CH-2 Transducers (Sensors) PDF

Summary

This document covers transducers and sensors, including static specifications like accuracy, resolution, and repeatability, and dynamic specifications. It provides examples and solutions, including a plot of a calibration curve.

Full Transcript

Ch. 2 : TRANSDUCERS
(Sensors)

1- INTRODUCTION
STATIC SPECIFICATIONS
DYNAMIC SPECIFICATIONS
 2. STATIC SPECIFICATIONS
Accuracy – Resolution – Repeatability –
Hysteresis and Linearity
Accuracy:
Error is the difference between true
output and actual output of transducer
1 - Percent error of the full scale output
( i.e. the max. reading ).
2 - Percent error of the true reading.
3 - Absolute error of the input quantity.
 Example-1
A load cell is a transducer used to
measure weight. A calibration is given
in table ( 1 ). It gives a full scale output
of 20 mV at the full scale load 100 Kg.
(A) plot the calibration curve.
(B) Determine the accuracy in both % of
FSO and of true reading.
)C) For accuracy + 7.85 % FSO, what is
the absolute error.?
 load (KG) output ( mV )
increasing decreasing
0 0.08 0.06
10 1.02 2.04
20 2.55 4.19
30 4.49 5.04
40 6.53 9.06
50 8.70 10.52
60 11.01 12.s4
70 13.32 14.92
80 15.4 16.94
90 17.66 l8.7
100 19.93 20.02
 Solution
(A) The plot is in Fig.( 1 )
OUTPUT
100 FSO

90

80

70

60

50

40

30

20

10
INPUT
0
10 20 30 40 50 60 70 80 90 100
 (B) We shall calculate, the true reading,
error ( mV ) and accuracy in % FSO and
% of reading for one reading ( increasing )
and another one (decreasing )
i - Load = 20 KG

V fullscale
Vtrue = xLoad mV
Load fullscale

20mV
Vtrue = x 20 Kg = 4 mV
100 Kg
 increasing
error e = Vtrue - Vactual = 4 - 2.55 = 1.45 mV
Accuracy :
percentage error of: true reading, or FSO:
%True reading = (1.45/4) x 100 = 36.25%
Percent error of full scale output :
𝟏. 𝟒𝟓
% 𝒆𝒓𝒓𝒐𝒆 𝒐𝒇 𝑭𝑺𝑶 = 𝒙𝟏𝟎𝟎 = 𝟕. 𝟐𝟓%
𝟐𝟎
 Decreasing
Error e = Vtrue – Vactual= 4- 4.19= -0.19 mV
Percentage error:
(of true reading)
= (- 0.19/4)x100 = - 4.75%
% of FSO =(- 0.19/20)x100= - 0.95 %
 ( C ) Absolute error is:
7.85 % of 100 KG = 7.85 KG
Thus, the output will be in error with
7.85 % of 20 mV i.e. + 1.57 mV.
Resolution
It is the smallest change in the input of
the transducer that will result a change
in the output.
 A rotation less than  / 2
may not result any countable output. So, this
encoder has 90o resolution
 Industrial encoders provide 100 and 1000
pulses per revolution i.e. resolution is:
𝟐𝝅/𝟏𝟎𝟎 𝒕𝒐 𝟐𝝅/𝟏𝟎𝟎𝟎 (i.e. 3.6 to 0.36 deg)

Example 2
A 2.5 meter long vane rotates in a circle by a
motor and gears attached to its center. It is
required to know the position of the vane
within 2 cm. What must be the resolution of the
optical encoder attached to the shaft that
positions the vane.
 Sol.
C = d =  (2.5) = 7.854 m
2
Re solutionin(deg) = x360 = 0.917 O
785.4
360
No.of − pulse / Re v = = 392.7 Pulses
0.917
Therefore, the optical encoder must produce at
least a 393 pulses/rev to achieve the
resolution required
 Repeatability
It is a measure of how well the output returns
to a given value when the same input is
applied several times.

𝑴𝒂𝒙𝒊𝒎𝒖𝒎 𝒓𝒆𝒂𝒅𝒊𝒏𝒈.. −.. 𝑴𝒊𝒏𝒊𝒎𝒖𝒎 𝒓𝒆𝒂𝒅𝒊𝒏𝒈
𝐑𝐞 𝒑 𝒆𝒂𝒕𝒂𝒃𝒊𝒍𝒊𝒕𝒚% = 𝒙𝟏𝟎𝟎
𝑭𝒖𝒍𝒍𝒔𝒄𝒂𝒍𝒆.𝒐𝒖𝒕𝒑𝒖𝒕

𝑳𝒂𝒓𝒈𝒆𝒔𝒕 𝒅𝒆𝒗𝒊𝒂𝒕𝒊𝒐𝒏
𝐑𝐞 𝒑 𝒆𝒂𝒕𝒂𝒃𝒊𝒍𝒊𝒕𝒚% = 𝒙𝟏𝟎𝟎
𝑭𝒖𝒍𝒍 𝒔𝒄𝒂𝒍𝒆 𝒐𝒖𝒕𝒑𝒖𝒕
 ‫ش‬
x

x x average
x x x x
x
average x x x
True
output x true output
x x x

(a) Accurate but not repeatable (b) Not accurate but repeatable

True
x x x x x x
output x x

(c) Accurate and repeatable
 Hysteresis : Maximum devation
Hysteresis % = x100
Full scale output

OUTPUT
100 FSO

90

80

70

Y
60

X
50

40

30

20

10
INPUT
0
10 20 30 40 50 60 70 80 90
 Linearity :
Ideally the transfer curve ( output - input )
of a transducer is a straight line. In
practice the curve will be as shown in
Fig. (1). Linearity measure how different
the actual characteristic from the ideal
one.
 Endpoint Linearity
Output-(Electrical)
10
0

