Download ch4_L1_i

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Wien bridge oscillator wikipedia , lookup

Topology (electrical circuits) wikipedia , lookup

Integrated circuit wikipedia , lookup

Power electronics wikipedia , lookup

Power MOSFET wikipedia , lookup

Valve RF amplifier wikipedia , lookup

Schmitt trigger wikipedia , lookup

Multimeter wikipedia , lookup

Index of electronics articles wikipedia , lookup

TRIAC wikipedia , lookup

Resistive opto-isolator wikipedia , lookup

Operational amplifier wikipedia , lookup

Switched-mode power supply wikipedia , lookup

Regenerative circuit wikipedia , lookup

Wilson current mirror wikipedia , lookup

Surge protector wikipedia , lookup

Current source wikipedia , lookup

Ohm's law wikipedia , lookup

Opto-isolator wikipedia , lookup

Rectiverter wikipedia , lookup

Current mirror wikipedia , lookup

RLC circuit wikipedia , lookup

Network analysis (electrical circuits) wikipedia , lookup

Transcript
Basic Electronics
A Sign in Penacook, New Hampshire
I, V Relations for R, L and C
(Table 4.1)
Element
Unit
Symbol
I(t)
V(t)
VI=const
Resistor
R
V(t)/R
RI(t)
RI
Capacitor
C
CdV(t)/dt
(1/C)∫I(t)dt
It/C
Inductor
L
(1/L)∫V(t)dt
LdI(t)/dt
0
R, L and C Combinations
Series:
R, L and 1/C add
Parallel:
1/R, 1/L and C add
Figures 4.5 and 4.6
Basic Electronics – R, C and L
Determine the DC potential difference across
2 inductors in parallel:
V(t) = LTdI/dt = [L1L2/(L1+L2)]dI/dt = 0
Basic Electronics – R, C and L
• For R, C, and L combination in series:
Potential Difference: V(t) = IR + (1/C)∫I(t)dt + LdI/dt
Current: I(t) = V/R = CdV/dt = (1/L)∫V(t)dt
• For R, C, and L combination in parallel:
Potential Difference:
V(t) = IR = (1/C)∫I(t)dt = LdI/dt
Current: I(t) = V/R + CdV/dt + (1/L)∫V(t)dt
Kirchhoff’s Laws
Node: a point in a circuit where any two of more elements meet
Loop: a closed path going from one circuit node back to itself
without passing through any intermediate node more
than once
Kirchhoff’s first (or current) law: at a circuit node, the current
flowing into the node equals the current flowing out
(charge is conserved)
Kirchhoff’s second (or voltage) law: around a circuit loop,
the sum of the voltages equal zero
(energy is conserved)
Example RLC Circuit
• Consider a RLC circuit used in a ‘Dynamic System
Response’ laboratory exercise, p 513
• Using Kirchoff’s Voltage Law, determine the expression
for this circuit that relates Eo to Ei.
R
• Ei, R, L and C are in series →
t

1
E i  RI  L dI

I(t )dt  0
dt
C
0
• Recall that I=dQ/dt →
Ei  L
d 2Q
dt 2
R
dQ
dt

Q
C
This is a linear,
2nd-order ODE,
See eq. H.47 p 514
• Now examine another loop and apply Kirchoff’s Voltage
Law again.
Eo  Q / C
• So, to find Eo, we must first find Q → we must integrate
the previous 2nd-order ODE.
• The solution is presented in Appendix H of the text, see
Eq H.48.