Exam (elaborations) TEST BANK FOR Giancoli's Physics Volume 1 6th Edition by Joe Boyle (Student Study Guide With Selected Solutions)
CHAPTER 1:
... [Show More] Introduction, Measurement, Estimating
Answers to Questions
1. (a) Fundamental standards should be accessible, invariable, indestructible, and reproducible. A
particular person’s foot would not be very accessible, since the person could not be at more than
one place at a time. The standard would be somewhat invariable if the person were an adult, but
even then, due to swelling or injury, the length of the standard foot could change. The standard
would not be indestructible – the foot would not last forever. The standard could be
reproducible – tracings or plaster casts could be made as secondary standards.
(b) If any person’s foot were to be used as a standard, “standard” would vary significantly
depending on the person whose foot happened to be used most recently for a measurement. The
standard would be very accessible, because wherever a measurement was needed, it would be
very easy to find someone with feet. The standard would be extremely variable – perhaps by a
factor of 2. That also renders the standard as not reproducible, because there could be many
reproductions that were quite different from each other. The standard would be almost
indestructible in that there is essentially a limitless supply of feet to be used.
2. There are various ways to alter the signs. The number of meters could be expressed in one
significant figure, as “900 m (3000 ft)”. Or, the number of feet could be expressed with the same
precision as the number of meters, as “914 m (2999 ft)”. The signs could also be moved to different
locations, where the number of meters was more exact. For example, if a sign was placed where the
elevation was really 1000 m to the nearest meter, then the sign could read “1000 m (3280 ft)”.
3. Including more digits in an answer does not necessarily increase its accuracy. The accuracy of an
answer is determined by the accuracy of the physical measurement on which the answer is based. If
you draw a circle, measure its diameter to be 168 mm and its circumference to be 527 mm, their
quotient, representing , is 3.. The last seven digits are meaningless – they imply a
greater accuracy than is possible with the measurements.
4. The problem is that the precision of the two measurements are quite different. It would be more
appropriate to give the metric distance as 11 km, so that the numbers are given to about the same
precision (nearest mile or nearest km).
5. A measurement must be measured against a scale, and the units provide that scale. Units must be
specified or the answer is meaningless – the answer could mean a variety of quantities, and could be
interpreted in a variety of ways. Some units are understood, such as when you ask someone how old
they are. You assume their answer is in years. But if you ask someone how long it will be until they
are done with their task, and they answer “five”, does that mean five minutes or five hours or five
days? If you are in an international airport, and you ask the price of some object, what does the
answer “ten” mean? Ten dollars, or ten pounds, or ten marks, or ten euros?
6. If the jar is rectangular, for example, you could count the number of marbles along each dimension,
and then multiply those three numbers together for an estimate of the total number of marbles. If the
jar is cylindrical, you could count the marbles in one cross section, and then multiply by the number
of layers of marbles. Another approach would be to estimate the volume of one marble. If we
assume that the marbles are stacked such that their centers are all on vertical and horizontal lines,
then each marble would require a cube of edge 2R, or a volume of 8R3, where R is the radius of a
marble. The number of marbles would then be the volume of the container divided by 8R3.
Chapter 1 Introduction, Measurement, Estimating
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currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
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7. The result should be written as 8.32 cm. The factor of 2 used to convert radius to diameter is exact –
it has no uncertainty, and so does not change the number of significant figures.
8. o sin 30.0 0.500
9. Since the size of large eggs can vary by 10%, the random large egg used in a recipe has a size with
an uncertainty of about 5%. Thus the amount of the other ingredients can also vary by about 5%
and not adversely affect the recipe.
10. In estimating the number of car mechanics, the assumptions and estimates needed are:
the population of the city
the number of cars per person in the city
the number of cars that a mechanic can repair in a day
the number of days that a mechanic works in a year
the number of times that a car is taken to a mechanic, per year
We estimate that there is 1 car for every 2 people, that a mechanic can repair 3 cars per day, that a
mechanic works 250 days a year, and that a car needs to be repaired twice per year.
(a) For San Francisco, we estimate the population at one million people. The number of mechanics
is found by the following calculation.
6
repairs
2
1 car year 1 yr 1 mechanic
1 10 people 1300 mechanics
2 people 1 car 250 workdays repairs 3
workday
(b) For Upland, Indiana, the population is about 4000. The number of mechanics is found by a
similar calculation, and would be 5 mechanics . There are actually two repair shops in Upland,
employing a total of 6 mechanics.
