1.l
2
REF: p. 123, p. 124
REF: p. 127
OBJ: 9.2
OBJ: 9.3
2
REF: p. 172, p. 173
Ph.1.e, Ph.1.m
3
REF: p. 172
OBJ: 12.4
1
REF: p. 183
OBJ: 13.1
3
REF: p. 186
OBJ: 13.3
2
REF: p. 200
OBJ: 14.2
2
REF: p. 374
OBJ: 25.2
1
REF: p. 372
OBJ: 25.1
1
REF: p. 374
OBJ: 25.2
1
REF: p. 378
OBJ: 25.5
1
REF: p. 379
OBJ: 25.6
2
REF: p. 379
OBJ: 25.7
1
REF: p. 383
OBJ: 25.9
3
REF: p. 383
OBJ: 25.9
3
REF: p. 375
OBJ: 25.2
2
REF: p. 385
OBJ: 25.11
1
REF: p. 385
OBJ: 25.11
2
Ph.4.f
2
REF: p. 382, p. 383
REF: p. 375
OBJ: 25.2
2
REF: p. 377
OBJ: 25.4
STO:
23. ANS:
STO:
24. ANS:
STO:
25. ANS:
OBJ:
26. ANS:
STO:
27. ANS:
STO:
28. ANS:
OBJ:
29. ANS:
STO:
30. ANS:
STO:
31. ANS:
STO:
32. ANS:
STO:
33. ANS:
STO:
34. ANS:
STO:
35. ANS:
STO:
36. ANS:
STO:
37. ANS:
OBJ:
38. ANS:
STO:
39. ANS:
STO:
40. ANS:
STO:
41. ANS:
STO:
42. ANS:
OBJ:
43. ANS:
OBJ:
44. ANS:
OBJ:
45. ANS:
STO:
46. ANS:
Ph.4.c, Ph.4.d
C
Ph.4.f
C
Ph.4.d
B
26.1
C
Ph.4.d
D
Ph.4.f
E
26.8
A
Ph.4.f
A
Ph.4.d
A
Ph.4.b
B
Ph.4.e
C
Ph.4.e
C
Ph.4.e
D
Ph.4.e, Ph.4.f
A
Ph.4.e
B
27.2
A
Ph.4.e, Ph.4.f
A
Ph.4.e
A
Ph.4.e, Ph.4.f
B
Ph.4.b
A
27.7
E
28.2
D
28.4
D
Ph.4.c, Ph.4.f
A
DIF: 2
REF: p. 374
OBJ: 25.2
DIF: 2
REF: p. 393
OBJ: 26.4
DIF: 1
STO: Ph.4.d
DIF: 1
REF: p. 390, p. 391
REF: p. 392
OBJ: 26.3
DIF: 1
REF: p. 395
OBJ: 26.8
DIF: 2
STO: Ph.4.f
DIF: 1
REF: p. 395, p. 396
REF: p. 398
OBJ: 26.10
DIF: 2
REF: p. 393
OBJ: 26.4
DIF: 1
REF: p. 414
OBJ: 27.7
DIF: 2
REF: p. 407
OBJ: 27.2
DIF: 2
REF: p. 408
OBJ: 27.3
DIF: 2
REF: p. 408
OBJ: 27.3
DIF: 2
REF: p. 409
OBJ: 27.4
DIF: 2
REF: p. 408
OBJ: 27.3
DIF: 2
STO: Ph.4.e
DIF: 2
REF: p. 406, p. 407
REF: p. 410
OBJ: 27.4
DIF: 2
REF: p. 408
OBJ: 27.3
DIF: 2
REF: p. 409
OBJ: 27.4
DIF: 2
REF: p. 414
OBJ: 27.7
DIF:
STO:
DIF:
STO:
DIF:
STO:
DIF:
REF: p. 414, p. 415
2
Ph.4.b
2
Ph.4.e
2
Ph.4.e
2
DIF: 2
REF: p. 422, p. 423
REF: p. 425, p. 426
REF: p. 432
OBJ: 28.8
REF: p. 421
OBJ: 28.1
STO:
47. ANS:
OBJ:
48. ANS:
