TEST BANK FOR Electric Circuits 8th Edition By Nilsson, J.W. and Riedel, S
Exam (elaborations)
TEST BANK FOR Electric Circuits 8th Edition By Nilsson, J.W. and Riedel, S (Solution Manual)
28 views 0 purchase
Course
TEST BANK FOR Electric Circuits 8th Edition By Nilsson, J.W. and Riedel, S
Institution
Harvard University
Exam (elaborations) TEST BANK FOR Electric Circuits 8th Edition By Nilsson, J.W. and Riedel, S (Solution Manual) Circuit Variables Assessment Problems AP 1.1 To solve this problem we use a product of ratios to change units from dollars/year to dollars/millisecond. We begin by expressing $10 billion...
TEST BANK FOR Electric Circuits 8th Edition By Nilsson, J.W. and Riedel, S
All documents for this subject (2)
Seller
Follow
Exceldemics
Reviews received
Content preview
, Circuit Variables
1
Assessment Problems
AP 1.1 To solve this problem we use a product of ratios to change units from dollars/year to
dollars/millisecond. We begin by expressing $10 billion in scientific notation:
$100 billion = $100 × 109
Now we determine the number of milliseconds in one year, again using a product of
ratios:
1 year 1 day 1 hour 1 min 1 sec 1 year
· · · · =
365.25 days 24 hours 60 mins 60 secs 1000 ms 31.5576 × 109 ms
Now we can convert from dollars/year to dollars/millisecond, again with a product
of ratios:
$100 × 109 1 year 100
· = = $3.17/ms
1 year 31.5576 × 109 ms 31.5576
AP 1.2 First, we recognize that 1 ns = 10−9 s. The question then asks how far a signal will
travel in 10−9 s if it is traveling at 80% of the speed of light. Remember that the
speed of light c = 3 × 108 m/s. Therefore, 80% of c is (0.8)(3 × 108 ) = 2.4 × 108
m/s. Now, we use a product of ratios to convert from meters/second to
inches/nanosecond:
2.4 × 108 m 1s 100 cm 1 in (2.4 × 108 )(100) 9.45 in
· 9 · · = =
1s 10 ns 1m 2.54 cm (109 )(2.54) 1 ns
Thus, a signal traveling at 80% of the speed of light will travel 9.45 in a
nanosecond.
1–1
, 1–2 CHAPTER 1. Circuit Variables
AP 1.3 Remember from Eq. (1.2), current is the time rate of change of charge, or i = dq
dt
In
this problem, we are given the current and asked to find the total charge. To do this,
we must integrate Eq. (1.2) to find an expression for charge in terms of current:
t
q(t) = i(x) dx
0
We are given the expression for current, i, which can be substituted into the above
expression. To find the total charge, we let t → ∞ in the integral. Thus we have
∞
−5000x 20 −5000x ∞ 20
qtotal = 20e dx = e = (e∞ − e0 )
0 −5000 0 −5000
20 20
= (0 − 1) = = 0.004 C = 4000 µC
−5000 5000
AP 1.4 Recall from Eq. (1.2) that current is the time rate of change of charge, or i = dq
dt
. In
this problem we are given an expression for the charge, and asked to find the
maximum current. First we will find an expression for the current using Eq. (1.2):
dq d 1 t 1
i= = 2
− + 2 e−αt
dt dt α α α
d 1 d t −αt d 1 −αt
= − e − e
dt α2 dt α dt α2
1 −αt t 1
= 0− e − α e−αt − −α 2 e−αt
α α α
1 1 −αt
= − +t+ e
α α
= te−αt
Now that we have an expression for the current, we can find the maximum value of
the current by setting the first derivative of the current to zero and solving for t:
di d
= (te−αt ) = e−αt + t(−α)eαt = (1 − αt)e−αt = 0
dt dt
Since e−αt never equals 0 for a finite value of t, the expression equals 0 only when
(1 − αt) = 0. Thus, t = 1/α will cause the current to be maximum. For this value
of t, the current is
1 −α/α 1
i= e = e−1
α α
Remember in the problem statement, α = 0.03679. Using this value for α,
1
i= e−1 ∼
= 10 A
0.03679
, Problems 1–3
AP 1.5 Start by drawing a picture of the circuit described in the problem statement:
Also sketch the four figures from Fig. 1.6:
[a] Now we have to match the voltage and current shown in the first figure with the
polarities shown in Fig. 1.6. Remember that 4A of current entering Terminal 2
is the same as 4A of current leaving Terminal 1. We get
(a) v = −20 V, i = −4 A; (b) v = −20 V, i = 4A
(c) v = 20 V, i = −4 A; (d) v = 20 V, i = 4A
[b] Using the reference system in Fig. 1.6(a) and the passive sign convention,
p = vi = (−20)(−4) = 80 W. Since the power is greater than 0, the box is
absorbing power.
[c] From the calculation in part (b), the box is absorbing 80 W.
AP 1.6 Applying the passive sign convention to the power equation using the voltage and
current polarities shown in Fig. 1.5, p = vi. From Eq. (1.3), we know that power is
the time rate of change of energy, or p = dw
dt
. If we know the power, we can find the
energy by integrating Eq. (1.3). To begin, find the expression for power:
p = vi = (10,000e−5000t )(20e−5000t ) = 200,000e−10,000t = 2 × 105 e−10,000t W
Now find the expression for energy by integrating Eq. (1.3):
t
w(t) = p(x) dx
0
The benefits of buying summaries with Stuvia:
Guaranteed quality through customer reviews
Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.
Quick and easy check-out
You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.
Focus on what matters
Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!
Frequently asked questions
What do I get when I buy this document?
You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.
Satisfaction guarantee: how does it work?
Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.
Who am I buying these notes from?
Stuvia is a marketplace, so you are not buying this document from us, but from seller Exceldemics. Stuvia facilitates payment to the seller.
Will I be stuck with a subscription?
No, you only buy these notes for $17.49. You're not tied to anything after your purchase.