90

80

70

60 Va
50 Vb

40

30

20

10
Input-(Physical)
0
10 20 30 40 50 60 70 80 90 100
 2 - Independent straight line linearity :
OUTPUT

100

90

80

70

60 Va
50
Vb
40

30

20

10
INPUT
0
10 20 30 40 50 60 70 80 90 100
 3 - Least squares linearity :
If : Xi = input values
Yi = output values
m = slope of the straight line
b = vertical intercept of straight line
n = number of data points
Y = mX + b n n n
n  ( X i Yi ) −  X Y i i
m = i =1
n
1
n
1

n  X i2 − (  X i ) 2
1 1

n n

Y i X i
b= 1
− 1

n n
 DYNAMIC SPECIFICATIONS
First order element
Time Constant - dead time
Input

Time

Output

1.0
0.9
0.632
Td
0.10
Tr
Tc Time
 Second order element:
Damping Ratio – Natural Frequency, DT

2
1

3
 4. POSITION TRANSDUCERS
Potentiometer as a displacement sensor
Resistor element
Resistor element
i

Linear displacement X i
+
+ o
E _
- _
eo ( xo ) +
E
 Wire wound
𝐹𝑢𝑙𝑙 𝑠𝑐𝑎𝑙𝑒 𝑑𝑖𝑠𝑝𝑙𝑎𝑐𝑒𝑚𝑒𝑛𝑡
Re 𝑠 𝑜𝑙𝑢𝑡𝑖𝑜𝑛 % =
𝑁𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝑤𝑖𝑟𝑒 𝑡𝑢𝑟𝑛𝑠

Carbon resistors: advantages are:
higher resolution
smooth resistive surface
increased speed
 Example 4
It is necessary to measure the position of
a panel. It moves 0.8 meter. Its position
must be known within 0.1 cm. Part of the
mechanism which moves the panel is a
shaft that rotates 250o when the panel is
moved from one end to the other. A
control potentiometer has been found
which is rotated at 300o full scale
movement. It has 1000 turns of wire. Can
this potentiometer be used ?.
 Sol.
The shaft
Required res. = 250/800 = 0.3125o/mm
Rotation of 0.3125 degrees is required to move
the panel 1 mm.

Available potentiometer has resolution of :
300/1000 = 0.3o/ turn
Pot. resolution < required resolution.
Potentiometer will work.
 Potentiometer Connections :
(a) (b)

E

E f f

i
R p i
V
V E
)c(
)d( mechanical link
to controlled
R variable

E CV

SP
E V (Error)
 Effect of Loading
V out
V in
1
Rp
=0
RL

Vin R2

R1
Rp
0
R L Vout RL
increasing

1 Xr
 𝑅1
𝑉𝑑𝑒𝑠𝑖𝑟𝑒𝑑 = 𝑉𝑖𝑛
𝑅1 + 𝑅2
[𝑅1 𝑅𝐿 /(𝑅1 +𝑅𝐿 )]
RL parallels R1 then, 𝑉𝑎𝑐𝑡𝑢𝑎𝑙 = 𝑉
[𝑅1 𝑅𝐿 /(𝑅1 +𝑅𝐿 )]+𝑅2 𝑖𝑛

𝑹𝟏 𝑹𝑳
𝑽𝒂𝒄𝒕𝒖𝒂𝒍 = 𝑽𝒊𝒏
𝑹𝟏 𝑹𝑳 + 𝑹𝟏 𝑹𝟐 + 𝑹𝟐 𝑹𝑳
If: Rp= R1+ R2 ,total petitioner resistance. Xa the actual wiper
displacement, and Xfs the full scale potentiometer displacement, then:
𝑋𝑎 𝑅1
𝑋𝑟 = = R1= Xr.Rp
𝑋𝑓𝑠 𝑅𝑝

𝑽𝒐𝒖𝒕 𝟏
Then: = 𝟏 𝑹𝒑 𝒇𝒐𝒓 𝑹𝑳 = ∞, 𝑽𝒐𝒖𝒕 = 𝑿𝒓 𝑽𝒊𝒏
𝑽𝒊𝒏 +(𝟏−𝑿𝒓 )𝑹
𝑿𝒓 𝑳
 Example 6
Plot the transfer curve and determine the
end point linearity of a 1 KΩ
potentiometer driving a 5 KΩ load
powered from a 10 V source.
Solution :
The desired and actual values are
presented in table (2) these are obtained
at 100 Ω steps of the wiper R1. Even if the
load is five times the resistance of the
potentiometer, up to 2.8 % error is
produced by the load.
 R1(Ω) R2(Ω) Vdesired(V) Vactual(V) % Dev. of FS Xr Vactual/Vin error
%

0 l000 0 0 0 0 0 0

100 900 1 0.9823 0.18 0.1 0.098 0.2

200 800 2 1.9380 0.62 0.2 0.194 0.6

300 700 3 2.8791 1.21 0.3 0.288 1.2

400 600 4 3.8168 1.83 0.4 0.382 1.8

500 500 5 4.76L9 2.38 0.5 0.476 2.4

600 400 6 5.7252 2.75 0.6 0.573 2.7

700 300 7 6.7179 2.82 0.7 0.672 2.8

800 200 8 7.7519 2.48 0.8 0.775 2.5

900 100 9 8.8409 1.59 0.9 0.884 1.6

l000 0 10 10.0 0.0 1.0 1.0 0.0
 Nonlinearity caused by loading
Voct 1.0
Vin

0.9
Actual

0.8

Desired
0.7

0.6

0.5

0.4

0.3

0.2
Nonlinearity error = 2.8%
0.1

0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
Xr
 Linear variable differential transformers
(LVDT )
The LVDT is an electromechanical device
that produces an electrical output
proportional to the displacement of a
separate movable core.
It consists of a primary coil and two
secondary coils symmetrically spaced on
a cylindrical form, connected in opposite
polarity.
No physical contact between the movable
core and coil structure, i.e., LVDT is a
frictionless device
 Sec.
Sec. coil 1
coil 2
Primary
coil