Solutions to Problems
1. (a) 10 14 billion years 1.4 10 years
(b) 10 7 17 1.4 10 y 3.156 10 s 1 y 4.4 10 s
2. (a) 214 3 significant figures
(b) 81.60 4 significant figures
(c) 7.03 3 significant figures
(d) 0.03 1 significant figure
(e) 0.0086 2 significant figures
(f) 3236 4 significant figures
(g) 8700 2 significant figures
Giancoli Physics: Principles with Applications, 6th Edition
© 2005 Pearson Education, Inc., Upper Saddle River, NJ. All rights reserved. This material is protected under all copyright laws as they
currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
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3. (a) 0 1.156 1.156 10
(b) 1 21.8 2.18 10
(c) 3 0.0068 6.8 10
(d) 1 27.635 2.7635 10
(e) 1 0.219 2.19 10
(f) 2 444 4.44 10
4. (a) 4 8.69 10 86,900
(b) 3 9.1 10 9,100
(c) 1 8.8 10 0.88
(d) 2 4.76 10 476
(e) 5 3.62 10 0.
5. The uncertainty is taken to be 0.01 m.
0.01 m
% uncertainty 100% 1%
1.57 m
6.
0.25 m
% uncertainty 100% 6.6%
3.76 m
7. (a)
0.2 s
% uncertainty 100% 4%
5 s
(b)
0.2 s
% uncertainty 100% 0.4%
50 s
(c)
0.2 s
% uncertainty 100% 0.07%
300 s
8. To add values with significant figures, adjust all values to be added so that their exponents are all the
same.
3 4 6 3 3 3 3
3 5
9.2 10 s 8.3 10 s 0.008 10 s 9.2 10 s 83 10 s 8 10 s 9.2 83 8 10 s
100 10 s 1.00 10 s
When adding, keep the least accurate value, and so keep to the “ones” place in the parentheses.
9. 2 1 2.079 10 m 0.082 10 1.7 m . When multiplying, the result should have as many digits as
the number with the least number of significant digits used in the calculation.
10. To find the approximate uncertainty in the area, calculate the area for the specified radius, the
minimum radius, and the maximum radius. Subtract the extreme areas. The uncertainty in the area
is then half this variation in area. The uncertainty in the radius is assumed to be 0.1 104cm .
Chapter 1 Introduction, Measurement, Estimating
© 2005 Pearson Education, Inc., Upper Saddle River, NJ. All rights reserved. This material is protected under all copyright laws as they
currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
4
2 4 2 9 2
specified specified
2 4 2 9 2
min min
2 4 2 9 2
max max
1 1 9 2 9 2 9 2
2 max min 2
3.8 10 cm 4.5 10 cm
3.7 10 cm 4.30 10 cm
3.9 10 cm 4.78 10 cm
4.78 10 cm 4.30 10 cm 0.24 10 cm
A r
A r
A r
A A A
Thus the area should be quoted as 9 2 A 4.5 0.2 10 cm
11. To find the approximate uncertainty in the volume, calculate the volume for the specified radius, the
minimum radius, and the maximum radius. Subtract the extreme volumes. The uncertainty in the
volume is then half this variation in volume.
4 3 4 3 1 3
specified 3 specified 3
4 3 4 3 1 3
min 3 min 3
4 3 4 3 1 3
max 3 max 3
1 1 1 3 1 3 1 3
2 max min 2
2.86 m 9.80 10 m
2.77 m 8.903 10 m
2.95 m 10.754 10 m
10.754 10 m 8.903 10 m 0.926 10 m
V r
V r
V r
V V V
The percent uncertainty is
1 3
1 3
specified
0.923 10 m
100 0.09444 9%
9.80 10 m
V
V
12. (a) 286.6 mm 3 286.6 10 m 0.286 6 m
(b) 85 V 6 85 10 V 0.000 085 V
(c) 760 mg 6 760 10 kg 0.000 760 kg (if last zero is significant)
(d) 60.0 ps 12 60.0 10 s 0.000 000 000 0600 s
(e) 22.5 fm 15 22.5 10 m 0.000 000 000 000 022 5 m
(f) 2.50 gigavolts 9 2.5 10 volts 2,500, 000,000 volts
13. (a) 6 1 10 volts 1 megavolt 1 Mvolt
(b) 6 2 10 meters 2 micrometers 2 m
(c) 3 6 10 days 6 kilodays 6 kdays
(d) 2 18 10 bucks 18 hectobucks 18 hbucks
(e) 9 8 10 pieces 8 nanopieces 8 npieces
14. (a) Assuming a height of 5 feet 10 inches, then 5'10" 70 in 1 m 39.37 in 1.8 m
(b) Assuming a weight of 165 lbs, then 165 lbs 0.456 kg 1 lb 75.2 kg
Technically, pounds and mass measure two separate properties. To make this conversion, we
have to assume that we are at a location where the acceleration due to gravity is 9.8 m/s2.
