temprature sensing major_project_report (2)
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Microcontroller Based Temperature Sensing And Controlling
INTRODUCTION
Our minor project involved the design of a fully functional TEMPERATURE SENSING
AND CONTROLLING USING MICROCONTROLLER 89S52.This was our attempt at
producing a portable device that could be widely used for a variety of different purposes.
For example, think of the many situations where the precise measurement of temperature is
of high importance. Temperature control and monitoring is important in homes for the
comfort of its occupants, it is important for gardeners who want to carefully monitor the
atmospheric conditions within greenhouse.
Furthermore, our portable digital thermometer could be valuable as a scientific tool in the
laboratory. Its ability to accurately measure temperature to within 1degree per celsius . As a
household device, our multi-functioning digital thermometer is useful for its ability to
carefully display the extreme temperatures reached in its environment. By simply pressing
the appropriate button on its user interface, you can easily set the reference value of
temperature.
This is accomplished by entering lower and upper bound temperatures via two push
buttons on the user interface. When the temperature recorded by this device crosses one of
these boundary points, the LED glows to indicate the rise or fall of temperature.Additional functionality has been added to this feature regarding the options for changing
these boundary temperatures. As the temperature rises above the reference temperature a
fan is switched on and as the temperature falls below the reference bulb starts glowing
indicating the fall in temperature. Thus the temperature can be monitored using
MICROCONTROLLER BASED TEMPERATURE SENSING AND CONTROLLING
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Basic Circuit for 8051
8051 PIN OUT
Power - Vcc, Vss
Reset - RST
Crystal - XTAL[1,2]
External device
interfacing
EA, ALE, PSEN, WR,
RD
I/O Port
P0[7;0], P1[7:0], P2[7:0], P3 FIG.1
P3 is shared with control lines
Serial I/O RxD, TxD,
external interrupts INT0, INT1
Counter control T0, T1
P0 and P2 are multiplexed with Address and Data bus
BASIC CIRCUIT -THAT MAKES 8051 works
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FIG.2
EA/VP Pin
The EA on pin 31 is tied high to make the 8051
executes program from Internal ROM
Reset Circuit
RESET is an active High input When RESET is set
to High, 8051 goes back to the power on state.
The 8051 is reset by holding the RST high for at least
two machine cycles and then returning it low.
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Power-On Reset
- Initially charging of capacitor makes RST High
- When capacitor charges fully it blocks DC.
Manual reset
-closing the switch momentarily will make RST High.
After a reset, the program counter is loaded with 0000H but the content of on-chip RAM is
not affected.
TABLE-1
Note: content of on-chip RAM is not affected by Reset.
Oscillator Circuit
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Register Content Register Content
Program counter 0000h IP XXX00000b
Accumulator 00h IEv 0XX00000b
B register 00h All timer registers 00h
PSW 00h SCON 00h
SP 07h SBUF 00h
DPTR 0000h PCON (HMOS) 0XXXXXXXbv
All ports FFh PCON (CMOS)v 0XXX0000b
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The 8051 uses the crystal for precisely that: to synchronize its operation. Effectively, the
8051 operates using what are called "machine cycles." A single machine cycle is the
minimum amount of time in which a single 8051 instruction can be executed. although
many instructions take multiple cycles.
8051 has an on-chip oscillator. It needs an external crystal thats decides the operating
frequency of the 8051.
This can be achieved in two ways,,
The crystal is connected to pins 18 and 19 with stabilizing capacitors. 12 MHz
(11.059MHz) crystal is often used and the capacitance ranges from 20pF to 40pF.
The oscillator can also be a TTL clock source connected with a NOT gate as shown
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How fast 8051 works ?
A cycle is, in reality, 12 pulses of the crystal. That is to say, if an instruction takes one
machine cycle to execute, it will take 12 pulses of the crystal to execute. Since we know
the crystal is pulsing 11,059,000 times per second and that one machine cycle is 12 pulses,
we can calculate how many instruction cycles the 8051 can execute per second:
11,059,000 / 12 = 921,583
Why is such an oddball crystal frequency?
11.0592 MHz crystals are often used because it can be divided to give you exact clock rates
for most of the common baud rates for the UART, especially for the higher speeds (9600,19200). Despite the "oddball" value, these crystals are readily available and commonly
used.