Core
motion

Core
 Sec. coil 1

Primary coil
Core
e1 e = e − e
o 1 2

e2

Sec. coil 2
 LVDT output versus displacement
a

Output (V)

Displacement

Linear displacement
 LVDT electronics

LVDT

Carrier Rectifier &
Demodulator DC amplifier
generator filter

AC Power supply
 LVDT provides complete isolation
between excitation input ( primary ) and
output (secondaries). This makes it an
effective analog computing element
without the need for buffer amplifies
Frictionless, infinity life.
used in aircrafts, missiles, space
vehicles and critical industrial
equipment.
 Optical Encoders:
Incremental Encoder:
The encoder is a disk with a track on it
near to its outer edge this track is
divided into equal dark and transparent
parts with light source on one side and
light sensor on the other.

1
0
 Incremental encoder with two tracks shifted by  / 2
for direction detection

A

B

A

B

C

reference pulse C
 B - Absolute Encoder:
Absolute encoders are used in
applications where a device is inactive
for long periods of time or moves at slow
rates such as flood control, telescopes
cranes, etc.
It gives a different and full binary word for
each position increment.
 (a) Natural binary code. (b) Grey code, only
outer track is the LSB, one bit switch at a
inner track is the MSB time
 A 4 bits Gray code absolute encoder:.
 5. FORCE TRANSDUCERS
An entire engineering discipline
(experimental stress analysis) has been
established to evaluate forces applied to
various parts of a machine or vehicle.
Accurately measured forces allow proper
design of machinery (including cars and
spacecrafts) that is lighter, more efficient,
more reliable, less expensive, and which
provides higher performance.
 Measurement of force allows us to evaluate
parameters which are difficult to measure
directly like mass, level, pressure, flow
rate.... etc. Finally, the force exerted by a
spring is directly proportional to how much it
has been expanded:
F=KX
Measurement of force exerted on (or by) the
spring is an indirect way to measure the
displacement X in spring-mass-damper
system
 Stress and strain
Strain may be either tensile (positive) or
compressive (negative),
𝜟𝑳
𝜺=
𝑳

Usually expressed in microstrain, which is ε
X 10-6 , for example 0.00500 in/ in = 5000
micro strain ( με).
 a

𝑭 
𝑺𝒕𝒓𝒆𝒔𝒔 𝝈= E (Young ' s − mod) =
𝑨

 Strain Gage:
Probably the most important electrical
characteristic which varies in proportion to
strain is the electrical resistance :
piezoresistive or semiconductor gage,
carbon resistor.
bonded metallic wire gage.
foil resistance gages.
 Bonded Resistance Strain Gage :

Bonded wire Metal foil strain
strain gauge gauge

Δ𝑅/𝑅
𝐺= , 𝑔𝑎𝑔𝑒 𝑓𝑎𝑐𝑡𝑜𝑟
𝜀
 Example :8
A strain gage is bonded to a steel beam
which is 10 cm long and has cross sectional
area of 4 cm2. Young's modulus of elasticity
for steel is 20.7 x l0l0 N/m2. The strain gage
has a nominal (unstrained) resistance of 240
Ω and a gage factor of 2.2. When load is
applied, the gage's resistance changes by
0.013 Ω. Calculate the change in length of
steel beam and the amount of force applied
to the beam.
 Solution:
Gage factor:
𝜟𝑹/𝑹
𝑮=
𝜟𝑳/𝑳

In above equation the only unknown is ∆L
Young’s modulus E :
𝑭 𝜟𝑳
=𝑬
𝑨 𝑳

The only unknown is the force F
 It would be preferred that the gage resistance
changes only with strain, but practically the
gage resistance varies also with temperature.
RT = RTo(1+αoΔT)
where :
RT = resistance at T
RTo = resistance at a reference temperature To
αo = temperature coefficient
ΔT = change in temperature from To.
i.e. the change in resistance due ∆T change in
temperature only is:
ΔR = αo ΔT RTo
 Example: 9
Calculate the change in resistance caused
by a 1 Co change in temperature for the
strain gage in the last example. The
temperature coefficient αo for most
materials αo = 0.003925 / Co
Solution :
∆R = 0.003925 x 1 x 240
= 0.942 Ω
𝑹𝒕𝒆𝒎𝒑 𝟎. 𝟗𝟒𝟐
= = 𝟕𝟐. 𝟓
𝑹𝒔𝒕𝒓𝒆𝒔𝒔 𝟎. 𝟎𝟏𝟑
 Wheatstone Bridge Circuit :
Because of its sensitivity, Wheatstone bridge
is the most used circuit for strain
measurements

Rg = Ro + R
Ra
+

Vo
E -
Rc
Rb
 𝒄𝒐𝒏𝒔𝒊𝒅𝒆𝒓: 𝑹𝒐 = 𝑹𝒂 = 𝑹𝒃 = 𝑹𝒄 = 𝑹
when stress is applied, the strain gage
changes its resistance by ΔR :
R R
Vout = E− E
R+R R + R + R
1 R R
= E− E= E
2 2 R + R 4 R + 2R

but as R >> ΔR , 4R >> 2ΔR

R
Vout = E
4R
 Use of active and dummy gages to compensate
temperature

Ro
active Ra
gauge +

V

Rc E
Rb
-
dummy
gauge
 acting force

active guage dummy guage

Rg Rc
 Beside the temperature effect will be
eliminated, the bridge sensitivity can be
increases if we make both gages active, by
having one gage in tension ( its resistance
increase with load ) and the other in
compression ( its resistance decrease with
Load).
The output voltage for a given load
doubles the single active gage output :

