International Journal of Engineering Materials and Manufacture 2023 8(3) 75-87 

https://doi.org/10.26776/ijemm.08.03.2023.03 

 

S. M. Z Al-Hady , M. R. Islam, M. M. Rashid 

Department of Mechatronics Engineering 

Faculty of Engineering, International Islamic University Malaysia 

PO Box 10, 50728 Kuala Lumpur, Malaysia 

E-mail: syedmdzakaria@gmail.com  
           syedmdzakaria@live.iium.edu.my 

 

Reference: Al-Hady el al. (2023). Development of IoT Based Automated Dynamic Emergency Response System Against Fire Incident 
in Academic Building. . International Journal of Engineering Materials and Manufacture, 8(3), 75-87. 

 

 

Development of IoT-Based Automated Dynamic Emergency Response 

System Against Fire Incidents in Academic Building 

 

 

Syed Mohammed Zakaria Al-Hady, Md Rafiqul Islam, Muhammad Mahbubur Rashid 

 

 

Received: 26 April 2023 

Accepted: 30 May 2023 

Published: 01 July 2023 

Publisher: Deer Hill Publications 

© 2023 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

The ongoing advancement of architectural and structural designs, high-ceiling spaces, special spaces have made fire 

disasters increasingly diverse and difficult to predict. It is demanding the need for improved firefighting systems. This 

study aims to address the need for improved firefighting systems in academic building by proposing the development 

of an IoT-based automated emergency response website. The proposed system leverages IoT technology, wireless 

and bluetooth sensor networks to gather real-time data from various sensors and devices installed in the site and uses 

machine learning algorithms to predict and prevent potential fire incidents. The system also includes an emergency 

response website that allows users to access real-time information about the fire incident, location, severity, and 

evacuation instructions. Additionally, the proposed system incorporates Building Information Modelling (BIM) to 

optimize evacuation and rescue routes, providing early detection and accurate alarm capabilities, evacuation guidance 

for endangered individuals, and guidance for firefighters. The integration of BIM allows the system to provide a 

three-dimensional visualization of the site, enabling a more efficient and effective response to fire incidents. Overall, 

the proposed system aims to improve the safety and security through real-time monitoring and response capabilities. 

By leveraging the power of IoT technology, machine learning algorithms and BIM, the proposed system aims to 

reduce the impact of fire disasters by providing accurate and timely information, route optimization and facilitating 

effective evacuation and rescue efforts. 

Keywords: Building Information Modeling, IoT, Sensor, Dijkstra Algorithm, Simulation 

 

1 Introduction 

Around the world, modern industrial sites, office sites and academic buildings have grown more complex and 

augmented. Given the structural characteristics of these sites, quick evacuation such as through emergency exits or 

evacuee guidance markers during blackouts caused by fire, building collapse, earthquakes, or building aging is a critical 

issue. Uniform evacuation guidance, such as exit light is insufficient for guiding evacuees during a fire, causing them 

to take incorrect exits while buildings are on fire. Existing emergency exit guides do not take the location of the fire 

in and out of the account and simply direct people to the nearest exit, which may result in significant secondary 

casualties if a fire occurs at the exit and evacuees are directed towards it. As a result, we must pay special attention 

to implementing new technology to combat fire disasters. The Internet of Things (IoT), in conjunction with Building 

Information Modelling (BIM) and wireless sensor networks (WSN), is ideal for firefighting. IoT has a high level of 

intelligence for maintaining many product categories, quantities, complex fire danger factors, and a wide range of 

fire monitoring and fighting equipment. IoT has high scalability and resource-sharing capabilities for handling various 

complex business information. IoT in conjunction with the Wireless Sensor Network (WSN) plays an important role 

in fire alarm, fire control facility monitoring, and fire equipment management. The fire department's emergency 

response & rescue capabilities are effectively improved by it. This research will propose an IoT-based intelligent fire 

emergency response system with decentralized control which is far more effective than the traditional non-

communicative signal-based evacuation technology. It can intelligently guide evacuees based on the location and 

time of a fire to reduce human life loss. 

 



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2 Literature Review 

The recent surge of technological advancement in sensor-based networking systems has enriched studies based on 

IoT systems and their mechanisms. Most IoT-based studies on firefighting in the last decade have discussed the 

following topics: general firefighting systematic plan, technological sensor development, improvement in sensor 

sensitivity and mechanism, and use of different parameters in fire identification (such as temperature, pressure, 

moisture content, etc.). 

