cell phone operated vehicle

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Cell Phone Operated Vehicle CHAPTER 1 INTRODUCTION In this project, the robot is controlled by a mobile phone that makes a call to the mobile phone attached to the robot. In the course of a call, if any button is pressed, a tone corresponding to the button pressed is heard at the other end of the call. This tone is called dual-tone multiple-frequency (DTMF) tone. The robot perceives this DTMF tone with the help of the phone stacked in the robot The received tone is processed by the microcontroller with the help of DTMF decoder MT8870 .The decoder decodes the DTMF tone into its equivalent binary digit and this binary number is sent to the microcontroller. The microcontroller is pre programmed to take a decision for any given input and outputs its decision to motor drivers in order to drive the motors for forward or backward motion or a turn. The mobile that makes a call to the mobile phone stacked in the robot acts as a remote. So this simple robotic project does not require the construction of receiver and transmitter units. 1.1 LITERATURE SURVEY The First Remote Control Vehicle / Precision Guided Weapon: 1

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Page 1: Cell Phone Operated Vehicle

Cell Phone Operated Vehicle

CHAPTER 1

INTRODUCTION

In this project, the robot is controlled by a mobile phone that makes a call to the mobile

phone attached to the robot. In the course of a call, if any button is pressed, a tone

corresponding to the button pressed is heard at the other end of the call. This tone is called

dual-tone multiple-frequency (DTMF) tone. The robot perceives this DTMF tone with the

help of the phone stacked in the robot

The received tone is processed by the microcontroller with the help of DTMF decoder

MT8870 .The decoder decodes the DTMF tone into its equivalent binary digit and this binary

number is sent to the microcontroller. The microcontroller is pre programmed to take a

decision for any given input and outputs its decision to motor drivers in order to drive the

motors for forward or backward motion or a turn. The mobile that makes a call to the mobile

phone stacked in the robot acts as a remote. So this simple robotic project does not require

the construction of receiver and transmitter units.

1.1 LITERATURE SURVEY

The First Remote Control Vehicle / Precision Guided Weapon:

This propeller –driven radio controlled boat, built by Nikola Tesla in 1898, is the

original prototype of all modern-day uninhabited aerial vehicles and precision guided

weapons. In fact, all remotely operated vehicles in air, land or sea. Powered by lead-

acid batteries and an electric drive motor, the vessel was designed to be maneuvered

alongside target using instructions received from a wireless remote-control

transmitter. Once in position, a command would be sent to detonate an explosive

charge contained within the boat’s forward compartment. The weapon’s guidance

system incorporated a secure communications link between the pilot’s controller and

the surface-running torpedo in an effort to assure that control could be maintained

even in the presence of electronic countermeasures. To learn more about tesla’s

system for secure wireless communications and his pioneering implementation of the

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electronic logic-gate circuit read ‘Nikola Tesla-Guided Weapons & Computer

Technology’, Tesla Presents Series Part 3, with commentary by Leland Anderson.

Use Of Remote Controlled Vehicles During World War II:

During World War II European Theater the U.S. Air Force experimented with three

basic forms radio-control guided weapons. In each case, The weapon would be

directed to its target by a crew member on a control plane. The first weapon was

essentially a standard bomb fitted with steering controls. The next evolution involved

The fitting of a bomb to a glider airframe, one version, the GB-4 having a TV camera

to assist the controller with targeting. The third class of guided weapon was the

remote controlled B-17.

It’s known that Germany deployed a number of more advanced guided strike

weapons that saw combat before either the V-1 or V-2. They were the radio-

controlled Henschel’s Hs 293A and Ruhrstahl’s SD1400X, known as “Firtz X,” both

air-launched, primarily against ships at sea.

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SYSTEM REQUIREMENTS

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CHAPTER 2

SYSTEM REQUIREMENTS:

2.1 HARDWARE REQUIREMENTS:

2.1.1 LM358 AMPLIFIER:

Description:

The LM158 series consists of two independent, high gain, internally frequency compensated

operational amplifiers which were designed specifically to operate from a single power

supply over a wide range of voltages. Operation from split power supplies is also possible

and the low power supply current drain is independent of the magnitude of the power supply

voltage. Application areas include transducer amplifiers, dc gain blocks and all the

conventional op amp circuits. Which now can be more easily implemented in single power

supply systems. For example, the LM158 series can be directly operated off of the standard

+5V power supply voltage which is used in digital systems and will easily provide the

required interface electronics without requiring the additional ±15V power supplies.

