Sensors and Transducers PDF

Summary

This document provides an overview of sensors and transducers, encompassing their definitions, functions, and key characteristics. It details various types of sensors and examines fundamental aspects such as range, span, accuracy, and sensitivity.

Full Transcript

Chapter 2

Sensors and Transducers
 A collection of Sensors

GPS
Linear Encoder Gas
Camera

Gyroscope
Lever Switch

Sonar Ranging

Accelerometer
Piezo Bend Laser Rangefinder
PIR

Rotary
Encoder
Resistive Bend
Pressure
Pyroelectric
Detector
UV Detector
Pendulum Resistive
Metal Detector Tilt

IR Modulator
Receiver
Magnetometer Microphone

Radiation Magnetic Reed Switch
Infrared Ranging CDS Cell Compass
Definitions: Transducer and sensors
Transducer
– a device that converts a primary form of energy into a
corresponding signal with a different energy form
Primary Energy Forms: mechanical, thermal,
electromagnetic, optical, chemical, etc.
Sensor (e.g., thermometer)
- is a device that detects a change in a physical
stimulus and turns it into a signal which can be
measured or recorded
– acquires information from the “real world”

real intelligent
world sensor Mechatronic
system
 Sensor Systems
Typically sensor system
– convert desired parameter into electrically measurable
signal
General Sensor system
– Sensor/ transducer: sense “real world” parameter and
converted into a suitable signal
– Signal conditioning: converts the sensed signal into an
analog or digital electrical value
A/D usable
real Signal conditioning values
transducer signal
world
sensor

input microcontroller
signal signal processing
sensed data communication
(measured)

network
display
 Performance and terminology
The desirable features of sensors are:
1. Range / span
2. Errors and accuracy
3. Nonliearity
4. Hysteresis
5. Dead band and Saturation
6. Output impedance
7. Repeatability
8. Reliability
9. Sensitvity
10. Resolution
11. Frequency Response
12. Response time
13. calibration
 Range and Span
Range: lowest and highest values of the
stimulus
Span: the arithmetic difference between the
highest and lowest values of the input that
being sensed.
Input full scale (IFS) = span
Output full scale (OFS): difference between
the upper and lower ranges of the output of
the sensor.
Dynamic range: ratio between the upper and
lower limits and is usually expressed in db
 Range and Span (Example)

Example: a sensors is designed for: −30
°C to +80 °C to output 2.5V to 1.2V
Range: −30°C and +80 °C
Span: 80− (−30)=110 °C
Input full scale = 110 °C
Output full scale = 2.5V-1.2V=1.3V
Dynamic range=20log(140/30)=13.38db
 Errors and Accuracy
Errors: is the difference between the result of the
measurement and the true value of the quantity being
measured
error= measured value –true value
As a percentage of full scale (span for
example) error is calculated as;
e = ∆t/(tmax-tmin)*100 where tmax and tmin are the
maximum and minimum values the device is
designed to operate at.
 Errors and Accuracy Example:
Accuracy: is the extent to which the
measured value might be wrong and
normally expressed in percentage
Example: A thermistor is used to measure
temperature between –30 and +80 °C and
produce an output voltage between 2.8V and
1.5V. Because of errors, the accuracy in
sensing is ±0.5°C. so the measured value
may be high than or lower than by 0.5 °C
a. In terms of the input as ±0.5°C
b. Percentage of input: error = 0.5/(80+30)*100 = 0.454%
c. In terms of output. From the transfer function:
error= ±0.059V. ?
 Hysteresis
Hysteresis is the deviation of
the sensor’s output at any
given point when approached
from two different directions
Caused by electrical or
mechanical systems
– Magnetization
– Thermal properties
– Loose linkages
If temperature is measured, at a rated
temperature of 50°C, the output might be 4.95V
when temperature increases but 5.05V when
temperature decreases.
This is an error of ±0.5% (for an output full scale
of 10V in this idealized example).
 Nonlinearity
Nonlinearity is defined as the
maximum deviation from the ideal
linear transfer function.
Nonlinearity must be deduced
from the actual transfer function
or from the calibration curve
A few methods to do so:
a. by use of the range of the
sensor
– Pass a straight line between
the range points (line 1)
b. use a linear best fit (least
squares) through the points of the
curve (line 2)
c. use the tangent to the curve at some point on the curve
Take a point in the middle of the range of interest
-Draw the tangent and extend to the range of the curve (line 3)
 Deadband
Deadband: the lack of response or
insensitivity of a device over a specific range
of the input.
In this range which may be small, the output
remains constant.
A device should not operate in this range
unless this insensitivity is acceptable.

