case study of automatic fire alarm system in java

Code Sample: Fire Alarm in Java*

This smart fire alarm application is part of a series of how-to Intel® Internet of Things (IoT) code sample exercises using the Intel® IoT Developer Kit, Intel® Edison development platform, cloud platforms, APIs, and other technologies.

From this exercise, developers will learn how to:

Connect the Intel® Edison development platform, a computing platform designed for prototyping and producing IoT and wearable computing products. Interface with the Intel® Edison platform IO and sensor repository using MRAA and UPM from the Intel® IoT Developer Kit, a complete hardware and software solution to help developers explore the IoT and implement innovative projects.

Run this code sample in Intel® System Studio IoT Edition. Intel® System Studio IoT Edition lets you create and test applications on Intel®-based IoT platforms. Set up a web application server to store alarm data using Azure Redis Cache* from Microsoft Azure*, Redis Store* from IBM Bluemix*, or ElastiCache* using Redis* from Amazon Web Services* (AWS), different cloud services for connecting IoT solutions including data analysis, machine learning, and a variety of productivity tools to simplify the process of connecting your sensors to the cloud and getting your IoT project up and running quickly.

Invoke the services of the Twilio* API for sending text messages.

For more such intel IoT resources and tools from Intel, please visit the  Intel® Developer Zone

Source:https://software.intel.com/en-us/articles/fire-alarm-in-java

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COMPUTERIZED AUTOMATED FIRE DETECTION SYSTEM USING JAVA SCRIPT

ABSTRACT FIRE ALARM SYSTEM PLAYS AN IMPORTANT ROLE in maintaining and monitoring the safe of all kind environment and situations. However the usability of many existing fire alarm system is well known but could be produce with high cost. Subsequently, it is not affordable for the low income users. The main objective of this project is to produce a prototype of Fire Detection program with low cost. The microcontroller has two main systems, the detection system and the monitoring system. The detection system operates as the fire detection components which are flame detector, smoke detector and heat detector. This project discusses the design and implementation of a fire alarm system using the microcontroller which operates the entire system. The detectors are place in a parallel in different levels in a building. Any signal from each detector at any level is monitored using the sensor system. The monitoring system is developed using the Java Script. The Fire Detection program is been programmed in such a way  by using the micro sensor . From the experiment done.,  detect fire, smoke flame and heat. Hopefully with the development of the microcontroller based remote fire outbreak monitor, it helps all the users at home an in the office against fire outbreak. TABLE OF CONTENTS Title page --------------------------------------------------------------------- Certification Page    ---------------------------------------------------------- Dedication ------------------------------------------------------------------- Acknowledgement --------------------------------------------------------- Abstract ---------------------------------------------------------------------- Table of content ------------------------------------------------------------ CHAPTER ONE: INTRODUCTION 1.1     Background Of The Study    ------------------------------------------1    1.2     Statement of The Problem      ------------------------------------------2 1.3     Aim and Objectives Of The Study     ----------------------------------2 1.4     Significance Of The Study      ------------------------------------------2-3 1.5     Scope and Delimitation Of The Study    --------------------------------3 1.6     Definition of Operational Terms       ----------------------------------3-4 CHAPTER TWO: LITERATURE REVIEW 2.1        Introduction     ----------------------------------------------------------------5-6 2.2    Theories and Model Relevance        -----------------------------------------6-7 2.3.   The 8051 Family of Microcontroller             -------------------------------11 2.4.   The 8051 Instruction Set        -------------------------------------------------11 2.5.   The 8051 Application       -----------------------------------------------------11-12 2.6.    The Electromagnetic Spectrum                 ----------------------------------12-14 2.7.     System Components Description    ------------------------------------------15-19 CHAPTER THREE: SYSTEM ANALYSIS AND DESIGN 3.1     Introduction                 ------------------------------------------------------------20 3.2     Analysis of the Existing System                  ---------------------------------20-21 3.3     Weakness of the Existing System                 ---------------------------------21 3.4     Data Collection Techniques               ----------------------------------------21-22 3.5     Analysis of the Proposed System                  ------------------------------22-23 3.5.1 Algorithm             --------------------------------------------------------------23-24 3.5.2 System Flowchart              ---------------------------------------------------24 3.6     Database Design             --------------------------------------------------------25 CHAPTER FOUR: SYSTEM IMPLEMENTATION 4.1 Program Development--------------------------------------------------------26 4.2 System Requirement----------------------------------------------------------26 4.2.1 Software Requirement-----------------------------------------------------26 4.2.2 Hardware Requirement----------------------------------------------------26-27 4.3 System Interface--------------------------------------------------------------27 4.3.1 Input Interface---------------------------------------------------------------28 4.3.2 Output Interface-------------------------------------------------------------29 4.4       System Performance-------------------------------------------------------30-31 4.5     System Training   -----------------------------------------------------------31-32 4.6     conversions to the Proposed System        --------------------------------32-32 4.7     System Documentation    ---------------------------------------------------32 4.7.1 Operational Manual      -------------------------------------------------------32 4.7.2 User’s Manual     --------------------------------------------------------------33 4.8   System Maintenance       ------------------------------------------------------33 CHAPTER FIVE:    SUMMARY, RECOMMENDATION AND CONCLUSION 5.1 Summary -------------------------------------------------------------------------34 5.2 Recommendation   --------------------------------------------------------------34 5.3 Conclusion    ---------------------------------------------------------------------34-35 Reference Appendix I Appendix II

