1. Advanced Sensor
Prepared By,
Gaurav Maniar
Karan Raithatha

2. Introduction
 Devices which perform an input function are commonly
called Sensors because they "sense" a physical change in some
characteristic that changes in response to some excitation, for
example heat or force and covert that into an electrical signal.
Devices which perform an output function are generally called
Actuators and are used to control some external device, for
example movement.
 Simple stand alone electronic circuits can be made to repeatedly
flash a light or play a musical note, but in order for an electronic
circuit or system to perform any useful task or function it needs
to be able to communicate with the "real world" whether this is
by reading an input signal from an "ON/OFF" switch or by
activating some form of output device to illuminate a single light.

3. Analogue & Digital
Sensors
 Analogue Sensor
 Analogue Sensors produce a continuous output signal or voltage which is
generally proportional to the quantity being measured. Physical quantities
such as Temperature, Speed, Pressure, Displacement, Strain etc are all
analogue quantities as they tend to be continuous in nature.
 Analogue sensors tend to produce output signals that are changing
smoothly and continuously which are very small in value so some form of
amplification is required. Then circuits which measure analogue signals
usually have a slow response and/or low accuracy.

4.  Digital Sensor
 Digital Sensors produce a discrete output signal or voltage that is a digital
representation of the quantity being measured. Digital sensors produce
a Binary output signal in the form of a logic "1" or a logic "0“. This means
then that a digital signal only produces discrete values which may be
outputted as “bit” or “byte”.
 Compared to analogue signals, digital signals or quantities have very high
accuracies and can be both measured and "sampled" at a very high clock
speed. The accuracy of the digital signal is proportional to the number of
bits used to represent the measured quantity.

5. Position Sensor
 As their name implies, these types of sensors provide a "position"
feedback. One method of determining a position, is to use either
"distance", which could be the distance between two points such as
the distance travelled or moved away from some fixed point, or by
"rotation“.
 Potentiometer:- The most commonly used of all the "Position
Sensors", is the potentiometer because it is an inexpensive and easy
to use position sensor.
 Inductive Position Sensor:- One type of positional sensor that
does not suffer from mechanical wear problems is the "Linear
Variable Differential Transformer" or LVDT for short. This is an
inductive type position sensor which works on the same principle as
the AC transformer that is used to measure movement.
 Inductive Proximity Sensor:- Another type of inductive sensor in
common use is the Inductive Proximity Sensor also called an Eddy

6. Si m e Posi t i on Sensi ng C r cui t
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LVDT I nduct i ve Pr oxi m t y Sensor
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7. Temperature Sensor
 Temperature sensor vary from simple ON/OFF thermostatic devices
which control a domestic hot water system to highly sensitive
semiconductor types that can control complex process control plants.
 Temperature Sensors measure the amount of heat energy or even
coldness that is generated by an object or system, and can "sense"
or detect any physical change to that temperature producing either
an analogue or digital output.
 Temperature sensors consist of two basic physical types:-
1)Contact Temperature Sensor:- These types of temperature
sensor are required to be in physical contact with the object
being sensed and use conduction to monitor changes in
temperature.
2)Non-contact Temperature Sensor:- These types of
temperature sensor use convection and radiation to monitor
changes in temperature.

8. • Thermostat:- The Thermostat is a contact type electro-mechanical
temperature sensor or switch, that basically consists of two different
metals such as nickel, copper, tungsten or aluminum etc, that are
bonded together to form a Bi-metallic strip.
• Thermistor:- The Thermistor is another type of temperature
sensor, whose name is a combination of the words THERM-ally
sensitive res-ISTOR. A thermistor is a type of resistor which changes
its physical resistance with changes in temperature.
• Resistive Temperature Detector:- Another type of electrical
resistance temperature sensor is the Resistance Temperature
Detector or RTD. RTD's are precision temperature sensors made
from high-purity conducting metals such as platinum, copper or
nickel wound into a coil and whose electrical resistance changes as
a function of temperature.
• Thermocouple:- The Thermocouple is by far the most commonly
used type of all the temperature sensing devices due to its
simplicity, ease of use and their speed of response to changes in
temperature, due mainly to their small size. Thermocouples also