 

2.1 Development of IoT-based Fire Hazard Solutions 

The “Internet of Things for Smart Cities” discussed only general IoT features that can be implemented in Smart City 

networks, but no recommendations for Firefighting were given in it whereas Folea and Mois discussed low-power 

wireless sensors for online environmental monitoring, which combines Wi-Fi connectivity with ambient sensors, used 

for remote data collection and processing [1]. The use of narrowband IoT (NB-IoT) in Intelligent Fire Protection 

Systems, can significantly improve firefighting forces combat capability [2]. Combined application features of IoT 

technology based on fire-fighting business requirements discuss the fire-fighting IoT systematic frame, planning of 

society fire-fighting safety management, and propose priority development points of society fire-fighting safety 

management, thereby providing a reference for technology research and development of IoT technology in the field 

of society fire-fighting safety management [3]. An IoT-based novel fire extinguishing monitoring and control system 

is proposed to acquire real-time information on fire extinguishing working conditions and improve the reliable 

prediction mechanism in a traditional fire monitoring system [4]. The novel system can obtain real-time data on the 

operation of fire extinguishing facilities, such as pipe flow, pressure, temperature, and humidity of the environment, 

current and voltage of the electric equipment, valve switch, relay action, and an alarming message [5]. The 

investigation of the design and implementation of a VOC monitoring system using a ZigBee wireless sensor network 

[6]. 

The consideration of Gator tech smart house to be a programmable pervasive space [7]. The detailed discussion 

on the current state of smart homes and the discussion on the WSN-based smart sensors and actuators for intelligent 

building power management [8-9]. There are some investigations were conducted on the intelligent self-adjusting 

sensor based on ZigBee communications for smart home services where the structure composition, design concept, 

and implementation approach has described [ 10]. Byun, et al. [11] have made an investigation on a Zigbee-based 

simulation process on a safeguarding sensor system for the real-time monitoring of wireless fire detection nodes. 

Intelligent-based bridging components in the space where the distributed services have been working seamlessly and 

where the robots are sharing the missing information in the intelligent space [12]. The use of blockchain technology 

in an IoT-based automated dynamic emergency response system for energy distribution can improve the efficiency, 

reliability, and security of energy distribution, leading to a more sustainable and resilient energy ecosystem [13]. A 

computer-aided visualization of rescue operations was applied, and the investigation novel concept of a fire hazard 

ranking distribution system based on multisensory technology [14]. The challenges of integrating a Wireless Sensor 

Network and the Internet of Things for Environmental Monitoring can be improved by using wireless sensors in 

network-based forest-fire surveillance systems [15-16]. 

 

2.2 BIM Model Development in Fire Hazard Situations 

In recent years, Building Information Models (BIM) have been widely used in building disaster prevention and relief 

management, and not only does it provide three-dimensional space for visualizing fire conditions and other 

emergencies [17-19]. The uncertainty of a building fire makes every second of the fire scene critical and the users can 

quickly determine the best escape route to deal with the fire using this information [20]. BIM-based construction 

safety management system using AR and 4D simulation technologies. Advances in Civil Engineering [21-22]. Most of 

the current research on building fire escape focuses on path planning based on the current fire situation. However, 

due to many floors and complex internal space in high-rise buildings and large complex buildings, it is difficult to 

obtain the overall optimal escape path that carries on path planning only through the current location data and 

situation of a fire, lacking fire spreading and using the fire spreading data to correct the path [23-24]. Although there 

have been some studies on escape paths in the case of fire spreading, they have primarily focused on fire rendering 

but the research on the emergency evacuation management system of a museum based on BIM and virtual reality 

with little research on dynamically changing escape paths based on fire spreading simulation [25-27] 

 

2.3 Dijkstra’s Algorithm in a Fire Escape Situation 

The fire is sprawling and uncertain, and the trapped people are in constant motion. If the escape route planning was 

performed only by real-time personnel location and fire information, it may cause the current route to be opposite 

to the previous route with the fire spread and the escape proceeded [28-30]. As a result, it is hard to escape quickly 

from the fire scene for the problem of partial route detour. Although there has been research on fire spread and path 

planning based on simulation data [31], there is a lack of processing to dynamically correct the escape path according 

to the fire spread data, so it is impossible to ensure the real-time escape path is optimal in the overall escape process 

[28]. Moreover, people often escape at the same time in a real fire. And it will be more difficult to escape if people 

are in a panic. Congestion and stampede tend to occur on stairs, resulting in unnecessary casualties [32]. 

