Transcript Charges
1
기초 회로 이론
2014. 9. 1.
EMLAB
2
Contents
1. Basic concepts
2. Resistive circuits
3. Nodal and loop analysis techniques
4. Operational amplifiers
5. Additional analysis techniques
6. Capacitance and inductance
7. First and second order transient circuits
EMLAB
3
Circuits for modern electronic systems
Rack-mount computer
Super-computer
motherboard
Printed circuit board
Example : ATX power supply schematic
EMLAB
Electronic circuit design flow
4
System concept
Functional specification
Schematic circuit
Schematic simulation
BOM (Bill of materials)
PCB layout
Test and debugging
EMLAB
Typical electronic components
5
EMLAB
6
Basic concepts
EMLAB
Charges : electrons, nucleus
7
EMLAB
Friction charges
8
EMLAB
Generation of friction charges
9
Contact
Electrons “lost”
Separation
Electrons “gained”
EMLAB
10
Generation of charges : battery
Electrons(-) are absorbed.
(+) charges are generated
Electrons(-) are generated.
(+) charges are absorbed.
2NH 4 2e 2 NH3 H 2
Zn Zn 2 2e
Electrons are generated via
electro-chemical reaction.
EMLAB
Current
11
Steady state current (simple DC circuit)
The globe lights up due to the work done by electric current (moving charges).
EMLAB
12
Charge transport : microscopic view
Direction of current is
defined as that of positive
charges by convention.
Direction of current
EMLAB
13
Definition of current
S
q
I
dQ
dt
I
•
Current is electric charges in motion, and is defined as the rate of movement
of charges passing a given reference plane.
•
In the above figure, current can be measured by counting charges passing
through surface S in a unit time.
EMLAB
Charge transport mechanism: drift current
14
Positive charges
E
E
H
H
Charges are drifted by
electromagnetic waves.
Negative charges
EMLAB
15
Charge transport : diffusion current
Charges in a wire are moved by diffusion and electromagnetic laws.
Positive charges are plenty.
Diffusion
Charge movement by
diffusion
Negative charges are plenty.
Diffusion current is due to density
gradient independent of charges.
EMLAB
16
Electromotive force
Chemical battery
2NH 4 2e 2 NH3 H 2
Zn Zn 2 2e
(reduction)
(oxidation)
Electrons are generated via electro-chemical reaction.
EMLAB
AC(alternating current) generator
17
Electromotive force is generated by
changing magnetic flux (Faraday’s law).
EMLAB
18
Circuit elements
EMLAB
19
Circuit symbols
Independent sources
resistor
Dependent sources
capacitor
Ground (GND)
inductor
transformer
EMLAB
20
voltage sources
Dry cell
Lithium ion battery
Lead-acid battery
Switching power supply
DC power supply
Voltage source
i-v characteristics
EMLAB
Analogy between potential energy and voltage level
21
• Absolute value of voltage is not important.
• Only voltage difference has physical
meaning.
EMLAB
Ground symbol
22
• Ground (GND) is used to represent
voltage reference (0 V), arbitrarily.
EMLAB
current sources
23
current source
EMLAB
24
resistors
R (t ) i1 (t ) R1
EMLAB
25
capacitors
1
C (t )
C
t
i (t ) dt
0
EMLAB
i-v relation of a capacitor
26
t
1
C (t ) i (t ) dt
C0
i (t )
EMLAB
27
inductors
L (t ) L
di
dt
EMLAB
i-v relation of an inductor
L (t ) L
28
di
dt
(t )
EMLAB
29
Passive sign convention
p (t ) (t ) i (t )
i (t )
(t )
-
A circuit element absorbs power
when the current flows into the
positive terminal.
• For passive devices, the terminal into which current
comes becomes a positive terminal.
• For independent sources, current flows out of the
positive terminal.
EMLAB
30
Example
i (t )
Power is
generated
(t )
i (t )
(t )
Power is
absorbed
EMLAB
31
Example : passive sign convention
1.5V
0.1A
-0.1A
1.5V
Power = -0.1 * 1.5 = -0.15W (generation)
0.1A
1.5V
Power = 0.1 * 1.5 = 0.15W (absorption)
EMLAB
32
Power
Power is defined to be the energy dissipated per unit time.
p (t )
dW
dW dq
(t ) i (t )
dt
dq dt
p (t ) (t ) i (t )
W (t ) i (t )dt
EMLAB
Tellegen’s theorem
33
• The sum of the powers absorbed by all elements in an electrical
network is zero.
• Another statement of this theorem is that the power supplied in a
network is exactly equal to the power absorbed.
54W
-18W
-36W
-36W + 54W -18W = 0
EMLAB
Example 1.2
34
Given the two diagrams shown in Fig. 1.12, determine whether the element is
absorbing or supplying power and how much.
In Fig. 1.12a the power is P=(2 V)(–4 A)=–8 W. Therefore, the element is
supplying power.
In Fig. 1.12b, the power is P=(2 V)(–2 A)=–4 W. Therefore, the element is
supplying power.
EMLAB
Example 1.3
35
We wish to determine the unknown voltage or current in Fig. 1.13.
In Fig. 1.13a, a power of –20 W indicates that the element is delivering power.
Therefore, the current enters the negative terminal (terminal A), and from Eq. (1.3)
the voltage is 4 V. Thus, B is the positive terminal, A is the negative terminal, and
the voltage between them is 4 V.
In Fig 1.13b, a power of ±40 W indicates that the element is absorbing power and,
therefore, the current should enter the positive terminal B. The current thus has a
value of –8 A, as shown in the figure.
EMLAB
36
Example E1.4
Determine the power supplied by the dependent sources in Fig. E1.4.
(a) Power supplied = 80 W;
(b) power supplied = 160 W.
EMLAB
37
Example 1.7
Use Tellegen’s theorem to find the current Io in the network in Fig. 1.19.
-12 + 6Io - 108 - 30 - 32 + 176 = 0
Io = 1A
EMLAB
Example 1.8
38
The charge that enters the BOX is shown in Fig. 1.20. Calculate and sketch the
current flowing into and the power absorbed by the BOX between 0 and 10
milliseconds.
EMLAB