9. Light Sensor
 A Light Sensor generates an output signal indicating the intensity of
light by measuring the radiant energy that exists in a very narrow
range of frequencies basically called "light", and which ranges in
frequency from "Infrared" to "Visible" up to "Ultraviolet" light
spectrum.
 The light sensor is a passive devices that convert this "light energy"
whether visible or in the infrared parts of the spectrum into an
electrical signal output. Light sensors are more commonly known as
"Photoelectric Devices" or "Photo Sensors" because the convert light
energy into electricity .
 Light Sensors are classified in four types:
1)Photo Emissive Cells:- These are photo devices which release
free electrons from a light sensitive material such as cesium
when struck by a photon of sufficient energy.
2)Photo Conductive Cells:- These photo devices vary their

10. 3) Photo Voltaic Cells:- These photo devices generate an emf in
proportion to the radiant light energy received and is similar in
effect to photoconductivity. Light energy falls on to two
semiconductor materials sandwiched together creating a voltage.
4) Photo Junction Devices:- These photo devices are mainly true
semiconductor devices such as the photodiode or phototransistor
which use light to control the flow of electrons and holes across
their PN-junction. Photo junction devices are specifically designed
for detector application and light penetration with their spectral
response tuned to the wavelength of incident light.

11. • Light Dependant Resistor:- As its name implies, the Light
Dependant Resistor (LDR) is made from a piece of exposed
semiconductor material such as cadmium sulphide that changes its
electrical resistance from several thousand Ohms in the dark to only a
few hundred Ohms when light falls upon it by creating hole-electron
pairs in the material. The net effect is an improvement in its conductivity
with a decrease in resistance for an increase in illumination. Also, photo
resistive cells have a long response time requiring many seconds to
respond to a change in the light intensity.

12. • Phototransistor:- An alternative photo-junction device to the
photodiode is the Phototransistor which is basically a photodiode with
amplification. The Phototransistor light sensor has its collector-base PN-
junction reverse biased exposing it to the radiant light source.
Phototransistors operate the same as the photodiode except that they
can provide current gain. Phototransistors consist mainly of a
bipolar NPN Transistor with its large base region electrically
unconnected, although some phototransistors allow a base connection
to control the sensitivity, and which uses photons of light to generate a
base current which inturn causes a collector to emitter current to flow.
Most phototransistors are NPN types.

13. • Photo-Darlington:- Photo Darlington transistors use a second bipolar
NPN transistor to provide additional amplification or when higher
sensitivity of a photo detector is required due to low light levels or
selective sensitivity, but its response is slower than that of an ordinary
NPN phototransistor. Photo Darlington devices consist of a normal
phototransistor whose emitter output is coupled to the base of a larger
bipolar NPN transistor. Because a Darlington transistor configuration
gives a current gain equal to a product of the current gains of two
individual transistors, a photo Darlington device produces a very
sensitive detector.

14. Motion Sensor
 A motion detector is a device for motion detection. That is, it is a
device that contains a physical mechanism or electronic sensor that
quantifies motion that can be either integrated with or connected to
other devices that alert the user of the presence of a moving object
within the field of view.
 An electronic motion detector contains a motion sensor that
transforms the detection of motion into an electric signal. This can
be achieved by measuring optical or acoustical changes in the field
of view.
 An occupancy sensor is a motion detector that is integrated with a
timing device. It senses when motion has stopped for a specified
time period in order to trigger a light extinguishing signal.

15. • Passive Infrared Sensor:- A Passive Infrared sensor (PIR sensor) is
an electronic device that measures infrared (IR) light radiating from
objects in its field of view. PIR sensors are often used in the
construction of PIR-based motion detectors. Apparent motion is
detected when an infrared source with one temperature, such as
a human, passes in front of an infrared source with another
temperature, such as a wall. All objects above absolute zero emit
energy in the form of radiation. Usually infrared radiation is invisible to
the human eye but can be detected by electronic devices designed for
such a purpose. The term passive in this instance means that the PIR
device does not emit an infrared beam but merely passively accepts
incoming infrared radiation. “Infra” meaning below our ability to detect
it visually, and “Red” because this color represents the lowest energy
level that our eyes can sense before it becomes invisible.

16. • Ultrasonic Sensor:- Ultrasonic sensors work on a principle similar
to radar or sonar which evaluate attributes of a target by interpreting the
echoes from radio or sound waves respectively. Ultrasonic sensors
generate high frequency sound waves and evaluate the echo which is
received back by the sensor. Sensors calculate the time interval between
sending the signal and receiving the echo to determine the distance to
an object. Systems typically use a transducer which generates sound
waves in the ultrasonic range, above 18,000 hertz, by turning electrical
energy into sound, then upon receiving the echo turn the sound waves
into electrical energy which can be measured and displayed.

17. THANK
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