The LM358 and LM2904 are available in a chip sized package (8-Bump DSBGA) using TI's

DSBGA package technology.

Fig 2.1: LM358 Operational Amplifier

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2.1.2 DUAL-TONE MULTI-FREQUENCY (DTMF):

DTMF is a generic communication term for touch tone (a Registered Trademark of AT&T).

The tones produced when dialing on the keypad on the phone could be used to represent the

digits, and a separate tone is used for each digit. However, there is always a chance that a

random sound will be on the same frequency which will trip up the system. It was suggested

that if two tones were used to represent a digit, the likelihood of a false signal occurring is

ruled out. This is the basis of using dual tone in DTMF communications. DTMF dialing uses

a keypad with 12/16 buttons. Each key pressed on the phone generates two tones of specific

frequencies, so a voice or a random signal cannot imitate the tones. One tone is generated

from a high frequency group of tones and the other from low frequency group. The

frequencies generated on pressing different phone.

Features:

• Complete DTMF Receiver

• Low power consumption

• Internal gain setting amplifier

• Adjustable guard time

• Central office quality

Applications

• Receiver system for British Telecom (BT) or CEPT Spec (MT8870D

• Paging systems

• Repeater systems/mobile radio

• Credit card systems

• Remote control

• Personal computers

• Telephone answering machine

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Description:

An MT8870 series DTMF decoder is used here. The MT8870D/MT8870D-1 is a complete

DTMF receiver integrating both the band split filter and digital decoder functions. The filter

section uses switched capacitor techniques.

Fig 2.3: DTMF Keypad Frequencies(With Sound Clips)

There are four frequencies associated with the four rows, and three frequencies associated

with the three columns. Each key then specifies two frequencies. The DTMF signal for that

key is the sum of two sinusoidal waves, one at each frequency. So for example, the digit '4'

translates into a sound with two tones, one at 770 Hz. and the other at 1209 Hz.

2.1.2 H-BRIDGE:

An H-bridge is an arrangement of transistors that allows a circuit full control over a standard

electric DC motor. That is, with an H-bridge a microcontroller, logic chip, or remote control

can electronically command the motor to go forward, reverse, brake, and coast.

The basic H-bridge that is a good choice for most robots (including BEAM robots) and

portable gadgets. This H-bridge can operate from a power source as low as two nearly-

exhausted 'AAA' batteries (2.2V) all the way up to a fresh 9V battery (9.6V).

The H-bridge circuit (below) looks complicated at first glance, but it is really just four copies

of a resistor + transistor + diode.

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Fig 2.4: Schematic of a bipolar transistor h-bridge circuit to drive a DC motor

There are many different ways to draw the circuitry, but the above wiring diagram matches

the model of most H-bridges.

Q1, Q3: These are NPN transistors. They connect the motor to ground (negative terminal of

the battery).

Q2, Q4: These are PNP transistors. They connect the motor to +2.2V to +9.6V (positive

terminal of the battery).

R1-R4: These resistors prevent too much current from passing through the base (labeled B)

control pin of the transistor. The resistor value of 1 kiloohm (1kΩ) was chosen to provide

enough current to fully turn on (saturate) the transistor. A higher resistance would waste less

power, but might cause the motor to receive less power. A lower resistance would waste

more power, but wouldn't likely provide better performance for motors running on consumer

batteries.

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D1-D4: Diodes provide a safe path for the motor energy to be dispersed or returned to the

battery when the motor is commanded to coast or stop.

M1: This is a direct-current (DC) motor. These are very common. And can find them in

surplus stores online or in salvaged toys. The motor should have only two wires. Measure the

resistance of the two motor wires using a multimeter. If it is much less than 5 ohms, then the

transistor parts listed in this article are too weak to power the motor.

Controlling the H-bridge motor driver

The resistors are the inputs that control the H-bridge. By connecting a resistor to either

+VDC or GND, it turns on or off the corresponding transistor. (+VDC is the positive end of

the battery. GND is the negative end of the battery.) When a particular pair of transistors is

turned on, the motor does something.