Dead Zone
 Output impedance
Output impedance: ratio of the rated output voltage
and short circuit current of the port (i.e. current
when the output is shorted)
output impedance is important for interfacing
Example: 500 Ω sensor (output impedance)
connected to a processor
– b. Processor input impedance is infinite
– c. Processor input impedance is 500 Ω
 Repeatability
Also called reproducibility: failure of the sensor to
represent the same value under identical
conditions when measured at different times.
– usually associated with calibration
– given as percentage of input full scale of the
maximum difference between two readings
taken at different times under identical input
conditions.

max− min.values given
Re peatability = ×100
full range
 Reliability

Reliability: a statistical measure of
quality of a device which indicates the
ability of the device to perform its stated
function, under normal operating
conditions without failure for a stated
period of time or number of cycles.
Given in hours, years or in MTBF
Usually provided by the manufacturer
Based on accelerated lifetime testing
 Sensitivity
Sensitivity of a sensor is defined as the
change in output for a given change in
input, usually a unit change in input.
Sensitivity represents the slope of the
transfer function.
Also is used to indicate sensitivity to other
environment that is not measured.
Example: sensitivity of resistance
measurement to temperature change
d aT + b = 1 → dR = a Ω
dR dT °C
 Resolution
Resolution: the minimum increment in
stimulus to which the sensor can respond. It
is the magnitude of the input change which
results in the smallest observable output.
Example: a digital voltmeter with resolution of
0.1V is used to measure the output of a
sensor. The change in input (temperature,
pressure, etc.) that will provide a change of
0.1V on the voltmeter is the resolution of the
sensor/voltmeter system.
In digital systems generally, resolution may
be specified as 1/ 2N (N is the number of bit.)
 Frequency response
Frequency response: The ability of the device to
respond to a harmonic (sinusoidal) input
A plot of magnitude (power, displacement, etc.)
as a function of frequency
Indicates the range of the stimulus in which the
device is usable (sensors and actuators)
Provides important design parameters
Sometimes the phase is also given (the pair of
plots is the Bode diagram of the device)
 Frequency response (cont)

Important design parameters
– Bandwidth (B-A, in Hz)
– Flat frequency range (D-C in Hz)
– Cutoff frequencies (points A and B in Hz)
– Resonant frequencies
Frequency response (example.)
Bandwidth: 16.5kHz-70Hz=16.43 kHz
Flat frequency range: 10kHz-120Hz=9880 Hz
Cutoff frequencies: 70 Hz and 16.5 kHz
Resonance: 12 kHz
 Response time
Response time: indicates the time needed for
the output to reach steady state for a step
change in input.
Typically the response time will be given as the
time needed to reach 90% of steady state output
upon exposure to a unit step change in input.
The response time of the device is due to the
inertia of the device (both “mechanical” and
“electrical”).
Fast response time is usually desirable
Slow response times tend to average readings
 Response Time

y(t)
p
Mp
1 ±10%
td
0.5

0
t
tr ts
s
 Calibration
Calibration: the experimental determination of
the transfer function of a sensor or actuator.
Typically, needed when the transfer function
is not known or,
When the device must be operated at
tolerances below those specified by the
manufacturer.
Example, use a thermistor with a 5%
tolerance on a full scale from 0 to 100°C to
measure temperature with accuracy of, say,
±0.5°C.
The only way this can be done is by first
establishing the transfer function of the
sensor.
 Calibration (cont.)
Two methods:
Method1. known transfer function:
– Determine the slope and crossing point (line
function) from two known stimuli (say two
temperatures) if the transfer function is linear
– Measure the output
– Calculate the slope and crossing point in V=aT+b
– If the function is more complex, need more points:
V = aT + bT2 + cT3 + d
– 4 measurements to calculate a,b,c,d
– Must choose points effectively - if linear, use
points close to the range. If not, use equally
spaced points or points around the locations of
highest curvature
Calibration
(con..)