STO:
49. ANS:
STO:
50. ANS:
OBJ:
51. ANS:
STO:
52. ANS:
STO:
53. ANS:
STO:
54. ANS:
STO:
55. ANS:
STO:
56. ANS:
STO:
57. ANS:
STO:
58. ANS:
STO:
59. ANS:
STO:
60. ANS:
OBJ:
61. ANS:
STO:
62. ANS:
OBJ:
63. ANS:
64. ANS:
65. ANS:
66. ANS:
67. ANS:
68. ANS:
STO:
69. ANS:
STO:
70. ANS:
STO:
71. ANS:
STO:
72. ANS:
STO:
Ph.4.e
B
DIF:
28.2
STO:
C
DIF:
Ph.4.e
D
DIF:
Ph.4.c, Ph.4.f
D
DIF:
28.9
STO:
A
DIF:
Ph.4.c
A
DIF:
Ph.4.f
D
DIF:
Ph.4.c, Ph.4.f
A
DIF:
Ph.4.f
A
DIF:
Ph.4.c, Ph.4.f
A
DIF:
Ph.4.c, Ph.4.f
A
DIF:
Ph.4.f
B
DIF:
Ph.4.c, Ph.4.f
A
DIF:
Ph.4.c, Ph.4.e, Ph.4.f
B
DIF:
29.10
STO:
A
DIF:
Ph.4.f
E
DIF:
30.2
C
DIF:
A
DIF:
A
DIF:
A
DIF:
C
DIF:
E
DIF:
Ph.4.c, Ph.4.f
C
DIF:
Ph.4.c, Ph.4.f
C
DIF:
Ph.4.c, Ph.4.f
B
DIF:
Ph.5.e
E
DIF:
Ph.5.e
2
Ph.4.e
3
REF: p. 422, p. 423
REF: p. 423
OBJ: 28.2
2
REF: p. 432
OBJ: 28.8
2
REF: p. 433, p. 434
Ph.4.c, Ph.4.f
1
REF: p. 427
OBJ: 28.5
1
REF: p. 444
OBJ: 29.1
2
REF: p. 445
OBJ: 29.3
1
REF: p. 447
OBJ: 29.4
1
REF: p. 448
OBJ: 29.6
1
REF: p. 457
OBJ: 29.12
2
REF: p. 451
OBJ: 29.8
1
REF: p. 452
OBJ: 29.9
2
REF: p. 454
OBJ: 29.10
2
REF: p. 454, p. 455
Ph.4.c, Ph.4.e, Ph.4.f
2
REF: p. 451
OBJ: 29.8
2
REF: p. 465, p. 466
2
1
2
2
2
1
REF:
REF:
REF:
REF:
REF:
REF:
1
REF: p. 486
OBJ: 31.3
1
REF: p. 487
OBJ: 31.3
1
REF: p. 501
OBJ: 32.1
1
REF: p. 501
OBJ: 32.1
p. 466
p. 467
p. 463
p. 474
p. 473
p. 486
OBJ:
OBJ:
OBJ:
OBJ:
OBJ:
OBJ:
30.2
30.3
30.1
30.6
30.6
31.3
73. ANS:
STO:
74. ANS:
STO:
75. ANS:
STO:
76. ANS:
STO:
77. ANS:
STO:
78. ANS:
STO:
79. ANS:
80. ANS:
OBJ:
81. ANS:
82. ANS:
83. ANS:
STO:
84. ANS:
STO:
85. ANS:
STO:
86. ANS:
STO:
87. ANS:
STO:
88. ANS:
STO:
89. ANS:
STO:
90. ANS:
STO:
91. ANS:
STO:
92. ANS:
STO:
93. ANS:
STO:
94. ANS:
STO:
95. ANS:
STO:
96. ANS:
STO:
97. ANS:
STO:
98. ANS:
B
DIF: 1
Ph.5.e
A
DIF: 2
Ph.5.e
B
DIF: 2
Ph.1.m
D
DIF: 2
Ph.1.m
D
DIF: 3
Ph.1.m
B
DIF: 2
Ph.1.m
D
DIF: 1
D
DIF: 2
32.5, 32.6
STO: Ph.5.e
D
