International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 14, no. 17, 2020


Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

Research Design of Mobile Based Decision Support for 

Early Flood Warning System 

https://doi.org/10.3991/ijim.v14i17.16557 

Mohd Faizal Omar() 
Universiti Utara Malaysia, Kedah, Malaysia  

Centre for Testing, Measurement and Appraisal (CeTMA),  

Universiti Utara Malaysia, Kedah, Malaysia 
faizal_omar@uum.edu.my 

Mohd Nasrun Mohd Nawi 
Universiti Utara Malaysia, Kedah, Malaysia 

Disaster Management Institute (DMI), Universiti Utara Malaysia,  

Kedah, Malaysia 

Jastini Mohd Jamil 
Universiti Utara Malaysia, Kedah, Malaysia 

Ani Munirah Mohamad 
School of Law, Universiti Utara Malaysia, Kedah, Malaysia  

Centre for Testing, Measurement and Appraisal (CeTMA),  

Universiti Utara Malaysia, Kedah, Malaysia 

Saslina Kamaruddin 
Universiti Pendidikan Sultan Idris, Perak, Malaysia  

Abstract—Flooding has become one of the most rapidly growing types of 

natural disaster that has spread around the globe. It is one of the major natural 

hazards in many countries and mostly affected in the low-lying or flood prone 

areas. In order to minimize loss of life and economic losses, a detailed and com-

prehensive decision-making tool is necessary for both flood control planning and 

emergency service operations. In this paper, we demonstrate our research design 

for mobile based decision support of Flood Early Warning System (FEWS). We 

outlined four research objectives. Firstly, critical criteria for flood risk assessment 

will be identified and the second step will involve develop measurement model 

for relative flood risk using Geographic Information System (GIS), Multi Attrib-

ute Decision Making (MADM) and data mining technique. In the third objectives, 

the holistic architectural design is developed by incorporating the communication 

technology and other related ICT requirements for the mobile decision support. 

The fourth objective is to validate the mathematical model and architectural de-

sign. Case study approach is chosen in order to understand the flood event and 

validate the decision support model. Following well-defined procedures, flood 

maps were drawn based on the data collected from expert responses to a ques-

tionnaire, the field survey, satellite images, and documents from flood manage-

ment agencies. It anticipates that by integrating of mathematical model, GIS and 

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https://doi.org/10.3991/ijim.v14i17.16557


Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

mobile application in flood risk assessment could provide useful detailed infor-

mation for flood risk management, evacuation, communication. The decision 

support design from this study is perhaps to improve the warning system and 

contribute to reduction of casualties. 

Keywords—Flood Management, Flood Early Warning System, Decision Sup-

port System, Multi Attribute Decision Making. 

1 Introduction 

A flood is a natural event that can have far reaching effects on people and the envi-

ronment. Flood can be defined as relatively high stream flow, which overtops the nat-

ural or artificial banks in any part of a stream, river, estuary, lake or dam, and/or over-

land runoff before entering a watercourse and/or coastal inundation resulting from su-

per elevated sea levels and/or waves overtopping coastline defenses. Given the concepts 

of flooding that are being addressed, it is essential that the terminology used is con-

sistent and understood. Flood can be defined as a body of water, which rises to overflow 

land that is not normally submerged [1]. Types of flood in Malaysia are: monsoon flood, 

urban flash flood, debris flow and mud flow, landslide, tidal flood, dam release, and 

bund breach [2]. Generally, floods can be classified into two types, which are river 

floods and coastal floods with different characteristics as follow [3]: 

1.1 River floods 

Floods in river valleys occur mostly on floodplains or wash lands as a result of flow 

exceeding the capacity of the stream channels and over spilling the natural banks or 

artificial embankments. Mainstream Flood, inundation of normally dry land occurring 

when water overflows the natural or artificial banks of a stream, river, estuary, lake or 

dam [2]. Sometimes inundation of the floodplain, or of other flat areas, occurs in wet 

conditions when an already shallow water table rises above the level of the ground sur-

face. This type of water table flooding is often an immediate precursor of overspill 

flooding from the stream channels [3]. 