Power Supply
C1-1000 mf ,C2-100 mf
The 78L05 is a 5V regulator. The input voltage ranges from 7V to 35V and the output
voltage is about 5V.
FIG.3
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PORT FUNCTIONS
Ports purpose
Port 0
(Pin 32-39)
Dual-purpose port- 1. general purpose I/O Port.
2. multiplexed address & data
bus
Open drain outputs
Port 1
(Pin 1-8)
Dedicated I/O port Used solely for interfacing to external
devices
Internal pull-ups
Port 2
(Pin 21-28)
Dual-purpose port- 1. general purpose I/O port.
2. a multiplexed address & data bus.
Internal pull-ups
Port 3
(Pin 10-17)
Dual-purpose port- 1. general purpose I/O port.
2. pins have alternate purpose related to
special features of the 8051
Internal pull-ups
TABLE-2
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The 8051 internal ports are partly bi-directional (Quasi-bi-directional). The following is the
internal circuitry for the 8051 port pins:
FIG.4
1.Configuring for output
P0 is open drain.
Has to be pulled high by external 10K resistors.
Not needed if P0 is used for address lines
Writing to a port pin loads data into a port latch that drives a FET connected to the port pin.
P0: Note that the pull-up is absent on Port 0 except when functioning as the external
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address/data bus. When a "0" is written to a bit in port 0, the pin is pulled low. But when a
"1" is written to it, it is in high impedance (disconnected) state. So when using port 0 for
output, an external pull-up resistor is needed, depending on the input characteristics of the
device driven by the port pin
P1, P2, P3 have internal pull-ups: When a "0" is written to a bit in these port , the pin is
pulled low ( FET-ON) ,also when 1 is written to a bit in these port pin becomes high (FET-
OFF) thus using port P1,P2,P3 is simple.
2. Configuring for input
At power-on all are output ports by default
To configure any port for input, write all 1s (0xFF) to the portLatch bit=1, FET=OFF, Read Pin asserted by read instruction
You can used a port for output any time. But for input, the FET must be off. Otherwise,
you will be reading your own latch rather than the signal coming from the outside.
Therefore, a "1" should be written to the pin if you want to use it as input, especially when
you have used it for output before. If you don't do this input high voltage will get grounded
through FET so you will read pin as low and not as high. An external device cannot easily
drive it high
so, you should not tide a port high directly without any resistor. Otherwise, the FET would
burn.
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MICROCONTROLLER (89S52)
Description
The AT89S52 is a low-power, high-performance CMOS 8-bit microcontroller with 4K
bytes of In-System Programmable Flash memory. The device is manufactured using
Atmels high-density nonvolatile memory technology and is compatible with the industry-
standard 80C51 instruction set and pinout. The on-chip Flash allows the program memory
to be reprogrammed in-system or by a conventional nonvolatile memory programmer. By
combining a versatile 8-bit CPU with In-System Programmable Flash on a monolithic chip,
the Atmel AT89s52 is a powerful microcontroller, which provides a highly flexible and
cost-effective solution to many embedded control applications. The AT89s52 provides the
following standard features: 4K bytes of Flash, 128 bytes of RAM, 32 I/O lines, Watchdog
timer, two data pointers, two 16-bit timer/counters, a five vector two-level interrupt
architecture, a full duplex serial port, on-chip oscillator, and clock circuitry. In addition, the
AT89s52 is designed with static logic for operation down to zero frequency and supports
two software selectable power saving modes. The Idle Mode stops the CPU while allowing
the RAM; timer/counters, serial port, and interrupt system to continue functioning. The
Power-down mode saves the RAM contentsBut freezes the oscillator, disabling all other chip functions until the next external
interrupt or hardware reset.
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Port 1: Port 1 is an 8-bit bi-directional I/O port with internal pull-ups. The Port 1 output
buffers can sink/source four TTL inputs. When 1s are written to Port 1 pins, they are pulled
high by the internal pull-ups and can be used as inputs. As inputs, Port 1 pins that are
externally being pulled low will source current (IIL) because of the internal pull-ups.
Port 1 also receives the low-order address bytes during Flash programming and
verification.