Determine the output equation ?
 Calibration (cont.)

Method 2:
b. Unknown transfer function:
– Measure the output Ri at as many input values Ti as is
practical
– Use the entire span
– Calculate a best linear fit (least squares for example)
– If the curve is not linear use a polynomial fit
– May use piecewise linear segments if the number of points is
large.
 Calibration (cont.)

Calibration is sometimes an operational
requirement (thermocouples, pressure
sensors)
Calibration data is usually supplied by the
manufacturer
Calibration procedures must be included with
the design documents
Errors due to calibration must be evaluated
and specified
Displacement, position and proximity sensor

Displacement sensors are concerned with the measurement
of amount by which some object has moved

Position sensors are concerned with the determination of the
position of some object with rereference to some reference
point

Proximity sensors are a form of position sensors. They
are used to determine when an object has moved to
within some particular critical distance of the sensor
When selecting these sensors its essential to care of :
-The size of displacement -Nature of the displacement
-The required resolution & accuracy -The material of the measured object
-cost
Displacement, position and proximity sensor

Contact sensors Non-contacting sensors

The movement of the The presence in the
sensor element’s is used vicinity of the measured
to cause a change in object cause change in air
electrical volatge, pressure or change in
resistance, capacitance inductance or capacitance
or mutual inductance

The commonly
used displacement
sensors are given
below

1-10
 1-Potentiometer sensors (1)
It consist of a constant resistance per
unit length with sliding contact which
can be moved over the length of the
element. It can be used for linear or
rotary displacements

With a constant source voltage Vs,
the output voltage V0 is a fractional
of the input voltage
Vo R23
=
Vs R13
So, for rotary potentiometer the output
voltage is proportional to the angle
through which the slider has rotated,
hence an angular displacement can be
converted into a potential difference
 1-Potentiometer sensors (2)
It is very important to consider the effect of the
load resistance RL connected across the output.
The load voltage VL is only directly proportional
to V0 if the load resistance is infinite.
Assuming that the total potentiometer
resistance is RP, find the error in the output
reading in terms of x as suggested in the
shown figure. And if Vs=4 volt, RP=500 ohm
and the slider is in the middle of the traveling
range with a load resistance of 10 k Ohm.
Find the value of the error (in volt)
 2-Strain gauged element (1)
Strain gauge is a metal wire,
metal foil or a strip of
semiconductor material, these
elements can be stuck onto
surfaces like a postage stamp.
When subjected to strain, its
resistance R changes, the
fractional change in resistance
being proportional to the strain
ǫ, i.e G is the gauge factor
∆R typical values are 2 for
= Gε metal foil or wires +100 for
R P-type, -100 for N-type
semiconductor
For R=100, G=2, the change in resistance due to
0.001 strain is ∆R=RGǫ=0.2 ohm
Strain is the ratio of
change in length / orignal length
 2-Strain gauged element (2)
When the flexible element is
bent or deformed as a result of
forces being applied by a
contact point being displaced,
then the electrical resistance
strain gauges mounted on the
element are strained and so
give a resistance change,
which can be monitored. The
change in resistance is thus a
measure of the displacement
or deformation of the flexible
element
 3- Capacitive element (1)
Since capacitance C of a
εε A
parallel plate is given by: C = r 0
d
Capacitive sensors for ε rε 0 A
C=
monitoring of linear d

displacements might take
the forms shown.

In (a) if d is changed by a
displacement x then capacitance is
ε rε 0 A
C + ∆C =
d+x
The change in the capacitance value is non
linear relationship
∆C x/d
=−
C 1+ x / d
 3- Capacitive element (2)
This nonlinearity can be
overcome by using a push-pull
displacement sensor shown.
The displacement moves the
central plate between the two
outer plates so if initially the
distance between plate 1 &2
equal the distance between
plate 2 & 3 then C1=C2
So when C1 is in one arm
And for small displacement x
of an ac bridge and C2 in
other arm then the result
out balance voltage is
proportional to x
V=a+bx ????
Show how