Robotic Manipulator Arm

[seminar surveyer]

---

Project members:
ANUSHA GOPINATH
HEMALATHA.B.M
SUMA.N
VISHAL.J.N

[attachment=7684]

objective
To design a robotic arm controlled through the internet/LAN used for patient operation.
To interface the robotic arm and the other components like LCD,DC motor and RF video camera with the microcontroller.
Introduction
India is a developing country. One of the hurdles it has overcome is medical field.
There is lack of basic medical facilities in cities as well as small towns.
The problems faced by patients are the lack of good facilities and also absence of skilled surgeons.
Incorporation of the robotic arm tackles these problems.
The plus point is the robotic arm is controlled by LAN.

By this method the doctors sitting in any place of the world can perform the surgery on patients and also can know the recovery status.
The choice of using the robots is b’coz they can perform variety of functions in more flexible environment and at lower production costs.
The word robot originated from the Czech word ”ROBOTA” meaning “work”.
Generally a robot is a re-programmable multi-functional manipulator designed to move materials.
Literature survey
The idea behind the development of the robotic mechanism was the hospital visit where the problem faced was the absence of the surgeon. 
As we all know that surgery is a common thing these days’ even a small tumor removal needs surgery.
Suppose that the surgeon is in a foreign country to ask him to come over for the surgery is impractical in cases of emergency.
These problems are tackled by our Robotic arm which is fully automated.


Microcontroller provides a helping hand in making a system automatic.
Microcontroller AT89s52 was chosen for a simple reason that it is advanced and more flexible version of microcontroller 8051.

The first robotic surgery was performed in 1992-93 called as the RoboDoc system.
Later the AESOP systems were developed that were used in general surgery.
After commercialization the systems were used in neuro surgery.
After the redesigning process the Da Vinci surgical system was developed.
First robotic surgery was performed in 1997
The surgery using robotics was limited to short distances cos of latency.
Problem statement
The problems that can be tackled by the design of our project are:
Lack of proper medical facilities in small towns and cities.
Unavailability of surgeons in time of emergencies.
Sophisticated data acquisition and monitoring techniques.
Centralized robotic arm control.
Problem formulation
Presently the problems faced by many hospitals are:
There were situations where the surgeons were unable to be on time for the operation, which could be fatal in many cases.
In many cases patients were shifted abroad in cases of emergency which was impractical.
Here the robotic arm is controlled by the AT89s52.We control the arm through the LAN.


Goals of the project
The points to be kept in mind during the control of arm through LAN are:
Accuracy.
Time.
Cost effective.
Strengthen the medical field.
Eliminate the shortage of skilled surgeons.

Scope of the project
It counters the problem of unavailability of skilled doctors.
Our project is economical.
It is a boon to medical field.
The accuracy and performance is very high.


Steps involved
analysis
The system’s services, goals and constraints are established by communicating with the client.
Before the design process begins we communicate with the client and note down the system specifications.
design
We partition the process into two stages
Hardware design
Software design
We represent the system’s function in a form transformable to an executable program.
Implementation
testing
The individual hardware units and programs are tested.
They are then integrated and tested as a complete system.
Project Description

ROBOTIC ARM
WORKING PRINCIPLE
The front end application will send the controlling data to the particular computer by sending corresponding IP address.
After sending the commands the Ethernet adapter which is already configured with that particular IP address; will receive the data.
And the Ethernet adapter will send the received data to microcontroller through serial port.


WORKING PRINCIPLEcontd..
After receiving the command the microcontroller will control the robotic arm by sending appropriate signals to geared motor.
The microcontroller part which is connected in robot side, is doing all the operations of motor control.
WORKING PRINCIPLEcontd..

The Ethernet card is a medium, which is used to convert LAN signal in to RS232 form.
According to the command received the microcontroller will control the robotic arm step movements.
We use the RF camera’s to view the patient status and transmit it to the PC.
In this project we are using the arm only to cut the skin of the patient using the high-speed blades.

COMPONENTS USED

Power supply 5v DC - lm 7805
Video camera - RF
Microcontroller - 89s52atmel
Crystal - 11.0592mhz
MAX232 - serial comm.
Buzzer - freq-1 to 18KHZ
DC Motors
Ethernet Adapter
LCD - 2x16 characters
Micro controller-AT89S52
The AT89S52 is a low-power, high-performance CMOS.
Features:
Compatible with MCS-51 products
8K bytes of in-system programmable (ISP) flash memory
Endurance: 1000 write/erase cycles
4.0V to 5.5V operating range
Fully static operation: 0 Hz to 33Hz
Three-level program memory lock
256 x 8-bit internal RAM
32 programmable I/O lines


Three 16-bit timer/counters
Eight interrupt sources
Full duplex UART serial channel
Low-power idle and power-down mode
Interrupt recovery from power-down mode
Watchdog timer
Dual data pointer
Power-off flag

PIN DESCRIPTION

Rst
Is the reset pin. A high on this pin for two machine cycle while the oscillator is running resets the device
ALE/PROG
Address Latch Enable is an output pulse for latching the low byte of address during the external memory access.
It acts as an Program Pulse Input during Flash Programming.
PSEN
Program Store Enable is the read strobe to external program memory.
EA/Vpp
External Access Enable must be strapped to the Gnd in order to fetch the code from external memory.

XTAL 1
Input to the inverting oscillator amplifier and input to the internal clock operating circuit.
XTAL 2
Output from the inverting oscillator amplifier.
Special Function Registers(SFR’s)
Timer 2 Registers
Control and status bits are contained in registers T2CON and T2MOD for timer 2.
The register pair (RCAP2H, RCAP2L)are the capture/reload registers for timer 2 in 16-bit capture mode or 16-bit auto-reload mode.
Interrupt Registers
The individual interrupt enable bits are in the IE register. Two priorities can be set for each of the six interrupt sources in the IP register.

---

---

Presented By,
Nikhil Vijay
Nitheesh Kurian
Paul Joy

[attachment=7685]
AIM
To make an autonomous ROBOTIC ARM using microcontroller and motors
To increase the production speed in the industry
To reduce the complexity in manufacturing processes
To increase the profit and productivity in the industries
To move hazardous materials

EXISTING METHOD
The manufacturing process are done manually by humans like pick and place
Welding, material handling, and thermal spraying, painting and drilling are doing with the help of machines.

PROPOSED MECHANISM
The manufacturing process is automated using ROBOTIC ARM technology
Drilling, milling process are made to simpler by using ROBOTIC ARM

INTRODUCTION

The main idea behind the robotic arm is that it imitates the actions of a human arm or hand.
It is a programmable Robotic Manipulator.
This type of robot is often termed, Anthropomorphic because of the similarities between its structure and the human arm.


MICROCONTROLLER
The AT89C51 microcontroller is used as the main part of the design
The AT89C51 is a low-power, high-performance CMOS 8-bit microcomputer with 4K bytes of Flash programmable and erasable read only memory (PEROM).
Atmel AT89C51 is a power full, highly flexible and cost effective solution to many embedded control applications.