Transcript Slide 1

Measurement Techniques
DC Circuits
Feb. 2009
Measurement Techniques
DC Circuits
• Resistance (R)
– Ohms, Ω, KΩ, MΩ
• Voltage (V)
– Volt, AC, DC, mV, KV
• Current (I)
– Amp, mA (milliamps), uA (microamps)
Bread Board Techniques - Series Circuits
Resistance Measurement
•
•
Measurement must be made without power applied or wired to
the circuit.
Individual components must be removed from the circuit to
measure the value accurately.
RT Ω
Series Circuit
RT = R1 + R2 + R3
RT
R1
R2
R3
Given R1= 100, R2= 4.7K, R3=100K Find RT
Breadboard Techniques - Series Circuit
Voltage Measurement
•
•
•
The voltage supplied by the (12V) voltage source is proportionally
distributed across each resistor.
The higher the resistor value, the greater the voltage drop
Kirchoffs Law – The sum of the voltage drop across each resistor in
the circuit will add up to the source voltage
Vs
VR1
12V
R1
Vs
R2
R3
VR3
Vs = VR1 + VR2 + VR3
VR2
Calculating Voltage Drops
1. Determine total resistance RT
RT = R1 + R2 + R3
2. Using Ohms Law calculate total current IT
IT = Vs / RT
3. Using Ohms Law again, calculate the voltage drop across R1, R2, R3
VR1
IT
Vs
12V
R1
Vs
R2
R3
VR3
VR1 = IT x R1
VR2 = IT x R2
VR3 = IT x R3
VR2
Bread Board Techniques - Series Circuit
Current Measurement
•
The meter must be configured for current measurement.
•
The circuit must be “opened” and the meter placed (anywhere) in series.
•
The same current flows from the voltage source, “through” the meter,
each resistor, and then back to the source.
IR1
IT
R1
IT
Vs
IT
Vs
IT
12V
IT
R2
R3
IR3
IT = IR1 = IR2 = IR3
IR2
Bread Board Techniques – Parallel Circuits
Resistance
•
Circuit must be removed from the voltage source
•
The total resistance is “less than” the smallest resistor value
•
Avoid finger contact when measuring
1
RT Ω
RT
R1
R2
R3
Parallel Circuits
Calculating Total Resistance
RT Ω
Parallel Circuit
1
1
1
1
=
RT
RT
R1
R1 + R2 + R3
R2
R3
R1//R2//R3 Where R1 is in parallel with R2 which is in parallel with R3
R1
R2
RT
Let Rp = R1 // R2
Rp =
R1 x R2
R1 + R2
Now RT = Rp // R3
RT =
Rp x R3
Rp + R3
R3
Product-Over-Sum
Method
• Calculate the parallel
resistance of any 2
resistors at a time.
• First do R1//R2 using
the Product-Over-Sum
method
• Then use the R1/2
resistance in parallel
with R3
Parallel Circuits
Voltage Measurement
The source voltage (Vs) is common to all
components in the circuit
Vs = VR1 = VR2 = VR3
Vs
R1
R2
R3
Parallel Circuits
Current Measurement
IT
I1
Vs
R1
I1 + I2 + I3
I2
R2
I2 + I3
IT = I1 + I2+ I3
I3
R3
Parallel Circuits
Current Calculations
To measure current the circuit must be broken and the
current meter must be placed in series with the component.
IT
Vs
I1
I2
R1
I3
R2
R3
Calculating Total Current (IT)
Vs
50V
R1
150 Ω
R2
300 Ω
R3
100 Ω
1.
First find total
resistance RT
2.