 



Al-Hady, Islam, M. R. and Rashid, M. M. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 75-87 

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Cheng et al. used Bluetooth and smoke sensors to obtain information about the fire scene in their study of building 

fire escape paths [33]. and then used the Dijkstra algorithm for dynamic evacuation/rescue path planning, which 

successfully realized real-time dynamic path planning and navigation of building fires. Similarly, Chou et al. developed 

an integrated fire protection system with multiple scenarios for evacuation and rescue by employing the Dijkstra 

algorithm to perform real-time dynamic path planning and constantly update the location nodes of trapped and 

rescuers [34]. 

In response to this problems, this paper is going to make a further study on the quick and safe escape from a 

building fire, and it will adopt IOT based system for an effective escape path. For this effective communication a 

website is created using the BIM model in conjunction with Dijkstra’s algorithm, integrating fire information to 

simulate fire spread, the data of fire spread can be obtained and adjusted dynamically according to the real-time 

situation. This dynamic path analysis of the escape path for complex building fires can be realized and displayed in 

the BIM model, which helps trapped people escape quickly. 

 

3 Methodology 

This proposal is divided into three phases that will be implemented simultaneously to achieve the main objectives. 

The execution of this research can be categorized as follows: 

1. Analyzing fire load and fuel arrangements in a typical building, investigating possible worst-case scenarios of 

fire phenomena in buildings during a fire. 

2. Examining the efficiency of dynamic exit signage during an emergency using a demo device, modeling a soft 

computing-based simulation process that can predict the level of emergency due to fire and occupants' flow. 

3. Integrating the main results from previous studies to produce an automated dynamic emergency response 

system that will be further developed to meet commercialization goals. 

 

3.1 Factors Identification 

A concept is developed through a comprehensive literature review and the identification and evaluation of various 

components of an IOT-based Fire Fighting System. It also aids in the extraction of preliminary factors that are widely 

used in various types of buildings, structures, and large areas shown in Figure 1. 

 

3.2 Data Collection and Organization 

To create a Building Information Modelling (BIM), fire system sensor data and building planning data were collected. 

The General Mustafiz Tower at the Military Institute of Science and Technology, located in Mirpur Cantonment, 

Bangladesh, was selected as the study site which has been shown in Figures 2, 3 , and 4. This academic building 

comprises 10 floors, with the first floor being a lobby. Participants were instructed to evacuate from the 3rd floor. As 

depicted in the figure, the building features one staircase, three elevators, one emergency exit, and a connecting 

bridge with the adjacent tower. To eliminate any issues with elevator scheduling, occupants on other floors were not 

permitted to use elevators during the experiments. Participants were only allowed to use the staircases, emergency 

exit, and connecting bridge for the duration of the experiment. 

 

 

Figure 1: Research framework 



Development of IoT Based Automated Dynamic Emergency Response System Against Fire Incident in Academic Building 

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3.3 Plan Layout 

The floor and node plan diagram are drawn according to the building layout and fire system placements which are 

shown in Figures 5, 6, and 7. The measurement of the classrooms, corridor, and washroom was taken physically 

during the experiment. 

 

  

Figure 2: General Mustafiz Tower, MIST, Mirpur 

Cantonment, Bangladesh 

Figure 3: Student classroom 

 

 

 

Figure 4: Common Space of the MIST academic building 

 

  

Figure 5: Emergency exit and staircase 



Al-Hady, Islam, M. R. and Rashid, M. M. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 75-87 

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Figure 6: Floor plan of the MIST academic building 

 

 

 

Figure 7: Combined nodes 

 

As shown in Figure 6, the building can be modeled as a “graph”, or a series of connected nodes and weighted edges. 

Dijkstra’s Algorithm is a computational algorithm that is commonly used to find the shortest distance between two 

nodes in a graph (with weighted edges), making it the perfect computational tool to find the optimal escape path 

from one specified location to another. The main advantage of the algorithm is that it can plan the shortest path 

between any two locations (when modeled as a graph) with the smallest computational time. This is important as in 

a large building with many locations, nodes, and possible escape paths, there may be a very large number of possible 

combinations that the IoT system would need to compute if a “brute force” computation approach is used to find 

the shortest path, which may take far too long to compute in a real fire situation. The node-to-node distance is shown 

in Table 1 below. 

