![LEVEL 3 ENGINEERING PRINCIPLES - DC CIRCUITS INFORMATION AND EQUATIONS
Voltage, Current, Power and Resistance
Subject Equation Variables and Units
Force between charged
particles (Coulombs Law) F =
keq1q2
r2
F = [attractive or repulsive] force in
Newtons (N)
*1
Ke = Coulomb’s constant (Nm2
C-2
)
*2
q = particle charge in Coulombs (C)
r = distance between particles (m)
I = Current in Amps (A)
Q = [total] charge in Coulombs (C)
t = time in seconds (s)
E = energy in Joules (J)
V = voltage in Volts (V)
R = resistance in Ohms (Ω)
ρ = resistivity in Ohm-meters (Ωm)
G = conductance in Siemens (S)
σ = conductivity in Siemens per meter
(S/m)
A = cross section area of conductor in
meters squared (m2
)
L = conductor length in meters (m)
P = power in Watts (W)
α = temperature coefficient of
resistance (K-1
)
θ = temperature in degrees Kelvin (K)
Current I =
Q
t
Energy E = QV
Resistance R = ρ
L
A
Conductance G = σ
A
L
Change in Resistance
(due to change in
temperature)
ΔR = RoαΔθ
Voltage
(Ohm’s Law)
V = IR
Power
P = Et
P = VI
P = I2
R
P =
V2
R
Useful Constant Values:
*1 Ke = 8.988 x 109 Nm2C-2
*2 qelectron = 1.603 x 10-19 C](https://image.slidesharecdn.com/level3engineeringprinciples-dccircuitsinfoandequations-180926150547/85/level-3-engineering-principles-dc-circuits-info-and-equations-1-320.jpg)
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Level 3 Engineering Principles - DC Circuits Equations Guide
- 1. LEVEL 3 ENGINEERING PRINCIPLES - DC CIRCUITS INFORMATION AND EQUATIONS Voltage, Current, Power and Resistance Subject Equation Variables and Units Force between charged particles (Coulombs Law) F = keq1q2 r2 F = [attractive or repulsive] force in Newtons (N) *1 Ke = Coulomb’s constant (Nm2 C-2 ) *2 q = particle charge in Coulombs (C) r = distance between particles (m) I = Current in Amps (A) Q = [total] charge in Coulombs (C) t = time in seconds (s) E = energy in Joules (J) V = voltage in Volts (V) R = resistance in Ohms (Ω) ρ = resistivity in Ohm-meters (Ωm) G = conductance in Siemens (S) σ = conductivity in Siemens per meter (S/m) A = cross section area of conductor in meters squared (m2 ) L = conductor length in meters (m) P = power in Watts (W) α = temperature coefficient of resistance (K-1 ) θ = temperature in degrees Kelvin (K) Current I = Q t Energy E = QV Resistance R = ρ L A Conductance G = σ A L Change in Resistance (due to change in temperature) ΔR = RoαΔθ Voltage (Ohm’s Law) V = IR Power P = Et P = VI P = I2 R P = V2 R Useful Constant Values: *1 Ke = 8.988 x 109 Nm2C-2 *2 qelectron = 1.603 x 10-19 C
- 2. Resistor Colour Coding Example: Blue, Yellow, Orange, Red 6, 4, 103, 2% 64,000Ω = 64kΩ ± 2% COLOUR BAND 1 (digit 1) BAND 2 (digit 2) BAND 3 (multiplier) BAND 4 (tolerance) Black 0 0 100 Brown 1 1 101 1% Red 2 2 102 2% Orange 3 3 103 Yellow 4 4 104 Green 5 5 105 Blue 6 6 106 Violet 7 7 107 Grey 8 8 108 White 9 9 109 Gold 10-1 5% Silver 10-2 10% None 20% 1 2 3 4
- 3. Resistors in Series and Parallel Subject Equation Variables and Units Resistors in Series: Total Resistance RT = R1 + R2 + R3 R = resistance in Ohms (Ω) V = voltage in Volts (V) I = Current in Amps (A) Supply Voltage Vs = V1 + V2 + V3 Supply Current Is = I1 = I2 = I3 Resistors in Parallel: Total Resistance 1 RT = 1 R1 + 1 R2 + 1 R3 Supply Voltage Vs = V1 = V2 = V3 Supply Current Is = I1 + I2 + I3
- 4. Capacitor Equations Subject Equation Variables and Units Electric Flux Density (on Capacitor Plates) D = Q a D = electric flux density in Coulombs per square meter (C/m2) Q = charge in Coulombs (C) a = capacitor common plate area in square meters (m2) C = capacitance in Farads (F) V = voltage in Volts (V) d = distance between capacitor plates in meters (m) *ε0 = absolute permittivity εr = relative permittivity E = energy stored in Joules (J) τ = time constant in seconds (s) R = resistance in ohms (Ω) Vc = voltage across capacitor (during charging) in volts (v) Vs = supply voltage in volts (v) t = time under charge / discharge in seconds (s) Vd = voltage across capacitor (during discharging) in volts (v) Capacitance C = Q V C = ( a d ) ε0εr Energy Stored by a Capacitor E = QV 2 E = CV2 2 Capacitor Time Constant (Charging and Discharging through a Resistor) τ = RC Capacitor Charging Voltage Vc = Vs (1 − e −t τ ) Capacitor Discharging Voltage Vd = Vse −t τ Useful Constant Values: *ε0 = 8.85 x 10-12
- 5. Capacitors in Series and Parallel Subject Equation Variables and Units Capacitors in Series: Total Capacitance 1 CT = 1 C1 + 1 C2 + 1 C3 C = capacitance in Farads (F) Q = charge in Coulombs (C) V = voltage in Volts (V) Total Charge QT = Q1 = Q2 = Q3 Supply Voltage Vs = V1 + V2 + V3 Capacitors in Parallel: Total Capacitance CT = C1 + C2 + C3 Total Charge QT = Q1 + Q2 + Q3 Supply Voltage Vs = V1 = V2 = V3