Giancoli Physics: Principles with Applications, 6th Edition
© 2005 Pearson Education, Inc., Upper Saddle River, NJ. All rights reserved. This material is protected under all copyright laws as they
currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
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15. (a) 6 11 93 million miles 93 10 miles 1610 m 1 mile 1.5 10 m
(b) 11 9 1.5 10 m 150 10 m 150 gigameters or 11 12 1.5 10 m 0.15 10 m 0.15 terameters
16. (a) 2 2 2 2 1 ft 1 ft 1 yd 3 ft 0.111 yd
(b) 2 2 2 2 1 m 1 m 3.28 ft 1 m 10.8 ft
17. Use the speed of the airplane to convert the travel distance into a time.
1 h 3600 s
1.00 km 3.8 s
950 km 1 h
18. (a) 10 10 9 1.0 10 m 1.0 10 m 39.37 in 1 m 3.9 10 in
(b) 8
10
1 m 1 atom
1.0 cm 1.0 10 atoms
100 cm 1.0 10 m
19. To add values with significant figures, adjust all values to be added so that their units are all the
same.
5 1.80 m 142.5 cm 5.34 10 m 1.80 m 1.425 m 0.534 m 3.759 m 3.76 m
When adding, the final result is to be no more accurate than the least accurate number used.
In this case, that is the first measurement, which is accurate to the hundredths place.
20. (a)
0.621 mi
1k h 0.621mi h
1 km
(b)
3.28 ft
1m s 3.28ft s
1 m
(c)
1000 m 1 h
1km h 0.278m s
1 km 3600 s
21. One mile is 3 1.61 10 m . It is 110 m longer than a 1500-m race. The percentage difference is
110 m
100% 7.3%
1500 m
22. (a) 8 7 15 1.00 ly 2.998 10 m s 3.156 10 s 9.46 10 m
(b)
15
4
11
9.462 10 m 1 AU
1.00 ly 6.31 10 AU
1.00 ly 1.50 10 m
(c) 8
11
1 AU 3600 s
2.998 10 m s 7.20AU h
1.50 10 m 1 hr
Chapter 1 Introduction, Measurement, Estimating
© 2005 Pearson Education, Inc., Upper Saddle River, NJ. All rights reserved. This material is protected under all copyright laws as they
currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
6
23. The surface area of a sphere is found by 2 2 2 A 4 r 4 d 2 d .
(a)
2 6 2 13 2
Moon Moon A D 3.48 10 m 3.80 10 m
(b)
2 2 2 6 2
Earth Earth Earth Earth
2 6
Moon Moon Moon Moon
6.38 10 m
13.4
1.74 10 m
A D D R
A D D R
24. (a) 3 3 3 2800 2.8 10 1 10 10
(b) 2 3 3 4 86.30 10 8.630 10 10 10 10
(c) 3 3 2 0.0076 7.6 10 10 10 10
(d) 8 9 9 9 15.0 10 1.5 10 1 10 10
25. The textbook is approximately 20 cm deep and 4 cm wide. With books on both sides of a shelf, with
a little extra space, the shelf would need to be about 50 cm deep. If the aisle is 1.5 meter wide, then
about 1/4 of the floor space is covered by shelving. The number of books on a single shelf level is
then 1 2 4
4
1 book
3500m 8.75 10 books
0.25 m 0.04 m
. With 8 shelves of books, the total number
of books stored is as follows.
4 5 books
8.75 10 8 shelves 7 10 books
shelf level
.
26. The distance across the United States is about 3000 miles.
3000 mi 1 km 0.621 mi 1 hr 10 km 500 hr
Of course, it would take more time on the clock for the runner to run across the U.S. The runner
could obviously not run for 500 hours non-stop. If they could run for 5 hours a day, then it would
take about 100 days for them to cross the country.
27. An NCAA-regulation football field is 360 feet long (including the end zones) and 160 feet wide,
which is about 110 meters by 50 meters, or 5,500 m2. The mower has a cutting width of 0.5 meters.
Thus the distance to be walked is
2 Area 5500m
11000 m 11 km
width 0.5 m
d
At a speed of 1 km/hr, then it will take about 11 h to mow the field.
28. A commonly accepted measure is that a person should drink eight 8-oz. glasses of water each day.
That is about 2 quarts, or 2 liters of water per day. Then approximate the lifetime as 70 years.
4 70 y 365 d 1 y 2 L 1 d 5 10 L
29. Consider the body to be a cylinder, about 170 cm tall, and about 12 cm in cross-sectional radius (a
30-inch waist). The volume of a cylinder is given by the area of the cross section times the height.