Table 2.1:Controlling H-Bridge

Command R1 R2 R3 R4

Coast/Roll/Off: GND or disconnected

+VDC or disconnected

GND or disconnected

+VDC or disconnected

Forward: GND or disconnected

GND +VDC +VDC or disconnected

Reverse: +VDC +VDC or disconnected

GND or disconnected

GND

Brake/Slow Down:

+VDC +VDC or disconnected

+VDC +VDC or disconnected

Since there are 4 resistors, there are actually sixteen possible ways this circuit can be

commanded. Never apply +VDC to R1 and GND to R2 at the same time.

Never apply +VDC to R3 and GND to R4 at the same time, Battery get short circuited.

As for the other parts, the resistors (R1-R4) in the H-bridge can be almost any brand,

material, or wattage. The maximum current passing through them will be about 9 mA, so

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wattage isn't a concern. Also, the resistance doesn't have to be exactly 1000 ohms, so

precision isn't a concern.

The diodes (D1-D4) can be any of the commonly used parts: 1N914, 1N4001, or 1N5817.

The 1N5817 is superior, and This type of motor driver is used, The motor driver circuit is

laid out on a solderless breadboard in the photograph below. The only tricky part is to note

the orientation of the transistors. The top transistors (Q4 and Q2) are flat-side down. The

bottom transistors (Q3 and Q1) are flat-side up.

Fig 2.5: Bipolar transistor H-Bridge motor driver circuit on a solderless breadboard.

Connect the positive end of a battery to the very top row of the board (+VDC). Connect the

negative end of a battery to the very bottom row of the board (+GND).

To try it out, connect a wire from GND to the right-side of R2. Then, connect a wire from

+VDC to the left-side of R3. The motor should spin forward.

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2.1.3 DC MOTOR:

A DC motor relies on the fact that like magnet poles repel and unlike magnetic poles attract

each other. A coil of wire with a current running through it generates an electromagnetic field

aligned with the center of the coil. By switching the current on or off in a coil its magnet field

can be switched on or off or by switching the direction of the current in the coil the direction

of the generated magnetic field can be switched 180°. A simple DC motor typically has a

stationary set of magnets in the stator and an armature with a series of two or more windings

of wire wrapped in insulated stack slots around iron pole pieces (called stack teeth) with the

ends of the wires terminating on a commutator. The armature includes the mounting bearings

that keep it in the center of the motor and the power shaft of the motor and the commutator

connections. The winding in the armature continues to loop all the way around the armature

and uses either single or parallel conductors (wires), and can circle several times around the

stack teeth. The total amount of current sent to the coil, the coil's size and what it's wrapped

around dictate the strength of the electromagnetic field created. The sequence of turning a

particular coil on or off dictates what direction the effective electromagnetic fields are

pointed. By turning on and off coils in sequence a rotating magnetic field can be created.

These rotating magnetic fields interact with the magnetic fields of the magnets (permanent or

electromagnets) in the stationary part of the motor (stator) to create a force on the armature

which causes it to rotate. In some DC motor designs the stator fields use electromagnets to

create their magnetic fields which allow greater control over the motor. At high power levels,

DC motors are almost always cooled using forced air.

The commutator allows each armature coil to be activated in turn. The current in the coil is

typically supplied via two brushes that make moving contact with the commutator. Now,

some brushless DC motors have electronics that switch the DC current to each coil on and off

and have no brushes to wear out or create sparks.

Different number of stator and armature fields as well as how they are connected provide

different inherent speed/torque regulation characteristics. The speed of a DC motor can be

controlled by changing the voltage applied to the armature. The introduction of variable

resistance in the armature circuit or field circuit allowed speed control. Modern DC motors

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are often controlled by power electronics systems which adjust the voltage by "chopping" the

DC current into on and off cycles which have an effective lower voltage.

Since the series-wound DC motor develops its highest torque at low speed, it is often used in

traction applications such as electric locomotives, and trams. The DC motor was the

mainstay of electric traction drives on both electric and diesel-electric locomotives, street-

cars/trams and diesel electric drilling rigs for many years.

If external power is applied to a DC motor it acts as a DC generator, a dynamo. This feature

is used to slow down and recharge batteries on hybrid car and electric cars or to return

electricity back to the electric grid used on a street car or electric powered train line when

they slow down. This process is called regenerative braking on hybrid and electric cars. In

diesel electric locomotives they also use their DC motors as generators to slow down but

dissipate the energy in resistor stacks. Newer designs are adding large battery packs to

recapture some of this energy.