Port 2: Port 2 is an 8-bit bi-directional I/O port with internal pull-ups. The Port 2 output
buffers can sink/source four TTL inputs. When 1s are written to Port 2 pins, they are pulled
high by the internal pull-ups and can be used as inputs. As inputs, Port 2 pins that are
externally being pulled low will source current (IIL) because of the internal pull-ups.
Port 2 emits the high-order address byte during fetches from external program memory and
during accesses to external data memory that use 16-bit addresses (MOVX @ DPTR). In
this application, Port 2 uses strong internal pull-ups when emitting 1s. During accesses to
external data memory that use 8-bit addresses (MOVX @ RI), Port 2 emits the contents of
the P2 Special Function Register.
Port 2 also receives the high-order address bits and some control signals during Flash
programming and verification.
Port 3: Port 3 is an 8-bit bi-directional I/O port with internal pull-ups. The Port 3 output
buffers can sink/source four TTL inputs. When 1s are written to Port 3 pins, they are pulled
high by the internal pull-ups and can be used as inputs. As inputs, Port 3 pins that are
externally being pulled low will source current (IIL) because of the pull-ups.
Port 3 receives some control signals for Flash programming and verification.
Port 3 also serves the functions of various special features of the AT89s52.
RST Reset input: A high on this pin for two machine cycles while the oscillator is running
resets the device. This pin drives High for 98 oscillator periods after the Watchdog times
out. The DISRTO bit in SFR AUXR (address 8EH) can be used to disable this feature. In
the default state of bit DISRTO, the RESET HIGH out feature is enabled.
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ALE/ PROGAddress Latch Enable (ALE): is an output pulse for latching the low byte
of the address during accesses to external memory. This pin is also the program pulse input
(PROG) during Flash programming.
In normal operation, ALE is emitted at a constant rate of 1/6 the oscillator frequency and
may be used for external timing or clocking purposes. Note, however, that one ALE pulse
is skipped during each access to external data memory.
If desired, ALE operation can be disabled by setting bit 0 of SFR location 8EH. With the
bit set, ALE is active only during a MOVX or MOVC instruction. Otherwise, the pin is
weakly pulled high. Setting the ALE-disable bit has no effect if the microcontroller is in
external execution mode.
PSEN Program Store Enable (PSEN): is the read strobe to external program memory.
When the AT89s52 is executing code from external program memory, PSEN is activated
twice each machine cycle, except that two PSEN activations are skipped during each access
to external data memory.
EA/VPP External Access Enable: EA must be strapped to GND in order to enable the
device to fetch code from external program memory locations starting at 0000H up to
FFFFH. Note, however, that if lock bit 1 is programmed, EA will be internally latched on
reset.
EA should be strapped to VCC for internal program executions.
This pin also receives the 12-volt programming enable voltage (VPP) during Flash
programming.
XTAL1: Input to the inverting oscillator amplifier and input to the internal clock operating
circuit.
XTAL 2: Output from the inverting oscillator amplifier
Port Pin Alternate Functions
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P3.0 RXD (serial input port)
P3.1 TXD (serial output port)
P3.2 INT0 (external interrupt 0)
P3.3 INT1 (external interrupt 1)
P3.4 T0 (timer 0 external input)
P3.5 T1 (timer 1 external input)
P3.6 WR (external data memory write strobe)
P3.7 RD (external data memory read strobe)
Special Function Registers:
A map of the on-chip memory area called the Special Function Register (SFR). Note that
not all of the addresses are occupied, and unoccupied addresses may not be implemented
on the chip. Read accesses to these addresses will in general return random data, and write
accesses will have an indeterminate effect.
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General PCB
Process followed While Making Printed Circuit Board :
Step#1 Film Generation:
Generated from the design
files, we create an exact film
representation of the design.
We will create one film per
layer.
Step#2 Shear Raw Material:
Industry standard 0.059" thick,
copper clad, two sides. Panels
will be sheared to
accommodate many boards.
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Step#3 Drill Holes:
Using NC machines and
carbide drills.
Step#4 Electroless Copper:
Apply thin copper deposit in
hole barrels.
Step#5 Apply Image:
Apply photosensitive dryfilm
(plate resist) to panel. Use
light source and film to expose
panel. Develop selected areas
from panel.
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Step#6 Pattern Plate:
Electrochemical process to
build copper in the holes and
on the trace area. Apply tin to
surface.
