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- No of Pages: 70

- No of Chapters: 06

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Introduction:

Abstract

The use of microcontroller is in every field even we can use it in the design and fabrication of biomedical equipments. A little example is here. The microcontroller at89s51 (8051) is here used to develop a heart beat monitoring system. By placing your finger in between a LED and photo resistance, we can detect the pulses of heart, the analog voltages are further processed with an operational amplifier LM 358, this chip has two built in OPAMPs. The TTL pulses or digital pulse are then feed to the external interrupt of microcontroller 8051. By using a software counter in the code, we can count the pulses, and the result the process is displayed on an LCD (2 line 16 characters). The schematic circuit diagram of heart beat monitor is shown below and the code ( c program) in c language using keil C51 uv3 is also shown. This is only test project and any one can copy from it.

Table of Content

CHAPTER ONE: INTRODUCTION



1.1 Background



1.2 Objectives



1.3 Justification..



1.4 Scope of the Project



1.5 Constraints..



1.6 Project Report Organization



CHAPTER TWO: LITERATURE REVIEW



2.1 Microcontroller Systems.



2.1.1 Benefits of Microcontroller Systems



2.1.2 Comparison between Microcontrollers and other design



techniques



2.2 Frequency Systems



CHAPTER THREE: SYSTEM ANALYSIS AND DESIGN..



3.1 Specification



3.2 The Input Interface Design..



3.3 Microcontroller system



3.4.1 System Reset



3.4.2 System Clock..



3.4.3 Memory



3.4.4 Other Features of the Microcontroller



3.5 Control Program Design.



3.7 Output Interface Design.



3.7.1 Introduction to LCD



3.7.2 Pin Description



3.8 Power Unit.



3.8.1 Timer Power Source



3.9 System Block Diagram



CHAPTER FOUR: SYSTEM IMPLEMENTATION



4.1 Choice of Programming Language



4.1 Hardware Implementation..



4.1.1.1Input Interface Implementation..



4.1.2 Control System Implementation..



4.1.3 Output Interface Implementation..



4.2 Software Implementation



4.2.1 Complete System Implementation



4.2.2 Complete System Wiring Diagram



CHAPTER FIVE: SYSTEM TESTING AND



IMPLEMENTATION



5.1 The Test Plan



5.2 Test Data, Expected Result versus Actual Test Result.



5.2.1 The Power Supply Unit Testing



5.2.2 Input Interface Testing..



5.2.3 Control Software Testing



5.2.4 Output Interface Testing



5.2.5 Complete System Testing



5.3 Performance Evaluation



5.4 System Packaging.



CHAPTER SIX: SUMMARY AND CONCLUSION



6.1 Summary of Achievements



6.2 Problems Encountered and Solutions



6.3 Suggestions for Further Improvements



6.4 Conclusions..



REFERENCES.



APPENDIX A: System Components List



APPENDIX B: Components Cost Analysis



Table..



APPENDIX C: Circuit Components Layout



APPENDIX D: Circuit Wiring Schedule



APPENDIX E: Complete System Circuit



Schematic



APPENDIX F System Flowchart



APPENDIX G System Source Code Listing



APPENDIX H System User’s Guide



APPENDIX I: Project Package Photograph



APPENDIX J: Microcontroller Instruction Set



LIST OF FIGURES



Fig. 3.1 Input Interface



Fig. 3.6 the Microcontroller system..



Fig. 3.7 System Reset Circuit..



Fig. 3.8 Crystal connection to the microcontroller..



Fig. 3.1.2 Top down flow chart of Remote Control.



Fig.3. character LCD type hd44780 pin diagram



Fig.3.2.0 Complete Power supply..



Fig.3.2.1 Output wave form of the complete power



Fig.3.2.2 Wave form of the transformer output..



Fig.3.2.3a Output of full wave rectified Dc..



Fig.3.2.3b Bridge rectifier..



Fig3.2.4 Waveform of Rectified..



Fig. 3.2.5 Voltage Regulator and output wave form of



regulated voltage..



Fig. 3.2.6 Block Diagram of System..



Fig 4.1 Complete Circuit Diagram



LIST OF TABLES



Table 5.1 project costing..

Introduction

1.1 Background



One of the most difficult tasks in generating signals is the decoding. It is only when signals are decoded that it can be used for any essential purpose. Frequency happens to be one of such signals that require a careful decoding technique. One important source of signal is the human body, where different types of signals are generated. Biomedical signal such as the heart beat is very essential to the medical expert to be able to ascertain the kind of medical issue with a patient.



This project, Microcontroller based heart beat monitor is a project that is geared toward the development of simple tool to assist the medical experts to check the human heart rate before further diagnosis can be recommended.



1.2 Objectives



The main objective of this project is to design and Implement Microcontroller based heart beat monitor. It is also intended to use this means to contribute to the academic research work.



1.3 Justification



If this prototype is fully developed will be very useful in many areas such as:



a. Laboratory experiments for measuring frequency.



b. Apply functions to signals being generated.



c. Applicable in the hospitals



d. Educational purpose especially in reversed engineering.



1.4 Scope of the Project



This project makes use of a keypad as the only major input channel. AT89C51 Microcontroller is the main control device. Multi-channel Frequency generators circuits will be realized. Simple interface of output/decoded frequency via LCD will also be built. Programming power of Bascom Basic compiler will be exploited.



1.5 Constraints



One the major constraint of this work was finance. Another like it was in availability of the required information.



1.6 Project Report Organization



This report is organized into six chapters. The first chapter takes care of introduction. Chapter two surveys the literature review of this work. In chapter three, the project analysis was done. The input, processing and output modules are critically analyzed.



In chapter four, system implementation was carefully done. Chapter five takes care of Testing and Implementation. Finally chapter six closes up with summary and conclusions.