Fig 2.6: DC Geared motor(100 rpm)

2.1.4 REGULATED POWER SUPPLY:

Description:

The MC78XX/LM78XX/MC78XXA series of three terminal positive regulators are available

in the TO-220/D-PAK package and with several fixed output voltages, making them useful in

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a wide range of applications. Each type employs internal current limiting, thermal shut down

and safe operating area protection, making it essentially indestructible. If adequate heat

sinking is provided, they can deliver over 1A output current. Although designed primarily as

fixed voltage regulators, these devices can be used with external components to obtain

adjustable voltages and currents

Fig 2.7: Pin Diagram Of 7805

Features

Output Current up to 1A

Output Voltages of 5

Thermal Overload Protection

Short Circuit Protection

Output Transistor Safe Operating Area Protection

Fig 2.8:Circuit diagram of Regulated power Supply

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2.1.5 MICROCONTROLLER:

Fig 2.9: Pin Diagram of Pic 16f872

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Table 2.1: Pin Out Description

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Memory Organization:

There are three memory blocks in the PIC16F872. The Program Memory and Data Memory

have separate buses so that concurrent access can occur. Additional information on device

memory may be found in the PICmicro™ Mid-Range Reference Manual(DS33023).

Program Memory Organization:

The PIC16F872 has a 13-bit program counter capable of addressing an 8K word x 14 bit

program memory space. The PIC16F872 device actually has 2K words of FLASH program

memory. Accessing a location above the physically implemented address will cause a

wraparound. The RESET vector is at 0000h and the interrupt vector is at 0004h.

Fig 2.10: PIC16F872 Program Memory Map And Stack

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Data Memory Organization:

The data memory is partitioned into multiple banks which contain the General Purpose

Registers and the Special Function Registers. Bits RP1 (STATUS<6>) and RP0

(STATUS<5>) are the bank select bits.

Table 2.2: Representing Banks

RP1:RP0 Bank

00 0

01 1

10 2

11 3

Each bank extends up to 7Fh (128 bytes). The lower locations of each bank are reserved for

the Special Function Registers. Above the Special Function Registers are General Purpose

Registers, implemented as static RAM. All implemented banks contain Special Function

Registers. Some frequently used Special Function Registers from one bank may be mirrored

in another bank for code reduction and quicker access.

High Performance Risc Cpu:

Only 35 single word instructions to learn

All single cycle instructions except for program branches, which are two-cycle

Operating speed: DC - 20 MHz clock input DC - 200 ns instruction cycle

2K x 14 words of FLASH Program Memory

128 bytes of Data Memory (RAM)

64 bytes of EEPROM Data Memory

Pinout compatible to the PIC16C72A

Interrupt capability (up to 10 sources)

Eight level deep hardware stack

Direct, Indirect and Relative Addressing modes

Peripheral Features:

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• High Sink/Source Current: 25 mA

• Timer0: 8-bit timer/counter with 8-bit prescaler

• Timer1: 16-bit timer/counter with prescaler, can be incremented during SLEEP via

external crystal/clock

• Timer2: 8-bit timer/counter with 8-bit period register, prescaler and postscaler

• One Capture, Compare, PWM module

o Capture is 16-bit, max. resolution is 12.5 ns

o Compare is 16-bit, max. resolution is 200 ns

o PWM max. resolution is 10-bit

• 10-bit, 5-channel Analog-to-Digital converter (A/D)

• Synchronous Serial Port (SSP) with SPI™ (Master mode) and I2C™ (Master/Slave)

• Brown-out detection circuitry for Brown-out Reset (BOR)

Cmos Technology:

• Low power, high speed CMOS FLASH/EEPRO technology

• Wide operating voltage range: 2.0V to 5.5V

• Fully static design

• Commercial, Industrial and Extended temperature ranges

• Low power consumption:

o < 2 mA typical @ 5V, 4 MHz

o 20 μA typical @ 3V, 32 kHz

o < 1 μA typical standby current

Special Microcontroller Features:

• Power-on Reset (POR), Power-up Timer (PWRT) and Oscillator Start-up Timer

(OST)

• Watchdog Timer (WDT) with its own on-chip RC oscillator for reliable operation

• Programmable code protection

• Power saving SLEEP mode

• Selectable oscillator options

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• In-Circuit Serial Programming™ (ICSP™) via two pins

• Single 5V In-Circuit Serial Programming capability

• In-Circuit Debugging via two pins

• Processor read/write access to program memory

Device Overview:

This document contains device specific information about the PIC16F872 microcontroller.