DIF: 2
A
DIF: 2
A
DIF: 2
Ph.5.e
E
DIF: 3
Ph.1.m
B
DIF: 3
Ph.1.m
C
DIF: 3
Ph.1.m
B
DIF: 2
Ph.5.l
C
DIF: 2
Ph.5.l
A
DIF: 2
Ph.5.j, Ph.5.n
B
DIF: 3
Ph.5.e, Ph.5.k, Ph.5.l, Ph.5.o
A
DIF: 2
Ph.5.j, Ph.5.n
B
DIF: 1
Ph.5.a, Ph.5.e
B
DIF: 2
Ph.5.a, Ph.5.c
B
DIF: 1
Ph.5.a, Ph.5.e
D
DIF: 2
Ph.5.c
B
DIF: 2
Ph.5.c
C
DIF: 2
Ph.5.m
B
DIF: 2
REF: p. 501
OBJ: 32.1
REF: p. 501
OBJ: 32.1
REF: p. 505
OBJ: 32.3
REF: p. 505
OBJ: 32.3
REF: p. 505
OBJ: 32.3
REF: p. 506
OBJ: 32.3
REF: p. 508
OBJ: 32.4
REF: p. 509, p. 510
REF: p. 508
REF: p. 508
REF: p. 512
OBJ: 32.4
OBJ: 32.4
OBJ: 32.6
REF: p. 505
OBJ: 32.3
REF: p. 505
OBJ: 32.3
REF: p. 505
OBJ: 32.3
REF: p. 518
OBJ: 33.1
REF: p. 518
OBJ: 33.1
REF: p. 519
OBJ: 33.2
REF: p. 524
OBJ: 33.4
REF: p. 519
OBJ: 33.2
REF: p. 532
OBJ: 34.2
REF: p. 541
OBJ: 34.9
REF: p. 533
OBJ: 34.2
REF: p. 534
OBJ: 34.4
REF: p. 534
OBJ: 34.4
REF: p. 538
OBJ: 34.6
REF: p. 539
OBJ: 34.7
STO:
99. ANS:
STO:
100. ANS:
STO:
101. ANS:
STO:
102. ANS:
STO:
103. ANS:
STO:
104. ANS:
STO:
105. ANS:
STO:
106. ANS:
STO:
107. ANS:
STO:
108. ANS:
STO:
109. ANS:
STO:
110. ANS:
STO:
111. ANS:
STO:
112. ANS:
STO:
113. ANS:
STO:
114. ANS:
STO:
115. ANS:
STO:
116. ANS:
STO:
117. ANS:
STO:
118. ANS:
STO:
119. ANS:
STO:
120. ANS:
STO:
121. ANS:
STO:
122. ANS:
Ph.5.a, Ph.5.c
A
DIF:
Ph.5.a, Ph.5.c
B
DIF:
Ph.5.a, Ph.5.c
E
DIF:
Ph.5.a, Ph.5.c
B
DIF:
Ph.5.b
C
DIF:
Ph.5.b
E
DIF:
Ph.5.b
C
DIF:
Ph.5.a, Ph.5.b, Ph.5.c
D
DIF:
Ph.5.a, Ph.5.b, Ph.5.c
D
DIF:
Ph.5.a, Ph.5.b, Ph.5.c
B
DIF:
Ph.5.a
A
DIF:
Ph.5.a
B
DIF:
Ph.5.a
A
DIF:
Ph.5.a
C
DIF:
Ph.5.a
A
DIF:
Ph.5.a
A
DIF:
Ph.5.a
C
DIF:
Ph.5.a
B
DIF:
Ph.5.a
C
DIF:
Ph.5.a
B
DIF:
Ph.5.c
B
DIF:
Ph.5.c
A
DIF:
Ph.5.e, Ph.5.f
C
DIF:
Ph.5.e, Ph.5.f
B
DIF:
1
REF: p. 539
OBJ: 34.7
2
REF: p. 543
OBJ: 34.10
1
REF: p. 539
OBJ: 34.7
2
REF: p. 535
OBJ: 34.5
2
REF: p. 535
OBJ: 34.5
2
REF: p. 535
OBJ: 34.5
2
REF: p. 543
OBJ: 34.11
2
REF: p. 543
OBJ: 34.11
3
REF: p. 543