In very dry conditions, when the ground surface is baked hard or becomes crusted, 

extensive flat areas may be flooded by heavy rainfall ponding on the surface. This rain-

water flooding is typical of arid and semi-arid environments but is also experienced 

much more widely [3]. Also typical of arid and semi-arid areas is the situation where 

there are no clearly defined channels and where sheet wash flooding occurs by the un-

impeded lateral spread of water moving down a previously dry or near-dry valley bot-

tom or alluvial fan. 

In urban areas flooding often results from over spilling or surface ponding, as de-

scribed above, but may also occur when urban storm-water drains become surcharged 

and overflow. Storm water is resulting from runoff from a storm event. During rainfall 

event some water remains on the surface or is held in the soil or underground aquifer 

as ground water, a portion of the water is used directly by plants and the remainder 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

flows over the surface. This overland flow is called storm water. Local Overland Flood 

where inundation by local runoff rather than over bank discharge from a stream, river, 

estuary, lake or dam. 

1.2 Coastal flood 

Floods in low-lying coastal areas, including estuaries and deltas, involve the inunda-

tion of land by brackish or saline water. Brackish-water floods result when river water 

overspills embankments in coastal reaches as flow into the sea is impeded by high-tide 

conditions. Overspill is exacerbated when high-tide levels are increased above normal 

by storm-surge conditions or when large freshwater flood flows are moving down an 

estuary [3]. Direct inundation by saline water floods may occur when exceptionally 

large wind-generated waves are driven into semi-enclosed bays during severe storm or 

storm-surge conditions, or when so-called 'tidal waves', generated by tectonic activity, 

move into shallow coastal waters. 

2 Issues in Flood Management 

Generally, a flood is caused by a combination of heavy rainfall causing river or 

coastal to over flow from their banks, and can happen at any time of the year. Most 

river floods result directly or indirectly from climatologically events such as exces-

sively heavy and/or excessively prolonged rainfall. In cold-winter areas, where snow-

fall accumulates, substantial flooding usually occurs during the period of snowmelt and 

ice melt in spring and early summer, particularly when melt rates are high. River floods 

may also result when landslides fall directly into upstream lakes or reservoirs causing 

a sudden rise in water level, which overspills the outlet or dam. Coastal areas are also 

at risk from sea flooding, where coastal floods are usually caused by a combination of 

high tides and the elevated sea level and large waves associated with storm surges, 

which result from severe cyclonic weather systems and low atmospheric pressure. 

Incidences of floods in urban areas are on the rise. This is because in new townships, 

the total impervious areas are very high since the housing developers only have to com-

ply to an open space of 10%; the developers normally go for maximum built up areas 

to maximize land use. With respect to catchment runoff, an increase in area impervi-

ousness from zero to 40% would cut the time to peak discharge by about 50% and 

increase the discharge magnitude by about 90% [23]. Before urbanization, rainwater is 

intercepted by the vegetation, infiltrates into the ground and takes time to travel to the 

river, but now it is quickly collected from the roofs and other paved grounds and cana-

lized efficiently to public drains, which in turn rapidly brings it to the nearest river. 

Although floods are natural phenomena, the effects of rainfall resulting in excess water 

running into streams and rivers, uncontrolled development activities in watersheds and 

along river corridors and high sea level areas can increase the severity of floods. The 

high rate of sedimentation in the rivers can also lead to serious flooding.  