R
Vout = E
2R
 Two active gages ,one placed on surface
under tension, other on compressed
surface
Gage place in
tension
Force Tension Copmression

R + R
Ro + R Ro − R
+
Vout
R − R

Gage placed in
E
compression -
R c

Rb
 Four active gages to increase sensitivity
and temperature compensation
R
Vout = E
R

Tension Compression
R + R R − R
+
E
Vout

-
R − R R + R
Compression Tension
 Accurate measurements using strain
gages are only obtained if the following
conditions are satisfied.
- Gage must be perfectly aligned with the
force.
- Adhesive material must transmit
faithfully the force between gage and the
beam.
- The beam must provide equal tension
and compression to opposite legs of the
bridge.
- Negligible solder connections to the
gage.
 LOAD Cells
It is a transducer specially designed to
measure force. It consists of a beam with
properly mounted four strain gages,
excitation voltage source, amplification
and display electronics are needed.
A set of specifications, but the important
one is the output at rated capacity i.e.
sensitivity, expressed in mV/V i.e. the
output voltage in (mV) at the full load
applied for each volt of the supply voltage.
 Example 11
A load cell type GS5353 has the following
specifications : output at rated load ( rated
capacity=max. or rated load) 500 Ib is 2 mV/V
Nonlinearity ± 0.050 %FS
Bridge resistance 300 ohms
Compensated temp. range + 25 Fo to 125 Fo
Temperature effect on zero ± 0.002 % FS/Fo
Recommended excitation 10 V DC
a - What is the output voltage per pound ?
b - What is the nonlinearity error in pounds ?
c - What is the zero shift in pounds if the
temperature varies across its rated range ?
 (a) Vout. max = output at rated capacity x Vsupply
= 2 mV/V x 10 V = 20 mV
Vout/Ib = 20 mV/500 Ib = 40 µV/Ib
This means that our electronic circuits
associated with the cell must be able to clearly
and accurately amplify signals of 40 µV or less
if we expect to resolve and display 1 Ib
increments.
(b) Nonlinearity is ± 0.05 % FS
= ± 0.05 x (1/100) x 500 = ± 0.25 Ib
* (c) Zero shift=(0.002/100)(100F)(500 Ib)=1 Ib
must be adjusted
 6. Velocity Transducers
Linear velocity sensors
Electromagnetic linear transducer

d
emf = − N
dt
 Laser-Doppler System
The Doppler effect relies on a shift in
frequency
Frec= Fo + Fv
Frec is the frequency of the echo
Fo the frequency of the transmitted signal
Fv the shift in echo frequency which is a
function of the target velocity.
Radar speeders detector, missile
targeting, tracing & navigation of
spacecrafts
Angular Velocity Measurements :

DC Tacho-generator:
Stator Field: permanent magnet or separately
excited
Rotor has a series of coils + Commutator
Induced emf in the coil is directly proportional
to the rotor speed
The output is pure DC (commutation + brushes)
PM: Output 3V to 7V per 1000 r/min or
Electromagnet : 10 V to 20 V per 1000 r/min.
Accuracies of 0.1 % to 0.25 % FSO
 AC Induction Tachogenerator:
Called the AC permanent magnet
tachometer.
It has no brushes.
Primary and secondary windings placed
at right angles on the stator.
Rotor is squirrel cage made of high
conductance metal.
When the rotor is stationary the magnetic
field of the rotor induced emf does not
link the secondary, then output equals
zero,
 At ω=0, no flux linkages between primary and
secondary, (right angle) the output voltage = 0
When the rotor is rotated, the field links the
secondary, inducing an output voltage.

The more faster the rotor, the larger output in the
secondary.
The output is AC, rectified, smoothed to be used
as a measure for the rotational velocity.
It overcomes the problems (sparks and
electromagnetic interference to other control
circuits) resulted by the brushes of the DC
tachometer.
 Counter-type Velocity Sensors
Outputs a signal its frequency depends
on the speed of rotation.
Conditioned in order to be a series of
countable pulses.
AC permanent magnet tachometer
the incremental optical encoder
Gears, belts and shafts all introduce
errors. Also, the inertia of the transducer
may load down the system.
 Reflective optical sensor
 Example 12:
A dc motor that drives a conveyor belt
has a maximum speed of 1720 r/min. It is
necessary to monitor the speed with a
resolution of 1 r/min and provide new
number every 100 ms.
- How many pulses per revolution are
required ?
- If it were necessary to use a 6-pulse/
revolution reflective optical sensor,
describe degradation in performance.
 The revolutions per second are:
speed = 1720 x (1/60)= 28.67 r/sec.
In 100 ms (the allowed counting time) the,
number of revolutions =
28.67 x 0.1 = 2.867 revolutions.
Thus, we must get 1720 counts during the
counting period (0.1 s), i.e., 1720 = 2.867 x
Number of pulses per revolution
No. of pulses/revolution = l720/2.867 = 600
pulse/ revolution.
That is to get a measure for the speed in
r/min every 0.1 sec.
 Simply how many revs occur in 0.1 sec.,