Then use Ohm’s
Law to find
total current
Using Product-Over-Sum Method
R1//R2 = (150 x 300) / (150 + 300) = 100 ohms
Rp//R3 = (100 x 100) / (100 + 100) = 50 ohms
Using Reciprocal Method
1/RT = 1/R1 + 1/R2 + 1/R3 = 1/150 + 1/300 + 1/100
= 0.00666 + 0.00333 + 0.01 = 0.020
RT = 1/ 0.020 = 50 ohms
Note: when the
parallel resistors
are equal in value,
just divide by the
number of R’s
3K//3K = 1.5K
6K//6K//6K = 2K
Calculating Total Current (IT)
Vs
50V
R1
150 Ω
R2
300 Ω
R3
100 Ω
1.
First find total
resistance RT
2.
Then use Ohm’s
Law to find
total current
Total Current IT
IT =
Vs
RT
50 v
= -------- = 1 amp
50 Ω
The power supply must be capable of supplying at least 1 amp
of current
Calculating Branch Currents
RT = 50 ohms IT = 1 amp
IT
I1
I2
I3
Vs
50 V
R1=150
I1 = Vs / R1 = 50/150 = 0.333333 amps
I2 = Vs / R2 = 50/300 = 0.166666 amps
I3 = Vs / R3 = 50/100 = 0.200000 amps
1.00 amp
R2=300
R3=100
Series/Parallel Circuits
• There are multiple current paths.
• Resistors may be in series or parallel with
other resistors.
• A node is where three or more paths come
together.
• The total power is the sum of the resistors’
power.
Simple Combo circuit
Reduce the parallel connection to
its series equivalent
R2 // R3 = Rs
Then reduce the series equivalent
to the total resistance as seen by
the source
--/\/\/\/\-Rs
RT = R1 + Rs
I
E
R
Kirchoff’s says
“what goes out come back”
Reduce & Simplify
R1
R2
R3
R4
RT = R1,2 // R3,4
R1
R3
+
+
R2
R4
Analysis of a combo circuit
100
200
200
400
12 V
Board Solution
Calculate
1. Total current
2. Branch currents
3. IR drops
Reduce & Simplify – find RT
100
200
300
12 V
200
600
400
RT = R1,2 // R3,4
= 300 // 600 = 200
12 V
200 Ώ
IT = 12 / 200 = 0.06 amps (60 mA)
Determining Total Resistance
IT
R1
R2
R3
V
RT
RT = V
IT
R1
RT
R2
R3
1
1
1
1
RT = R1 + R2 + R3
Branch Currents
IT
100
Ia
Ib
200
300
12 V
200
400
Branch Currents
Ia = 12 / 300 = 40 mA
Ib = 12 / 600 = 20 mA
IT = Ia + Ib = 40mA + 20 mA = 60 mA
600
IR Drops (voltage across each resistor)
60 mA
40 mA
20 mA
VR1 = 40 mA x 100 = 4000 mV = 4V
12 V
R1
R3
100
200
R2
R4
VR3 = 20 mA x 200 = 4000 mV = 4V
200
400
VR4 = 20 mA x 400 = 8000 mV = 8V
VR2 = 40 mA x 200 = 8000 mV = 8V
Bridge Circuit
In a bridge circuit the voltage
difference between the two
parallel branches is used to
indicate the potential difference
between the two points.
VAB
VAB = VA - VB
R1
A
Vs
VA
R2
Using the Voltage
Divider Formula
R3
B
R4
VA =
VB
R2
x Vs
R2 + R1
VB =
R4
x Vs
R4 + R3
Wheatstone Bridge – null balance detector
VOUT = 0 volts
A balanced bridge can be used to measure an unknown resistance.
The Wheatstone bridge can be used as an “ohmmeter” by
comparing the unknown resistance value to a known one.
Conditioning circuit for resistive sensors and
transducers
R1
Vs
A
R1
R1
VOUT
B
Rs
VOUT can be used to represent
some type of process variable
Temperature
Thermistor
Resistance Temperature
Detectors (RTD’s)
Pressure
Strain Gauge
Flow
Anemometer
The bridge is often used as a conditioning circuit to convert the
output of a resistive type sensing element into a voltage (mV)