The annual costs incurred by the Malaysian Government in flood disaster prepared-

ness, rescue and relief operations, and post-flood rehabilitation of victims and public 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

utilities are substantial. While loss of life due to flooding in the peninsular is not as 

severe as in Bangladesh or elsewhere in the world, it is nevertheless significant. Flood 

damages are based on crudely estimated damage to crops and livestock, public struc-

tures and properties, and interrupted activities and rescue and relief. The damage figures 

shown are substantial and would be much higher if damage to private properties were 

included. The potential flood damage in large urban centre such as Kuala Lumpur can 

be high. As a result, the Government of Malaysia has designated the government de-

partment notably the Department of Irrigation and Drainage as well as agencies to ex-

ecute strategic decisions to reduce the impact and negative effect of floods.  

In our proposed work, we outlined three research questions as follows: (1) What are 

the criteria to prepare a flood hazard/risk map in Malaysia? (2) How to measure flood 

risk and map indexing for a specific area in Malaysia? (3) What are the requirements 

dimensions for Mobile Decision Support for Early Flood Warning System in Malaysia? 

3 Flood Early Warning System 

One of the remedial measures that have been carried out is the development of the 

flood warning system where the information system plays the major role to get the in-

formation from all the stations situated along the river bank, process the information 

and channel the information to the appropriate authority for further immediate response. 

Although the system is very reliable in transmitting flood information, but have gener-

ally little effect in reducing the problem. However, it is now understood that it is neither 

possible nor desirable to control floods completely. A geographic information system 

(GIS) is thus being increasingly recognized as the most effective approach to flood 

disaster management. It is for this reason that, the research on flood warning system 

utilizing GIS has been executed. This GIS will be integrated with mathematical model-

ling in the collection and processing of data and the development of applications that 

monitor and create a proper awareness of likely flood disasters and their impact. The 

changing trends and advancement of GIS technologies and mathematical modelling 

have enabled their application in a large number of scientific and technological re-

sources and skills developments to reduce flood disasters. These developments include 

their real-time applications in suitable early warning systems, preparedness and overall 

flood disaster management. The system emphasizes the estimation of flood plain as an 

aspect of flood disaster management, which was generally neglected in previous man-

agement plans in Malaysia. Expected flood inundation maps are then produced to form 

the basis of advance warnings of impending floods well before they actually occur. 

In the last few years, a large number of projects aimed at the development of stronger 

and "smarter" flood protection systems have been initiated around the world. All of 

them aim to solve flood control problems, and several by developing Flood Early Warn-

ing Systems (FEWS). Existing EWSs are mostly localized, custom-designed and using 

local computer resources. State-of-the-art flood early warning systems use meteorolog-

ical data, water levels and remote satellite monitoring data (optionally) as input sources 

[4-7]. However, in Malaysia the concept of FEWS is still new and there is a need to 

develop a better decision support system for the government agency and disseminate 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

the result to affected community in real time. This mission critical activity is vital in 

order to minimize the loss particularly in East Coast State in Malaysia during the mon-

soon season. 

4 Decision Support System 

Historically, DSS research began in the 1960s where the emphasis of the research-

es was more on conceptual aspects of decision making [8]. Later, a more refined deci-

sion support framework was developed which incorporated categories of management 

activities and descriptions of decision type [9]. These include management activities 

such as strategic planning, management control and operational control. The proposed 

framework is a combination of Antony’s management activities and Simon’s Model 

explanation of decision types, which comprises structured, unstructured and semi-struc-

tured. DSS usually being develop to solve Multi Attribute Decision Making (MADM) 

problem [10-12]. Example of MADM problem includes project selection, contractor 

selection, supplier selection, consultant selection, etc. [14-18]. According to [13], 

MADM problem involves the selection of the ‘best’ alternative from a pool of pre-

selected alternatives described in terms of their criteria.  