1720 𝑥 0.1
Revs in 0.1 sec = = 2.867 𝑅𝑒𝑣𝑠
60

In 2.867 revs we must get 1720 counts (pulses),

1720
How many pulses/one rev= = 600 pulses
2.867
 b - If we must use a 6-pulse / revolution
reflective optical sensor, the number of
pulses will be less with a factor 1/100
Thus, we obtain a measure for the speed
in r/min every 10 Sec. which is too long
for most control applications.
The solution may to use a frequency multiplier
with a factor of 100, or to use a frequency/
voltage F/V converter and then amplify the
voltage by a gain of 100, then use V/F
converter.
This also may be shown as follow:
 With 6 pulse/rev, the number of revolutions
required to obtain 1720 counts =
𝟏𝟕𝟐𝟎
= = 𝟐𝟖𝟔. 𝟕 𝒓𝒆𝒗𝒔
𝟔
Time required to obtain 286.6 revs
𝟐𝟖𝟔.𝟕
= = 𝟏𝟎 𝑺𝒆𝒄.
𝟐𝟖.𝟔𝟕
Therefore, we obtain a measure for the speed
in revs/min every 10 seconds instead of 0.1 S
which is too long for most control systems.
Also, we my use an F/V converter then multiply
by a gain of 100, then use V/F converter.
 7. FLUID TRANSDUCERS
Fluid transducers are used extensively
throughout the industry.
Applications : food processing industry,
drug and chemical industries, and along
the entire line of oil production, from
exploration, drilling, pumping,
transportation, refining to sales.

Pressure, level and flow
 Pressure Transducers :
Normally pressure measured in
comparison to a reference :
a - Absolute pressure : (Vacuum)
The unit is :psia (a=absolute)
b - Gage pressure : (ambient)
The unit is :psig.
c - Differential pressure :
The unit is :psid.
 A common industrial unit for the
pressure is pounds per square inch (psi)

In metric system pressure units is
Newton/meter2 which is called Pascal (Pa)
1 psi = 6.8948 x 103 Pa
Pascal is a small unit,
1 KPa = 103 Pascal
1 psi = 6.8948 KPa
 The height of a column of mercury that yield a
certain pressure is also used as a unit of
pressure measurement:
1 inch of mercury (Hg) = 3.386 KPa
1 mm Hg = 133.32 Pa (also called torr)
1 torr = 1 mm Hg = 133.32 Pa
Atmospheric pressure at sea level is defined as:
1 atm = 76 Cm Hg = 760 mm Hg = 1.01325 x 105
Pa
Barometric pressure, in weather reporting is
measured in bar or millibar
1 bar = 105 Pa = 100 KPa
 Manometric means for pressure
measurements:
P2
P2 P1

Tube cross A1
sectional area

P1 h h

Well cross
sectional area
A2

Well-type manometer
 -

Vacuum

h

0

Barometer
 If Pl = P2, then h = 0, where P1, P2 are
pressures applied to the two arms and h
is difference between the levels of the two
surfaces, i.e. if P2 > P1
P2 - P1 = g h ρ
where
ρ: is liquid density
g: gravity constant
h: the differential height between the two
Liquid surfaces.
P2 = P1 + ρ g h
 1
h= ( P2 − P1 )
g

The accuracy depends mainly on :
the effect of temperature on ρ ,
The deviations in g according to the place,
The instrument also must be exactly in
vertical position
 Elastic Pressure Transducers
All elastic deformation pressure
transducers use the same principle.
Pressure causes a deformation of the
transducer material usually a metal.
This deformation results in a deflection or
displacement, i.e. these transducers are
pressure to position transducers
We will consider three types: Bourdon
tube, the bellows , and the diaphragms.
 Bourdon Tubes
Bourdon tube is one of the oldest and
most popular pressure transducers. It
was invented in 1851 by E. Bourdon
Made of brass, bronze, or steel
The tube deforms nonlinearly
Bourdon tube is simple to manufacture,
inexpressive and accurate and it
measures pressures up to 100,000 psi
(700,000 KPa)
Motion of the free end

Pressure
Helical tube C type
 C - type Bourdon tube with LVDT
 Diaphragms
Flexible plate usually made of metal or
rubber. For greater sensitivity, these
plates are corrugated.
Increase in pressure causes deformation
in the diaphragm, measured using strain
gage giving electric signal represents the
applied pressure

(a) Flat Diaphragm

(b) Corrugated
Diaphragm
 Pressure
Pressure P2
P1

Diaphragm
 Vacuum

Pressure

Diaphragm
 Bellows
Pressure bellow is a cylindrical shaped
device, corrugated along its edges.
As pressure increases the bellows
expands, moving the shaft upwards.
The shaft may be attached to a pointer
or an electric displacement transducer
like an LVDT
Bellows are more sensitive to pressures
in the range 0-30 psi (0-210 KPa) than
Bourdon tubes. Thus, they are useful at
lower pressures measurements.
 free
fixed
motion
pressure
 FLOW TRANSDUCERS
1 - Volumetric flow Q : Units are m3/sec.
litre/s or gallon/min.
2 - Mass flow Qm : Units are KG/Sec. or
pounds/Sec
Velocity of flow Qv : Unit is m/sec.
Qm = mass flow = Q.ρ
volumetric flowrate Q
Qv ( flow velocity ) = =
pipe cross sec tional area A
 Laminar Flow : fluid moves parallel to
the walls of the pipe, sliding smoothly.
Turbulent Flow: fluid tumbles and swirls.
The degree of turbulence
Q v d
N =
U
N: Reynolds number , QV: Velocity of
flow, d: diameter of the pipe
ρ: density of the fluid , U: Viscosity
For N > 4000 the flow is turbulent,
For N < 2000 the flow is laminar
 The material may vary from powder, solid,
gas or liquid
We will consider only fluid (liquid or
gases) transducers
Flow transducers are divided into two
groups
Obstruction: uses the energy in the flow
to produce a measurable effect. Two
effects: First, it causes a pressure drop
across the obstruction.
Second, the flow will be lowered.
Non intrusive:
 Orifice Plate :