 



Development of IoT Based Automated Dynamic Emergency Response System Against Fire Incident in Academic Building 

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3.4 Planning the Dynamic Fire Escape Path 

3.4.1 Introduction and Overview  

To demonstrate the application of IoT systems in a real firefighting scenario, this paper will make use of a web-based 

(http://dynamicfireescape.com:9999/SP_PROBLEM), simulation software “Dynamic Fire Fighting”, a purpose-built 

to test out fire scenarios. The software will be used to simulate three fire scenarios, which will be visually represented 

as graphs by the software. Dijkstra’s algorithm will then be applied by the software to illustrate how an IoT system 

may plan out an escape route. 

 

3.4.2 Simulation Software 

A web-based simulation software was created to demonstrate the application of Dijkstra’s Algorithm as a proof of 

concept. This software takes a table of nodes and paths between the nodes as inputs (exactly in the format of Table 

1 and outputs a table outlining the fastest path from one selected node to another. This software can be accessed at 

(http://dynamicfireescape.com:9999/SP_PROBLEM). 

 

3.5 Executed Simulations for a Dynamic Fire Escape Path 

Refer to Figure 7 Consider now a building with sensors, entrances, and exits in the locations as shown. Similarly, 

consider the evacuees and fires in the locations as shown in Table 2. The following is Table 2 of the scenarios that 

will be simulated for this demonstration. 

 

Table 1: Node to node distance 

 

 

Figure 8: Simulation software interface 

Node to Node Distance (ft) Node to node Distance (ft) 

P1 – N1 20 P14 – N2 20 

P2 – N1 39 P16 – N4 5 

P3 – N1 5 P17 – N4 31 

P4 – N1 31 P18 – N4 20 

P1 – N2 39 P19 – N4 39 

P2 – N2 20 P16 – N5 31 

P3 – N2 31 P17 – N5 5 

P4 – N2 5 P18 – N5 39 

P5 – N3 20 P19 – N5 20 

P6 – N3 5 P20 – N6 30 

P7 – N4 20 P21 – N6 25 

P8 – N4 5 P22 – N7 30 

P9 – N4 39 P23 – N7 25 

P10 – N4 31 E2 – N1 1 

P7 – N5 39 E3 – N1 1 

P8 – N5 31 N1 – N2 30 

P9 – N5 20 N2 – N3 12 

P10 – N5 5 N3 – N4 3 

P11 – N1 5 N4 – N5 30 

P12 – N1 31 N3 – N6 25 

P13 – N1 20 N6 – N7 24 

P14 – N1 39 E1 – N6 40 

P11 – N2 31 E1 – N7 30 

P12 – N2 5   

P13 – N2 39   

http://dynamicfireescape.com:9999/SP_PROBLEM
http://dynamicfireescape.com:9999/SP_PROBLEM


Al-Hady, Islam, M. R. and Rashid, M. M. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 75-87 

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3.5.1 Scenario 1 

Consider a case where, in the event of a fire breakout, there is an evacuee in the bottom left corner room, labeled 

Node P20 in Figure 7 As shown in Figure 10 below, it is not clear whether Evacuee P20 should take the exit Ex1 

through the red path (Path A) or take exit Ex3 through the black path (Path B). There might be multiple paths in the 

real scenario under any hazardous situation. But we consider the shortest safety path, which will provide the most 

safety exist for the people. Our shortest path is based on the hazard location, not only the shortest by distance. Now, 

we can model this scenario exactly by using Table 1 and inputting the values into the software, and we have the 

following information from Figure 11. 

 

 

 

Figure 9: Simulation Software Interface 

 

 

Table 2: Simulation dvancement 

 

Scenario Evacuee node Possible target 

exits nodes 

Fire node Remarks, the rationale for the choice 

1 P20 Ex3, Ex1 - To illustrate a simple scenario without a fire node. 

2 P1 Ex3, Ex2 F1 To illustrate a scenario where the fire is blocking the 

exit. 

3 P19 Ex1, Ex3 F6, F11 To illustrate the most complex scenario where 

multiple fire nodes are blocking multiple entrances of 

the rooms, and it is not clear what is the shortest path 

the evacuee should take. 

 

 

 
 

Figure 10: Possible escape paths of evacuee P20 



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As shown in Figure 12, the shortest path from P20 to Ex1 is 70 m. Thus, we can see that Path A to Ex1 in Figure 9 

would be the shortest path available for the evacuee and will be recommended by the IOT system to the user. 

In more complex and practical scenarios (such as Scenario 3), the system will always calculate the distances to ALL 

exits (not just Ex1 and Ex3). However, the other exits are not calculated in this example as it is observable by the eye 

that they are not as viable as Ex1 and Ex3, and the focus of this example is the result of the calculations. Indeed, all 

exits will be considered in the more complex Scenario 3. 