Additional information may be found in the PICmicro™ Mid-Rang Reference Manual

(DS33023), which may be obtained from local Microchip Sales Representative or

downloaded from the Microchip website. The Reference Manual should be considered a

complementary document to this data sheet, and is highly recommended reading for a better

understanding of the device architecture and operation of the peripheral modules. The block

diagram of the PIC16F872 architecture is shown in Figure 2.11. A pinout description is

provided in Table 2.3

Table 2.3: Key Features of The Pic 16F872

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Internal Architecture:

Fig 2.11: internal architecture of PIC16F872

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2.2 SOFTWARE REQUIREMENTS:

2.2.1 DIP TRACE :

Dip trace is EDA software for creating schematic diagrams and printed circuit boards. The

first version of Dip Trace was released in August, 2004. The latest version as of March 2013

is Dip Trace version 2.3.1. The interface and tutorials are multi-lingual (currently English,

Czech, Russian and Turkish). In January of 2011, Parallax switched from Eagle to Dip

Trace for developing its printed circuit boards.

2.2.2 µVISION KEIL:

The µVision IDE from Keil combines project management, make facilities, source code

editing, program debugging, and complete simulation in one powerful environment. The

µVision development platform is easy-to-use and helping you quickly create embedded

programs that work. The µVision editor and debugger are integrated in a single application

that provides a seamless embedded project development environment.

Fig 2.9: Working with µvision Keil

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2.2.3 FLASH MAGIC:

NXP Semiconductors produce a range of Microcontrollers that feature both on-chip Flash

memory and the ability to be reprogrammed using In-System Programming technology.

Flash Magic is Windows software from the Embedded Systems Academy that allows easy

access to all the ISP features provided by the devices. These features include:

· Erasing the Flash memory (individual blocks or the whole device)

· Programming the Flash memory

· Modifying the Boot Vector and Status Byte

· Reading Flash memory

· Performing a blank check on a section of Flash memory

· Reading the signature bytes

· Reading and writing the security bits

· Direct load of a new baud rate (high speed communications)

· Sending commands to place device in Bootloader mode

Flash Magic provides a clear and simple user interface to these features and more as

described in the following sections. Under Windows, only one application may have access

the COM Port at any one time, preventing other applications from using the COM Port. Flash

Magic only obtains access to the selected COM Port when ISP operations are being

performed. This means that other applications that need to use the COM Port, such as

debugging tools, may be used while Flash Magic is loaded. Note that in this manual third

party Compilers are listed alphabetically. No preferences are indicated or implied.

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Fig 2.10: Working with Flash Magic

PROJECT IMPLEMENTATION

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CHAPTER 3

PROJECT IMPLEMENTATION:

3.1 BLOCK DIAGRAM:

Fig 3.1: Block Diagram

The robot is so controlled by a mobile phone that makes a call to the mobile phone attached

to the robot. In the course of a call, if any button is pressed, a tone corresponding to the

button pressed is heard at the other end of the call. This tone is called ‘dual tone multiple

frequency’ (DTMF) tone. The robot perceives this DTMF tone with the help of the phone

stacked in the robot. The amplifier is used to amplify the received DTMF signal. The

receiver tone is processed by 8051microcontroller with the help of a DTMF decoder

CM8870. The decoder decodes the DTMF tone into its equivalent binary digit and this binary

number is sent to the microcontroller. The microcontroller is preprogrammed to take a

decision for any given input and outputs its decision to motor drivers in order to drive the

motors for forward or backward motion or a turn. The mobile that makes a call to the mobile

phone stacked in the robot acts as a remote.

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. 3.2 FLOW CHART:

Fig 3.2: Operational Flow chart

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3.4 APPLICATIONS:

Scientific :

Remote control vehicles have various scientific uses including hazardous environments,

working in the deep ocean , and space exploration. The majority of the probes to the other

planets in our solar system have been remote control vehicles, although some of the more

recent ones were partially autonomous. The sophistication of these devices has fueled greater

debate on the need for manned spaceflight and exploration. The Voyager I spacecraft is the

first craft of any kind to leave the solar system. The Martian explorers Spirit and Opportunity

have provided continuous data about the surface of Mars since January 3, 2004.