Step#7 Strip & Etch:
Remove dryfilm, then etch
exposed copper. The tin
protects the copper circuitry
from being etched.
Step#8 Solder mask:
Apply solder mask area to
entire board with the
exception of solder pads.
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Step#9 Solder coat:
Apply solder to pads by
immersing into tank of solder.
Hot air knives level the solder
when removed from the tank.
Step#10 Nomenclature:
Apply white letter marking
using screen printing process
Step#11 Fabrication:
Route the perimeter of the
board using NC equipment
FIG.6
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SOLDERING
How to Solder
First a few safety precautions:
Never touch the element or tip of the soldering iron.
They are very hot (about 400C) and will give you a nasty burn.
Take great care to avoid touching the mains flex with the tip of the iron. The
iron should have a heatproof flex for extra protection. An
ordinary plastic flex will melt immediately if touched by a hot iron and there
is a serious risk of burns and electric shock.
Always return the soldering iron to its stand when not in use.
Never put it down on your workbench, even for a moment!
Work in a well-ventilated area.
The smoke formed as you melt solder is mostly from the
flux and quite irritating. Avoid breathing it by keeping
you head to the side of, not above, your work.
Wash your hands after using solder.
Solder contains lead which is a poisonous metal.
Preparing the soldering iron:
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Place the soldering iron in its stand and plug in.
The iron will take a few minutes to reach its operating temperature of about 400C.
Dampen the sponge in the stand.
The best way to do this is to lift it out the stand and hold it under a cold tap for a
moment, then squeeze to remove excess water. It should be damp, not dripping wet.
Wait a few minutes for the soldering iron to warm up.
You can check if it is ready by trying to melt a little solder on the tip.
Wipe the tip of the iron on the damp sponge. This will clean the tip.
Melt a little solder on the tip of the iron.
This is called 'tinning' and it will help the heat to flow from the iron's tip to the joint. It
only needs to be done when you plug in the iron, and occasionally while soldering if
you need to wipe the tip clean on the sponge.
You are now ready to start soldering:
Hold the soldering iron like a pen,
near the base of the handle.
Imagine you are going to write your
name! Remember to never touch the
hot element or tip.
Touch the soldering iron onto the
joint to be made.
Make sure it touches both thecomponent lead and the track. Hold the tip there for a few seconds and...
Feed a little solder onto the joint.
It should flow smoothly onto the lead and track to form a volcano shape as shown in
the diagram. Apply the solder to the joint, not the iron.
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Remove the solder, then the iron, while keeping the joint still.
Allow the joint a few seconds to cool before you move the circuit board.
Inspect the joint closely.
It should look shiny and have a 'volcano' shape. If not, you will need to reheat it and
feed in a little more solder. This time ensure that both the lead and track are heated
fully before applying solder.
.
Using a heat sink
Some components, such as transistors, can be damaged by heat when soldering so if you
are not an expert it is wise to use a heat sink clipped to the lead between the joint and the
component body. You can buy a special tool, but a standard crocodile clip works just as
well and is cheaper.
What is solder?
Solder is an alloy (mixture) of tin and lead, typically 60% tin and 40% lead. It melts at a
temperature of about 200C. Coating a surface with solder is called 'tinning' because of the
tin content of solder. Lead is poisonous and you should
always wash your hands after using solder. Solder for electronics use contains tiny cores of
flux, like the wires inside a mains flex. The flux is corrosive, like an acid, and it cleans the
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metal surfaces as the solder melts. This is why you must melt the solder actually on the
joint, not on the iron tip. Without flux most joints would fail because metals quickly
oxidise and the solder itself will not flow properly onto a dirty, oxidised, metal surface.
ADC 0804
Analog signals are very common inputs to embedded systems .Most transducers and
sensors such as temperature ,pressure ,velocity ,humidity are analog. Therefore we need to
convert these analog signals in to digital so that 8051 can read it.
ANALOG DIGITAL TO CONVERTER - ADC
Commonly used ADC device ADC804
ABOUT IC
PinOut
CS Chip Select , active low
RD Read Digital data from ADC, H-L edge triggered
WR -- Start conversion, L-H pulse edge triggered
INTR -- end of conversion, Goes low to indicate conversion done
Data bits -- D0-D7
CLK IN & CLK R
CLK IN is an input pin connected to an external clock source when an external clock is
used for timing. However, ADC804 has an internal clock
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generator.