2 2 4 3 4 3 V r h 12 cm 170 cm 9 10 cm 8 10 cm
Giancoli Physics: Principles with Applications, 6th Edition
© 2005 Pearson Education, Inc., Upper Saddle River, NJ. All rights reserved. This material is protected under all copyright laws as they
currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
7
30. Estimate one side of a house to be about 40 feet long, and about 10 feet high. Then the wall area of
that particular wall is 400 ft2. There would perhaps be 4 windows in that wall, each about 3 ft wide
and 4 feet tall, so 12 ft2 per window, or about 50 ft2 of window per wall. Thus the percentage of wall
area that is window area is
2
2
50 ft
100 12.5%
400 ft
. Thus a rough estimate would be 10% 15% of
the house’s outside wall area.
31. Assume that the tires last for 5 years, and so there is a tread wearing of 0.2 cm/year. Assume the
average tire has a radius of 40 cm, and a width of 10 cm. Thus the volume of rubber that is
becoming pollution each year from one tire is the surface area of the tire, times the thickness per year
that is wearing. Also assume that there are 150,000,000 automobiles in the country – approximately
one automobile for every two people. So the mass wear per year is given by
3
8
Mass Surface area Thickness wear
density of rubber # of tires
year tire year
2 0.4 m 0.1 m 0.002 m y 1200 kg m 600, 000, 000 tires
4 10 kg y
32. For the equation 3 v At Bt , the units of 3 At must be the same as the units of v . So the units of A
must be the same as the units of 3 v t , which would be 4 distance time . Also, the units of Bt must
be the same as the units of v . So the units of B must be the same as the units of v t , which would
be 2 distance time .
33. (a) The quantity 2 vt has units of 2 m s s m s , which do not match with the units of meters
for x. The quantity 2at has units 2 m s s m s , which also do not match with the units of
meters for x. Thus this equation cannot be correct .
(b) The quantity 0 v t has units of m s s m , and 1 2
2 at has units of 2 2 m s s m . Thus,
since each term has units of meters, this equation can be correct .
(c) The quantity 0 v t has units of m s s m , and 2 2at has units of 2 2 m s s m . Thus,
since each term has units of meters, this equation can be correct .
34. The percentage accuracy is 5
7
2 m
100% 1 10 %
2 10 m
. The distance of 20,000,000 m needs to
be distinguishable from 20,000,002 m, which means that 8 significant figures are needed in the
distance measurements.
35. Multiply the number of chips per wafer times the number of wafers that can be made fro a cylinder.
chips 1 wafer 300 mm chips
100 50,000
wafer 0.60 mm 1 cylinder cylinder
Chapter 1 Introduction, Measurement, Estimating
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currently exist. No portion of this material may be reproduced, in any form or by any means, without permission in writing from the
publisher.
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36. (a) # of seconds in 1.00 y:
7
7 3.156 10 s
1.00 y 1.00 y 3.16 10 s
1 y
(b) # of nanoseconds in 1.00 y:
7 9
16 3.156 10 s 1 10 ns
1.00 y 1.00 y 3.16 10 ns
1 y 1 s
(c) # of years in 1.00 s: 8
7
1 y
1.00 s 1.00 s 3.17 10 y
3.156 10 s
37. Assume that the alveoli are spherical, and that the volume of a typical human lung is about 2 liters,
which is .002 m3. The diameter can be found from the volume of a sphere, 4 3
3 r .
3
4 3 4 3
3 3
3 1/ 3 3
8 3 3 3 4
8
2
6
6 2 10
3 10 2 10 m m 2 10 m
6 3 10
d
r d
d
d
.
38.
4 2 2
4 2
10 m 3.28 ft 1 acre
1 hectare 1 hectare 2.69 acres
1 hectare 1 m 4 10 ft
39. (a)
15
12
27
10 kg 1 proton or neutron
10 protons or neutrons
1 bacterium 10 kg
(b)
17
10
27
10 kg 1 proton or neutron
10 protons or neutrons
1 DNA molecule 10 kg
(c)
2
29
27
10 kg 1 proton or neutron
10 protons or neutrons
1 human 10 kg
(d)
41
68
27
10 kg 1 proton or neutron
10 protons or neutrons
1 galaxy 10 kg
40. There are about 300,000,000 people in the United States. Assume that half of them have cars, that
they each drive 12,000 miles per year, and their cars get 20 miles per gallon of gasoline.
8 11 1 automobile 12,000 mi 1 gallon
3 10 people 1 10 gallons y
2 people 1 y 20 mi
41. Approximate the gumball machine as a rectangular box with a square cross-sectional area. In
counting gumballs across the bottom, there are about 10 in a row. Thus we estimate that one layer
contains about 100 gumballs. In counting vertically, we see that there are bout 15 rows. Thus we
estimate that there are about 1500 gumballs in the machine.
42. The volume of water used by the people can be calculated as follows:
3 3
4 3 3
5
1200 L day 365 day 1000 cm 1 km
4 10 people 4.4 10 km y
4 people 1 y 1 L 10 cm
Giancoli Physics: Principles with Applications, 6th Edition [Show Less]