5 Mobile Decision Support System for FEWS 

Recent growth and advances in mobile computing and communication have revolu-

tionized the way we live and access information. Today we are able to receive and 

process a vast amount of real-time data and situational information on mobile devices 

in a manner that has not been witnessed previously. Mobile devices in general are port-

able devices that are able to communicate with each other using wireless networks, 

Internet, or other protocols [19]. They can be classified into different categories. Among 

these categories, smart-phones, PDAs and tablets are the most widely used devices to 

support mobile decision sup-port systems as well as being greatly popular with general 

users [20]. Smart phones enable the use of the Internet on the move and have introduced 

new perspectives on the use of mobile devices. Although traditional DSS is often ac-

commodated by desktop computers, [20] predicted that the blooming of mobile tech-

nology and mobile devices would bring a lot more opportunities for DSS. One of the 

main benefits that mobile technology offers to decision support systems is the ability to 

retrieve real-time information anywhere, anytime [21]. Mobile DSS provides a ubiqui-

tous working environment in situations that require high mobility. 

Research in Mobile DSS is growing since the introduction of smartphones such as 

Android and IOS device. However, limited study has been performed for FEWS using 

mobile device for the client side. Therefore, a location-based software is desirable to 

help the community combating the flood issue. Hence, we intend to conduct a require-

ment analysis in order to develop a framework for location-based decision support for 

FEWS in Malaysia. 

Figure 1 illustrates and example of risk mapping system in Japan [22]. This concep-

tual model of decision support has the potential to be deployed in a server. However, 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

the information needs to distributed to the community in order to minimize the losses. 

For example, in Malaysia, the information regarding the risk and mapping of each sec-

tor can be disseminate through mobile device which is similar to location-based appli-

cation such as Waze, Google Maps, Navigator, etc. 

 

Fig. 1. Conceptual Model of Flood Risk and Mapping [22] 

6 Research Methodology for Mobile Based Decision Support 

System 

The proposed research phases are as follows: 

Phase 1: Awareness of the problem 

The first phase research starts with the awareness of the problems. The literature 

review is the only activities in this phase. The output at this stage is the critical review 

of FEWS, and adaptive Requirement Engineering. 

Phase 2: Mobile based FEWS requirement analysis and design  

The second phase of the research concerns on the design aspect of mobile based 

FEWS. It involves a case study of requirement analysis which will perform an in-depth 

investigation of system requirements in terms of the ecosystem, user, technology and 

process modelling in flood monitoring for river Basin in Kelantan and Kubang Pasu in 

Kedah. Data collection techniques will involve documental analysis, interviews and 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

focus group discussion with experts from related government agencies. The case study 

will be used to justify the tentative architectural design for mobile based FEWS using 

Goal Requirement Analysis, computation of risk using Fuzzy TOPSIS and data mining, 

and mapping risks to locality on mobile application and its communication elements. 

Phase 3: The validation of mobile based FEWS 

The model will be tested and validate through case study to demonstrate the proposed 

approach. A tentative architectural design of mobile based decision support FEWS will 

be presented. Each sector or block will be associated with a risk value (that was previ-

ously been calculated based on Fuzzy TOPSIS and data mining) on the server side and 

they will be shared with user maps on the client side (mobile device). 

Phase 4: Deliverable and conclusions 

This is the final phase of the research where it will conclude and summarize the 

findings. Deliverables of this phase is the revised software specification of for mobile 

based decision support FEWS. Thus, this will directly address the main research aim.  

 

Fig. 2. Research Phases for Mobile based FEWS 

7 Discussion and Conclusion 

The annual costs incurred by the Malaysian Government in flood disaster prepared-

ness, rescue and relief operations, and post-flood rehabilitation of victims and public 

utilities are substantial. While loss of life due to flooding in the peninsular is not as 

severe as in Bangladesh or elsewhere in the world, it is nevertheless significant. Flood 

damages are based on crudely estimated damage to crops and livestock, public struc-

tures and properties, and interrupted activities and rescue and relief. The damage figures 

shown are substantial and would be much higher if damage to private properties were 

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Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

included. The potential flood damage in large urban centre such as Kuala Lumpur can 

be high [23]. As a result, the Government of Malaysia has designated the government 

department notably the Department of Irrigation and Drainage as well as agencies to 

execute strategic decisions to reduce the impact and negative effect of floods. 