Sharp edges

Orifice Plate

Q = K P1 − P2
Q = flow rate
K = Constant depends on the geometry of
the orifice and the units used.
P1, P2 = high side and low side pressures
 advantages.
simple to design, build and install.
It can be used for most fluids which are
free of particles.
disadvantages :
poor accuracy, limited range and
inability to be used with slurries
 Venturi Tube
diameter of the tube is gently narrowed,
and then widened
lower tendency to plug up. P1 is very near
to P2, so flow measurement error due to
pressure loading is much lower.
main advantage is it can be used for
slurries because there is no sharp edges.
Its major disadvantage is cost, it is
expensive to buy and install.
 Venturi Tube
 Dall Tube.
least insertion loss. Two cones, the
shorter one upstream of the restriction,
the longer cone downstream.
cheaper to purchase and install than the
Venturi tube. However, it cannot be used
with solids and slurries.

Flow

P1 P2
 Elbow tube.
P2 > P1.
Installation of elbows poses no problems.
No pressure loss as there is no
restriction. However, the elbow flowmeter
has only ±5% accuracy at best
 Rotameter
Produces a noticeable pressure drop and
may be nonlinear.
Leads from the potentiometer or LVDT

Glass
Tube
Scale
Float

X

Flow
 Cantilever Flow Meter
Flow causes a force on the target
producing a deflection, sensed by strain
gages bonded to the beam
To compensate for temperature variation
of the fluid, four active strain gages
should be used.
Target Strain gages

Flow
 Disadvantages:
As with other obstruction-type flow
sensors:
There is a pressure drop across the beam,
although not as severe as with orifice
plate.
The target encourages clogging and may
be damaged by particles.
In addition, the strain gage leads must be
brought out through the wall of the tube.
This requires extra effort in sealing the
transducer
 Turbine flowmeter:
Electromagnetic assembly

Output
signal

Turbine

Flow

e
Low rate High rate E
High rate
Frequency
to Voltage
Converter
Low rate

t t
 Rotary speed depends on the flow rate of
the fluid.
By reducing bearing and other losses to
a minimum, one can design a turbine
whose speed varies linearly with flow
rate.
turbine blades produce voltage pulses
when pass near a magnet. Counting
these pulses one can measure flow rate,
accumulating the total number of pulses
during a timed interval the total flow is
obtained.
 If an analog voltage signal is desired to
represent the flow, the pulses can be
fed to a frequency-to-voltage converter
Electromagnetic Flowmeter
magnetic field
Applied voltag (ac)
to produce the
magnetic field

b

Flow a

Electrodes Nonconductive
pipe
(a) Basic components

E
b +
2
E a
−
2

0 V line

(b) Tube cross section
Conductor Magnetic field

Direction
of motion

(a)
E
+
2

E
−
2
0 V
(b)
R E E R
2 2 2 2
0V
- + - +

- E +
(c)
 If a liquid is mildly conductive the
electromagnetic flow meter may be used. A
nonconductive section of pipe is required or
lining a metal pipe with a nonconductive
material.
A magnetic field is placed at right angles to the
flow. The generator rule will apply to both the
electromagnetic field and the liquid in motion.
Electrodes are placed so as to sense this
induced emf, which is linearly proportional to
the flow velocity, strength of the magnetic field,
and the diameter of the pipes.
 Advantages:
Producing no pressure drop to load
down the flow.
Flow reversal can easily be detected.
Also there is nothing to clog up or
break off. However, the fluid must be
consistently conducive, a special
section of pipe is required, and the
output is in the microvolt range.
 Ultrasonic Flowmeter
Nonintrusive flow uses the propagation
of ultrasonic waves through the fluid

Detection
and
encoding

Ultrasound transciever

Flow
f2
f1

Ultrasound transciever
 The transducers are piezoelectric
crystals capable of both receiving and
transmitting ultrasonic signal.
The signal traveling with the flow will
arrive at a higher frequency than that at
which it was transmitted.
The signal traveling against the flow will
have its frequency lowered.
This difference in arrival frequencies is
directly proportional to the velocity of the
fluid
 Level Transducers
Discrete Level Transducers
Float switch Photoelectric level sensors
high level low level Inferared
indication indication light
emitting Photo-sensitive
diod transistor
retainer
Reed
relay permanent
contacts magnet
Optical transmitter
Float
reflector

reed relay
contacts Reciever

(b)
retainer
nonferrous
tube
 Continuous Level Transducer
Level measurement by pressure sensing
Offset transducer

h to be measured

Pressure
transducer

offset to be corrected
by electronics
 The pressure at the bottom of a column of
liquid is defined as the head and is
proportional to the height of the column
P=ρgh
P = head (pressure)
ρ = density of the liquid
h = height of the column
 If the tank is sealed, the pressure at the bottom of
the tank depends not only on the head, but also on
the pressure at the top :

Pbotttom = gh + Ptop
Pbottom − Ptop
h=
g

Sealed tank
 Float Level Sensors
A float and valve arrangement installed
inside the tank.
The valve can be replaced with the
slider arm of a linear potentiometer

 The force applied by the float to the valve
is amplified by a factor of ℓ1/ℓ2.
Scale

l2
Pointer open

float l1
Float pivot
close
valve
 Capacitive Level Sensors
When the material or the liquid in the tank
is an insulating material, it can serve as a
dielectric in a capacitor.
The capacitor behaves as two capacitors
in parallel
The change in capacitance is caused by
the changing dielectric constant between
liquid and air. This change in capacitance
usually sensed by an oscillator in an AC
bridge.
 a

AC bridge
- RF
oscillator
 Ultrasonic radiation (ultrasonic range
detector)
Ultrasonic
Transceiver