To use the internal clock generator of the ADC804, the CLK IN and CLK R pins are
connected to a capacitor and a resistor. In that case, the
clock frequency is determined by the equation.
f = 1/1.1RC
R=10K and C=150pF f=606Hz
the conversion time is 110us.
Input Voltage range
Default 0-5V. Can be changed by setting
different value for Vref/2 pin.
Vin=Vin(+) Vin (-)
Range = 0 to 2x Vref/2.
for Vin = 2x Vref/2. we get 256 as a digital output on D0-D7. (Refer Table)
TABLE-3
Step Size a Smallest change
(2 x Vref/2)/ 256 for ADC804
for eg for step size 10mv ,digital output on D0-D7 changes by one count for every 10mv
change of the input analog voltage.
Data Out
Dout = Vin / Step Size
for input vtg. of 2.56 volts (Vref=1.28 volts) and stepsize of 10mv Dout =2560/10 =256
or FF that is full scale output.
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Vref/2
(Volts)
Vin
(Volts)
Step size (mV)
Open (2.5) 0 to 5 5/256 = 19.53
2.56 0 to 5.12 5.12/256 =20
1.28 0 to 2.56 2.56/256 = 10
0.5 0 to 1 1/256=3.90
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Conversion Time
Greater than 110us for ADC804
Resolution
8 bits for ADC804
INTERFACING TO MICROCONTROLLER USING ADC0804
FIG.7
The ADC804 has 8-bit resolution with a maximum of 256 steps and the LM35 produces
10mV for every degree of temperature change.
We will do calibration such that ,
for temperature range of 0 to 100C , voltage in at the input of ADC will be 0 to 2.56 v.
we need to set Vref/2 = 1.28V
so step size will be 2560mv/256 = 10mv
also for every degree change in temp. LM35 output changes by 10mv ,so every degree
change in temp. will produce 1 unit change in digital out of ADC
Thus resolution of our system will be 1deg C , which is Smallest temp. that we can
measure with this system.
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CALIBRATION
For Temperature range 0 to 100C Output voltage 0V to 1V
Required gain of amplifier Required Max. voltage input for ADC / Vout
at LM35 = 2560mv /100mv =2.56
Use preset for R2 --> 5.12KOhms so gain =R3/R2 =2.56
Although our theoretical design is correct , operational amplifiers are often needed to to becalibrated practically , what i mean to say is that you need to adjust gain of amp. (Adjusting
pot -R2) so that we get designed output at various temperature. That is if current temp. is
25C , LM35 output will be 250mv and amp. output should be 250x2.56 =0.64v . if it is
not, adjust R2.
LM35 has a limited ability
to drive heavy capacitive loads. The LM35 by itself is able to drive 50 pf without special
precautions. you can improve the tolerance of capacitance with a series R-C damper from
output to ground.
2. P100 Platinum resistance temp. detector .
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PT 1 00 - platinum resistance temp. detector (PRTD) . PT 1 00 has a resistance of 100 W at
zero deg. Celsius .
Linear
Sensitivity-a0 =0.00385W/ deg. Celsius
Response time - 0.5 to 5 s or more.
DESIGN (0 to 85 deg. cel.)
1) R1*R4 = R2*R3 -----BRIDGE BALANCE CONDITION
2) Rt = Ro [ 1 + a T] ----- RESISTANCE VARIATION FOR RTD
3) Vab = V*R3 / ( R1 + R3 ) - VR4 /( R2 + R4 ) --- BRIDGE
OUTPUT (V=5v)4) Vo = R2 / R1 ( Va Vb )---- GAIN OF INSTRUMENTATION AMPLIFIER
1. At 0oC
R1=R2=R3 =R4(100 W RTD )=100 ohms.
so bridge is
balance -o/p vtg
0v
2.At 85
oC
R85 = 100 ( 1 + 0.00385 [ 85 ] )
= 132.72 ohms FIG.8
Bridge output
Vab = 0.35V. (FOR R1=R2=R3=100ohms)
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3.Gain of Amplifier
Vo = R2 / R1 ( Va Vb )
For Vab = 0.351 & Vo = 0.351 V at 85 deg. Cel.