 

3.5.2 Scenario 2 

Next, consider the case of an evacuee represented by Node P1. As shown in Figure 13, under normal circumstances, 

his quickest exit route would be to take the green path (Path C) to exit Ex3. However, consider the scenario where 

that path is blocked by a fire, represented by node F1. Now, with the table row removed, we again run the algorithm 

with the ‘from’ node set to P1 and the target node set to Ex3. Now, as shown in Figure 15, the algorithm suggests 

that P1 goes to N2 first, (which is the further room door) then to N1 (outside the room), and finally to exit E3, thus 

avoiding the fire. 

The algorithm now must re-calculate the quickest way out of the fire for the evacuee. In our model, N1 represents 

the room door that is being blocked by the fire node. So, to re-calibrate the software to incorporate the information 

of the fire node blocking the exit path, we remove the P1 - N1 node from the node-to-node table 1, and the value 

for the same is shown in Figure 14. As the data in Fifure 11 is identical to Table 1, only 10 out of 49 entries are shown 

to avoid cluttering this report with repetitive information. Now, in the “solution” section of the software, we set Ex3 

and Ex1 to be our target nodes, as shown in Figure 10. The website now calculates the shortest paths to our target 

nodes using Dijkstra’s Algorithm and displays each walk from node to node on each row. 

 

 

 

Figure 11: Possible escape paths of evacuee P20 

 

 

 

Figure 12: Calculated exit path from P20 to Ex1 

 



Al-Hady, Islam, M. R. and Rashid, M. M. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 75-87 

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Figure 13: Quickest path to exit Ex3 avoiding. 

 

 

 

Figure 14: Table row to be removed 

 

 

 

 

 

Figure 15: Evacuation path blocked by fire 

 



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3.5.3 Scenario 3 

Finally, with such frameworks in place, consider the most complex (and likely realistic) fire scenario as shown in 

Figure 17, evacuee P19 trying to escape a fire, with fire nodes F6 and F11 actively blocking his path, and it is not clear 

how he should exit the building. This is the shortest path calculated by the software for all three exits combined. 

Charting this path on the Figure 7 diagram, we have Path F in purple, as shown in Figure 19. 

Thus, through the application of Dijkstra’s Algorithm in a complex fire scenario, we have successfully guided an 

evacuee through the shortest path to an exit while avoiding fires along the way. Now, in our software, we remove 

the node-to-node data connecting through F10 and F6 like in scenario 2. Setting each of the exits Ex1, Ex2, and Ex3 

to be the target nodes, we get the following path in Figure 17 for Ex1. 

 

3.6 System Flow Diagram 

The system's proposed module is shown below in Figure 20 where signals from the fire alarm are sent to the database, 

which is then incorporated into the website, where the optimal route for escaping will be identified using the previous 

algorithm and the fire exit notification will be sent to all mobile users via Mobile Apps. Graphically, this is represented 

now by the yellow path (Path D) in Figure 13. 

 

 

Figure 16: Calculated path to be taken around fire node F1. 

 

 

 
 

Figure 17: Complex fire scenario 

 

 

 

Figure 18: Calculated path for evacuee P19 to take given a complex 

 



Al-Hady, Islam, M. R. and Rashid, M. M. (2023): International Journal of Engineering Materials and Manufacture, 8(3), 75-87 

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Figure 19: Exit path for evacuee P19 

 

 

 

Figure 20: Components of Integrated Control System Module 



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5 CONCLUSIONS 

The suggested IoT-based intelligent fire emergency response system can reduce casualties by recognizing the location 

of a disaster within a building to avoid directional confusion of emergency lights and improper evacuation assistance. 

By combining the intelligent and automated evacuation system with the central national disaster management agency, 

the intelligent emergency evacuation system can also aid firefighting by allowing for a speedy assessment of the exact 

location of the fire. It reduces casualties and evacuation time by directing evacuees to dispersed routes that avoid the 

location of the fire. Future research will focus on expanding the system's applicability to include not just building 

disasters, but also maritime boats and evacuation within buildings, disaster safety via web or mobile application 

services, and preventive activities for optimal disaster recovery. 

 

6 ACKNOWLEDGEMENT 

The authors would like to express their deepest gratitude to Md Wahidul Islam, Head of Civil Engineering 

Department; Prof Dr Tauhid Ur Rahman (CE); Zabed Sultan (DSW); and Ahadul Islam (Program Coordinator) at 

Military Institute of Science and Technology (MIST) for allowing us to use MIST building and its layout pictures for 

this study. 

 

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