Level readout
 d = 0.5 V.t
where:
d = distance to the surface
V = velocity of sound
= 331.5 m/s sea level and 0 Co
t = total time to the surface and back.
 TEMPERATURE TRANSDUCERS
Early 1700s, when Gabriel Fahrenheit a
Dutch instrument maker, produced an
accurate and repeatable mercury
thermometers
1742, Anders Celsius proposed that the
melting point of ice and the boiling point
of water be used for the two benchmarks
Co = 5/9(Fo - 32) Fo = 9/5Co + 32
Ko = Co + 273.15
A) Mercury thermometer (b) Thermometer with an electrical
output using Bourdon tube and an LVDT

Capillary Bourdon Tube

Bulb

Tcap
T

LVDT eout
ein
 Bimetallic thermometers:
Two metallic
stripes bonded 1 >  2
At T1 (normal) the two stipes are
r in normal position (flat).

At T2 one stripe will expand
T1 more the the other, thus,
deforms into a circular arc

1

2 T2  T1
T2 
T2  T1

Temperature change from T1 to T2
 Details of materials and bonding
processes are in some cases considered
trade secrets.
Invar, a nickel steel with a nearly zero [l.7
x 10-6 in./(in. Co)] expansion coefficient.
Brass was originally employed, also a
variety of alloys are now used for the
high-expansion strip.
Bimetallic devices are used for temp.
measurement and also used widely as
combined sensing and control elements
in temp.-control systems, mainly of the
ON-OFF type.

2r
=
3( a −  b )(T2 − T1 )
ρ : radius of curvature
r : total strip thickness, 0.0005 inch < r <
0.125 inch in practice.
T2 – T1 : temperature rise
The working temp. ranges from -100 to
1000 Fo. Inaccuracy of the order of 0.5 %
to 1 % of scale range may be expected in
bimetal thermometers of high quality.
 Thermocouples:
Thomas Seebeck made the discovery in
1821 “ Seebeck Effect ” any 2 diff metals
Copper – constantan (Cu57+Ni43) (type-T)
thermocouple, to connect a voltmeter,
two more metallic junctions : J2 is a
constantan-copper junction which will
add an emf (V2) in opposition to V1
The other junction will have no effect as it
is copper-copper junction.
 a
A

J2 J1
i T2
(a)
T1
B
Ammeter
A A
J2 J1
(b) i
T2
T1
B
A thermojunction
Voltmeter
J1
(c) et i T2
B
Copper

Heat source
(measured Teperature)
 Copper – Constantan (type T) thermocouple
Connecting a voltmeter will form another junction
𝐽2

Copper
A
Copper

J1
E
T2
Copper
Constantan B
T1 J2
 J1 temp. is measured wrt J2
Voltmeter reading V will be proportional
to the temp. difference between J1 and J2.
This says that we can't find the temp. of
J1 unless we first find the temp. of J2
One way to determine the temp. of J1 is
to physically put the Junction J2 into an
ice bath (i.e. at zero Co), forcing its temp.
to be 0 Co and establishing J2 as the
reference junction.
V = V1 – V2
= TJ1 - TJ2= TJ1 – 0 = TJ1
 Temp. measurement with a thermocouple
and an external reference
Copper
Copper
J1
E
T2
Copper
Constantan
J2

J2 at zero temp.
 We may use a different arrangement without
ice box by using a thermistor to measure the
reference junction temperature. Then
calculations has to be made in order to find the
temp. of the junction J1. This is called “
software compensation” as it require
computation to compensate for the effect of
the reference junction.
 According to thermoelectric law-3
(follows) & measure the ref. jun. temp.
Isothermal block of
temperature T
ref
iron
J2 copper
T +
J1 _ V
J3 copper
Constantan
Thermistor.
 Electronic ice point reference:
We could insert a battery to cancel the
offset voltage of the reference junction
The combination of this hardware
compensation voltage and the reference
junction voltage is equal to that of a 0 Co
junction.
The major drawback is that a unique ice
point reference circuit is usually needed
for each individual thermocouple type.
 The AD594/AD595 is a complete
instrumentation amplifier and
thermocouple cold junction compensator
on a chip. It combines an ice point
reference with a pre-calibrated amplifier
to produce a high level 10 (mV/Co) output
directly from a thermocouple signal.
A given thermocouple material must be
calibrated over the complete range of
temperature in which it is to be used.
 Thermoelectric Laws:
These laws, are used for analysis of most
practical thermocouple circuits.
1-The thermal emf of a thermocouple
with junctions at T1 and T2 is totally
unaffected by temp. elsewhere in the
circuit if the two metals used are each
homogeneous
T3 T5
J2 J1 T2 T1
emf( )= emf( )
J2 J1
T2 T1
T4 T6
 2-If a third homogeneous metal C is
inserted into either A or B , as long as the
two new thermojunctions are at same
temps., the net emf of the circuit is
unchanged irrespective of the temp. of
conductor C away from the junctions.
A A
J2 J1 J2 J1
emf( )= emf(
J3 J4
)
T1 T2 T1
T2
B B B

C
 3. If a metal C is inserted between A and
B at one of the junctions, the temp. of C
at any point away from the AC and, BC
junctions is immaterial. So long as the
junctions AC and BC are both at the temp.
T1, the net emf is the same as if C were
not there.
A T1 C A
J2 J2 J1
emf(
T3
) = emf( )
T2 T1
T2 T1
B B
Fig.(47
 4. If the thermal emf of metals A and, C is
EAC and that of metals A and B is EAB and
that of metals B and C is EBC, the thermal
emf of metals A and C is EAB + EBC.
i.e. EAC=EAB+EBC

A A B
T2 T1 T2 T1 T2 T1
emf( ) = emf( )+ emf( )
C B C
 5. If a thermocouple produces emf E1 when its
junctions are at T1 and T2, and E2 when at T2
and T3, it will produce E1 + E2 when the
junctions are at Tl and T3.