A = R2 / R1 = 14.62
For R1 = 1 k ohm ; We let R2 = 14.62 K ohm approx. R2 = 15 k ohm(use
preset).
Since the change in resistance of RTD w.r.t. temp.is linear , the change in bridge output is
also linear w.r.t. temp. i.e. change in temp. from 0 to 85 deg. Cel. causes bridge output to
change from 0 to 0.351 V.
I have given Ref voltage of 5.12 v to ADC chip so step size will be ,5120mV/256 (8 bit
ADC) =20 mV.
So bridge output voltage in the range 0 to 0.351 V corresponding to 0 to 85oC change in
temperature is converted in to 0 to 5.12V using Amplifier having gain of 14.62 .Interfacing is same as that I have shown in ADC-DAC page .
PROGRAM LOGIC:
Output of an ADC is from 00 TO FFH for an input voltage variation of 0 to 5.12V. I used
lookup table method to display the proper temperature. For this,I prepare a lookup table of
256 values(00 to FF)i.e output of ADC.. An small example of a lookup table has been
shown below. Values corresponding to output of ADC are selected from lookup table and
displayed.
CONCEPT FOR LOOK- UP TABLE:
ADC OUTPUT TEMPERATURE IN DEG.CEL
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0000 00
0001 00
0002 00
0003 01
0004 01
0005 01Cntd
00FE 85
00FF 85
TABLE-4
INTERFACING ADC804 TO 8051
FIG.9
Signals to be interfaced (on the ADC804)
D0-D7, RD, WR, INTR, CS
Can do both Memory mapping and IO mapping
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Microcontroller Based Temperature Sensing And Controlling
Memory Mapping (timing is critical)
Connect D0-D7 of ADC804 to the data bus of the 8051 system
Connect RD, WR of the ADC804 to the 8051 system (ensure polarity)
Connect CS of ADC804 to an appropriate address decoder output
Connect INTR of ADC804 to an external interrupt Pin on the 8051 (INT0 or INT1)
IO Mapping (easiest - I prefer )
Connect D0-D7, RD, WR, CS, INTR to some port bits on the 8051 (12 in all).
Algorithm
Make CS=0 and send a low-to-high to pin WR to start the conversion.
Keep monitoring INTR
If INTR =0, the conversion is finished and we can go to the next step.
If INTR=1, keep polling until it goes low.
After INTR=0, we make CS=0 and send a high-to-low pulse to RD to get the data
out of the ADC804
30Swami Devi Dyal Institute Of Engineering And Technology
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Microcontroller Based Temperature Sensing And Controlling
SENSORS INTERFACING
Transducer is a device capable of being actuated by an an energizing input from one or
more transmission media and in turn generating a related signal to one or more
transmission systems. It provides a usable output in response to specified inputmeasurand , which may be in the form physical, chemical, Mechanical or optical....
For eg. temperature transducer transduces temp. changes to equivalent resistance changeswhich can further converted into electrical signal (voltage) for measurements.
TEMPERATURE
1. LM35 Precision temperature sensor
LM34 series are precision integration-circuit temperature sensors whose output voltage is
linearly proportional to the Fahrenheit temperature.
FIG.10
LM35 series are precision integration-circuit temperature sensors whose output voltage is
linearly proportional to the Celsius temperature.
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Microcontroller Based Temperature Sensing And Controlling
P/NTemperature
Range (oC)Accuracy (Oc) Output (mv/oC)
LM35A -55 to 150 1.0 10
LM35 -55to 150 1.5 10
LM35CA -40 to 110 1.0 10
LM35C -40 to 110 1.5 10
LM35D 0 to 100 2.0 10
TABLE-5
I am using LM35DT package to operate over a 0 to +100C temperature range
FIG.11
R5 and C3 are used for capacitive load compensation.
Features
n Calibrated directly in Celsius (Centigrade)n Linear + 10.0 mV/C scale factorn 0.5C accuracy guarantee able (at +25C)n Rated for full -55 to +150C rangen Suitable for remote applicationsn Low cost due to wafer-level trimming
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Microcontroller Based Temperature Sensing And Controlling
n Operates from 4 to 30 voltsn Less than 60 A current drainn Low self-heating, 0.08C in still airn Nonlinearity only 1.4C typical
n Low impedance output, 0.1 for 1 mA load