Raji, A. (2018). COMPUTERIZED AUTOMATED FIRE DETECTION SYSTEM USING JAVA SCRIPT. Afribary . Retrieved from https://afribary.com/works/computerized-automated-fire-detection-system-using-java-script-8526

Raji, Alex "COMPUTERIZED AUTOMATED FIRE DETECTION SYSTEM USING JAVA SCRIPT" Afribary . Afribary, 29 Jan. 2018, https://afribary.com/works/computerized-automated-fire-detection-system-using-java-script-8526. Accessed 15 Sep. 2024.

Raji, Alex . "COMPUTERIZED AUTOMATED FIRE DETECTION SYSTEM USING JAVA SCRIPT". Afribary , Afribary, 29 Jan. 2018. Web. 15 Sep. 2024. .

Raji, Alex . "COMPUTERIZED AUTOMATED FIRE DETECTION SYSTEM USING JAVA SCRIPT" Afribary (2018). Accessed September 15, 2024. https://afribary.com/works/computerized-automated-fire-detection-system-using-java-script-8526

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The analysis of the operational process of a complex fire alarm system used in transport facilities

• Research Article
• Advances in Modeling and Simulation Tools
• Open access
• Published: 28 May 2021
• Volume 15 , pages 615–629, ( 2022 )

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• Jacek Paś 1 ,
• Tomasz Klimczak 2 ,
• Adam Rosiński 3 &
• Marek Stawowy 3  

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A fire alarm system (FAS) is a system comprising signalling-alarm devices, which automatically detect and transmit information about fire, but also receivers of fire alarms and receivers for damage signals. Fire alarm systems function in different environmental conditions. During operation they should be in state of fitness. This is determined by the reliability of the assembled units and rational management of the operation process. Therefore a reliability and operational analysis of fire alarm systems as a whole is essential. This article presents an authorial model and an operational and reliability analysis of FAS, which is exploited in a transport building. It also demonstrates relationships occurring in the analysed system, where to an addressable fire alarm central unit with detection loops and control-monitoring loops alarm device lines (with monitored relay outputs for actuation of alarm-signalling devices) were connected. Research and analysis of results for representative FAS, which were exploited in similar environmental conditions, were conducted in order to determine operational and reliability parameters of the investigated system. FAS computer simulation was run during the time t = 1 year of safety system operation. This led to the calculation of the probability value of the analysed FAS staying in the examined operational states.

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Military University of Technology Faculty of Electronic, Institute of Electronic Systems, Division of Electronic Systems Exploitations, ul. gen. S. Kaliskiego 2, 00-908, Warsaw, Poland

The Main School of Fire Service, ul. Juliusza Słowackiego 52/54, 01-629, Warsaw, Poland

Tomasz Klimczak

Warsaw University of Technology, Faculty of Transport, Department of Telecommunications in Transport, ul. Koszykowa 75, 00-662, Warsaw, Poland

Adam Rosiński & Marek Stawowy

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Paś, J., Klimczak, T., Rosiński, A. et al. The analysis of the operational process of a complex fire alarm system used in transport facilities. Build. Simul. 15 , 615–629 (2022). https://doi.org/10.1007/s12273-021-0790-y

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Received : 28 December 2020

Revised : 18 February 2021

Accepted : 03 March 2021

Published : 28 May 2021

Issue Date : April 2022

DOI : https://doi.org/10.1007/s12273-021-0790-y

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• DOI: 10.1016/j.jobe.2024.110617
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The dynamic change in the reliability function level in a selected fire alarm system during a fire, engineering information format utilisation across building design stages: an exploration of bim applicability in china, automated process for generating an air conditioning duct model using the cad-to-bim approach, integrating building information modeling (bim) for optimal lifecycle management of complex structures, impact of building information modelling and advanced technologies in the aec industry: a contemporary review and future directions, bim-based automated multi-air distribution layout generation for office buildings: a case study, parametric modeling and heritage: a design process sustainable for restoration, rule-based generation of hvac duct routing, integration of the structural project into the bim paradigm: a literature review, transport infrastructure and urban-rural income disparity: a municipal-level analysis in china, related papers.

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