A A A
T3 T1 T3 T2 T2
emf( T1
) = emf( )
+ emf( )
B B B

ET3 −T1 = ET3 −T2 + ET2 −T1
 Common types of thermocouples:
Thermojunctions formed by welding,
soldering, or by pressing the two
materials together give identical voltages.
If current is allowed to flow, the currents
may be different since the contact
resistance differs for the various joining
methods.
Welding (gas or electric) is most widely
used although silver solder is used in
copper/constantan couples.
 Resistance Temperature Detector RTD
Pure metals such as platinum, nickel,
tungsten, and copper, have positive
temperature coefficients.
RT= Ro( 1+αT) Ω
RT = resistance at temperature T
Ro = resistance at 0 Co
α = temperature coefficient of resistance.
RTD is the most accurate and stable
temperature sensor.
 It is linear and covers high temperature
range.
Disadvantages include slowness of
response, small resistance change, and
high cost.
Common resistance values for RTD's
range from 10 Ω to several thousand
ohms. The most common value of
resistance is 100 Ω
 Thermistor
Like the RTD the thermistor is also a
temperature-sensitive resistor.
Thermistor exhibits the largest parameter
change with temp. i.e. higher sensitivity. The
price is loss of linearity.
Thermistors are made of semiconductor
material. Most thermistors have a negative
temperature coefficient (NTC)
The NTC can be as large as several percent per
Co, allowing the thermistor circuit to detect
minute changes in temp. which could not be
observed with an RTD or thermocouple circuit.
So it is the most sensitive temp. sensor
 Thermistor–temperature characteristics:
(Nonlinear)
Resistance: Ohms
5
10 Rt

4
10

10 3

2
10

max. continuous
10
temperature

1
100 200 300
o
Temperature: C
 The price we pay for this increased sensitivity
is loss of linearity. The thermistor is an
extremely nonlinear device.

 Thermistor curve can be approximated
through use of the equation :
1
= A + B ln( R) + C{ln( R)}2
T
T = degrees Kelvin
R = resistance of the thermistor
A,B,C = curve-fitting constants
Thermistor
RT

R To
-
Ei + Eo
 Circuits used for sensing temperature
with thermistor
E V

Termistor
or
ist
m

o o
T RT
er

T
Th

E
Eo
R1
 Connecting a resistor Rs in parallel to
improve thermistor linearity

Resistance (Ohm)
T
Resistor

Thermistor
Rt
Linear

Thermistor-resistor
R
s
o
(a) (b) Temperature C
 Semiconductor Temperature Sensors:
Germanium can be used to sense temp.
near absolute zero.
It has a negative temp. coefficient (NTC)
and is very nonlinear.
Silicon is also employed as temp.
sensors.
Silicon crystals have a positive linear
temp. coefficient (PTC) in this range
Their useful range extends from - 67 to
275 FO
 Recall that a reverse-biased PN junction
conducts a small amount of leakage, or
minority carrier, current flow.
As temp. increases, leakage current
increases exponentially.
A reverse biased diode with a CDA
(Current Differencing Amplifier) is used as
a temp. sensor.
 CDA is a linear amplifier circuit in which the reverse
current in the diode 𝑰𝑫 is mirrored in the feedback
resistor 𝑹𝑭 producing an output voltage:
𝑽𝒐 = 𝑹𝑭 𝑰𝑫
This effect is used to measure temp.
with transistors and reverse-biased
diodes.
Normally, germanium semiconductors
are used, because their leakage is much
greater than that of silicon.

 Suppose we have a feedback resistance
RF of 1 MΩ and a diode current ID at room
temperature of 10 μA. For the circuit
shown above ,the output voltage is
Vo = ID RF = (10 μA))1MΩ) = 10 V
The temp. sensitivity (S) of the
germanium diode is about 0.0333 μA/Co
Let us suppose that the temp. goes from
25 Co to 75 Co. Then the change in
current (∆ID) equals the change in temp.
(∆T) times the sensitivity:
 ∆ID = (∆T)(S) = (50 Co x 0.033 μA/Co)
= 1.67 μA
The total diode current at 75 Co equals
the change in current plus the current at
25 Co
ID(75Co) = ∆ID + ID(25Co) = 1.67 μA + 10 μA
= 11.67 μA
The output voltage at 75 Co is then
Vo = ID RF = (11.67 μA) x )l MΩ) = 11.67 V
 The transistor VBE depends on temp., varying
-2.25 mV/Co. For every Co increase in temp., VBE
will decrease by 2.25 mV.
 IC temperature sensors:
One of the most recent innovations in
thermometry is the IC temp. sensor.
The output of the IC (either voltage or
current) is directly proportional to temp.
Linearity exceeds that of the RTD.
Typical sensitivity value is 1 μA,/Co or 10
mV/Co (i.e. current mode or voltage mode)

Vo = S x temperature.
 AD590 manufactured by Analog Devices
sensitivity value is 1 μA,/Co or 10 mV/Co
LM335, which has an output equal to 10
mV/Ko.
National Semiconductor LM34 and LM35.
LM34 have an output voltage that is
linearly proportional to the Fahrenheit
temperature scale. Its output voltage
sensitivity is + 10 mV/Fo
 LM34 Temperature sensor
 The LM35 is similar to the LM34, but it
has a sensitivity of 10 mV/Co (i.e. works
with Celsius scale).
Both devices have a low output
impedance and a linear output voltage,
and both can be used with single or dual
power supply voltages.
Generally speaking, semiconductor
temperature sensors produce good
linearity, small in size and low in cost.