OBJ: 34.11
2
REF: p. 549
OBJ: 35.1
1
REF: p. 549
OBJ: 35.2
2
REF: p. 551
OBJ: 35.3
2
REF: p. 552
OBJ: 35.4
2
REF: p. 551
OBJ: 35.3
2
REF: p. 552
OBJ: 35.4
2
REF: p. 550
OBJ: 35.3
2
REF: p. 552
OBJ: 35.4
2
REF: p. 552
OBJ: 35.4
3
REF: p. 552
OBJ: 35.4
2
REF: p. 556
OBJ: 35.6
2
REF: p. 556
OBJ: 35.6
2
REF: p. 565
OBJ: 36.3
2
REF: p. 565
OBJ: 36.3
1
REF: p. 563
OBJ: 36.1
STO:
123. ANS:
STO:
124. ANS:
STO:
125. ANS:
STO:
126. ANS:
STO:
127. ANS:
STO:
128. ANS:
STO:
129. ANS:
STO:
130. ANS:
STO:
131. ANS:
STO:
Ph.5.e, Ph.5.f
A
Ph.5.e, Ph.5.f
A
Ph.5.f
C
Ph.5.f
E
Ph.5.g
C
Ph.5.k
C
Ph.5.f
B
Ph.5.n
B
Ph.5.f
C
Ph.5.a, Ph.5.b
DIF: 1
REF: p. 564
OBJ: 36.1
DIF: 1
REF: p. 565
OBJ: 36.2
DIF: 1
REF: p. 566
OBJ: 36.4
DIF: 2
REF: p. 568
OBJ: 36.5
DIF: 2
REF: p. 572
OBJ: 36.8
DIF: 2
REF: p. 574
OBJ: 36.9
DIF: 3
REF: p. 570
OBJ: 36.6
DIF: 2
REF: p. 565
OBJ: 36.2
DIF: 2
REF: p. 584
OBJ: 37.5
DIF: 1
REF: p. 414
OBJ: 27.7
DIF: 2
REF: p. 405
OBJ: 27.1
DIF: 1
REF: p. 407
OBJ: 27.2
DIF: 1
REF: p. 424
OBJ: 28.3
DIF: 2
REF: p. 445
OBJ: 29.3
DIF:
DIF:
DIF:
DIF:
DIF:
DIF:
REF:
REF:
REF:
REF:
REF:
REF:
OBJ:
OBJ:
OBJ:
OBJ:
OBJ:
OBJ:
TRUE/FALSE
132. ANS:
STO:
133. ANS:
STO:
134. ANS:
STO:
135. ANS:
STO:
136. ANS:
STO:
137. ANS:
138. ANS:
139. ANS:
140. ANS:
141. ANS:
142. ANS:
STO:
143. ANS:
STO:
144. ANS:
STO:
145. ANS:
STO:
146. ANS:
STO:
147. ANS:
T
Ph.4.b
T
Ph.4.e
T
Ph.4.e
T
Ph.4.f
F
Ph.4.c, Ph.4.f
T
T
T
T
T
F
Ph.1.m
F
Ph.5.e
F
Ph.5.c
F
Ph.5.a, Ph.5.e
F
Ph.5.a, Ph.5.c
F
1
1
2
1
1
2
p. 465
p. 473
p. 475
p. 465
p. 473
p. 505
30.2
30.6
30.7
30.2
30.6
32.3
DIF: 1
REF: p. 501
OBJ: 32.1
DIF: 2
REF: p. 534
OBJ: 34.3
DIF: 2
REF: p. 533
OBJ: 34.2
DIF: 2
REF: p. 539
OBJ: 34.7
DIF: 2
REF: p. 541
OBJ: 34.9
STO:
148. ANS:
STO:
149. ANS:
OBJ:
150. ANS:
STO:
Ph.5.a, Ph.5.c
T
Ph.5.a
T
36.1
T
Ph.5.g
DIF: 2
REF: p. 551
OBJ: 35.3
DIF: 1
REF: p. 563, p. 564
STO: Ph.5.e, Ph.5.f
DIF: 2
REF: p. 568
OBJ: 36.5