Military and Law Enforcement:

Military usage of remotely controlled military vehicles dates back to the first half of 20th

century. Soviet Red Army used remotely controlled Teletanks during 1930s in the Winter

War and early stage of World War II. There were also remotely controlled cutters and

experimental remotely controlled planes in the Red Army.

Remote control vehicles are used in law enforcement and military engagements for some

of the same reasons. The exposure to hazards is mitigated to the person who operates the

vehicle from a location of relative safety. Remote controlled vehicles are used by many

police department bomb-squads to defuse or detonate explosives. See Dragon Runner,

Military robot.

Unmanned Aerial Vehicles (UAVs) have undergone a dramatic evolution in capability in

the past decade. Early UAV's were capable of reconnaissance missions alone and then only

with a limited range. Current UAV's can hover around possible targets until they are

positively identified before releasing their payload of weaponry. Backpack sized UAV's

will provide ground troops with over the horizon surveillance capabilities.

Search and Rescue:

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UAVs will likely play an increased role in search and rescue in the United States. Slowly

other European countries (even some developing nations) are thinking about making use of

these vehicles in case of natural calamities & emergencies. This can be a great asset to save

lives of both people along with soldiers in case of terrorist attacks like the one happened in

26 Nov, 2008 in Mumbai, India. The loss of military personnel can be largely reduced by

using these advanced methods. This was demonstrated by the successful use of UAVs during

the 2008 hurricanes that struck Louisiana and Texas.

Recreation And Hobby:

See Radio-controlled model. Small scale remote control vehicles have long been popular

among hobbyists. These remote controlled vehicles span a wide range in terms of price and

sophistication. There are many types of radio controlled vehicles. These include on-road

cars, off-road trucks, boats, airplanes, and even helicopters. The "robots" now popular in

television shows such as Robot Wars, are a recent extension of this hobby (these vehicles do

not meet the classical definition of a robot; they are remotely controlled by a human). Radio-

controlled submarine also exist.

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CONCLUSION & FUTURE SCOPE

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CONCLUSION:

The primary purpose of the mobile phone operated land rover with DTMF decoder is to

know the information in the places where we cannot move. The robot perceives the DTMF

tone with the help of the phone stacked in the robot. It provides the advantage of robust

control, working range as large as coverage area of service provider.

FUTURE SCOPE

IR Sensors:

IR sensors can be used to automatically detect & avoid obstacles if the robot goes beyond

line of sight. This avoids damage to the vehicle if we are maneuvering it from a distant place.

Password Protection:

Project can be modified in order to password protect the robot so that it can be operated only

if correct password is entered. Either cell phone should be password protected or necessary

modification should be made in the assembly language code. This introduces conditioned

access & increases security to a great extent.

Alarm Phone Dialer:

By replacing DTMF Decoder IC CM8870 by a 'DTMF Transceiver IC’ CM8880, DTMF

tones can be generated from the robot. So, a project called 'Alarm Phone Dialer' can be built

which will generate necessary alarms for something that is desired to be monitored (usually

by triggering a relay). For example, a high water alarm, low temperature alarm, opening of

back window, garage door, etc.

When the system is activated it will call a number of programmed numbers to let the user

know the alarm has been activated. This would be great to get alerts of alarm conditions from

home when user is at work.

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REFERENCES

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REFERENCES:

[1] “The 8051 Microcontroller and Embedded Systems” By Muhammad Ali Mazidi and

Janice Gillispie Mazidi. Pearson Education.

[2] S. Chemishkian, “Building smart services for smart home”, Proceedings of IEEE

4thInternational Workshop on Networked Appliances, 2011 pp: 2 15 -224.s

[3] R. Sharma, K. Kumar, and S. Viq, “DTMF Based Remote Control System,” IEEE

International Conference ICIT 2006, pp. 2380 -2383, December 2006.

[4] R.C. Luo, T.M. Chen, and C.C. Yih, “Intelligent autonomous mobile robot

control through the Internet,”IEEE InternationalSymposium ISIE 2000, vol. 1, pp. 6-11,

December 2000

[5] G. Arangurenss, L. Nozal, A. Blazquez, and J. Arias, "Remote control of sensors and

actuators by GSM", IEEE 2002 28th Annual Conference of the Industrial Electronics Society

IECON 02, vol. , 5-8 Nov. 2002,pp.2306 – 2310

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