One of the remedial measures that have been carried out is the development of the 

flood warning system where the Information System plays the major role to get the 

information from all the stations situated along the river bank, process the information 

and channel the information to the appropriate authority for further immediate response. 

Decision Support System is a type of Information System that support decision making 

and it has been applied to a wide range of applications [24-26]. DSS has the potential 

to support flood warning system with the combination of other technology such as GIS, 

A GIS is recognized as the most effective approach to flood disaster management. It 

is for this reason that, the research on flood warning system utilizing GIS has been 

executed. This GIS will be integrated with mathematical modelling in the collection 

and processing of data and the development of applications that monitor and create a 

proper awareness of likely flood disasters and their impact. The changing trends and 

advancement of GIS technologies and mathematical modelling have enabled their ap-

plication in a large number of scientific and technological resources and skills develop-

ments to reduce flood disasters. These developments include their real-time applica-

tions in suitable early warning systems, preparedness and overall flood disaster man-

agement. The system emphasizes the estimation of flood plain as an aspect of flood 

disaster management. Expected flood inundation maps are then produced to form the 

basis of advance warnings of impending floods well before they actually occur.  

In this paper, we have outlined our research approach to developed mobile based 

FEWS in Malaysia. Our future works will consist of document analysis, semi-structured 

interviews, system development, experimentation and usability evaluation. 

8 References 

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9 Authors 

Mohd Faizal Omar is a senior lecturer at Universiti Utara Malaysia and received 

his PhD from Science and Engineering Faculty, Queensland University of Technology, 

Brisbane, Australia. His research work mainly focus on developing analytical tool by 

using Artificial Intelligence and Operation Research; to wide area of applications such 

as R&D performance measurement, built environment, manufacturing, business man-

agement, etc. In addition, Faizal is currently attached with School of Quantitative Sci-

ences and Center for Testing, Measurement and Appraisal (CeTMA) as a Research Fel-

low. Email: faizal_omar@uum.edu.my 

Mohd Nasrun Mohd Nawi specializes in the area of integrated design and construc-

tion management. He holds a PhD the field of Construction Project Management from 

the University of Salford, UK. As an academician and a fully qualified Building Sur-

veyor, he has been active in research and consultation works relating to the areas of 

Industrialised (offsite) and Modern Method of Construction, Integrated Design Deliv-

ery Solution (i.e. Integrated Project Delivery, Lean Construction, Building Information 

Modelling), Sustainable (green) Construction, Life cycle costing & Value Manage-

ment, Building Performance (i.e. Energy Management and Audit) and Management of 

Technology. Besides being involved actively in various academic activities, he is also 

an active author with various publications especially in the area of Construction and 

Technology Management. Email: nasrun@uum.edu.my 

Jastini Mohd Jamil is a senior lecturer and researcher in Data Mining at School of 

Quantitative Sciences, Universiti Utara Malaysia. She received his Ph.D in Data Mining 

from University of Bradford in 2012. Her doctoral thesis work (Partial Least Squares 

Structural Equation Modelling with Incomplete Data: An Investigation of the impact of 

statistical and computational imputation methods) used models drawn from customer 

index satisfaction domains using structural equation modeling to compare statistical 

imputation methods and computational imputation methods. She also holds a Master of 

Computer Sciences with focused on data mining, rough sets and neural networks from 

Universiti Teknologi Malaysia, and a Bachelor degree in Information Technology (net-

working) with honours from Universiti Utara Malaysia. Her research interests are solv-

ing problems in diverse area using data mining, decision support system and statistical 

techniques. Her other interests include structural equation modeling, partial least 

squares, neural networks, rough sets, data pre-processing, handling missing data and 

forecasting. Email: jastini@uum.edu.my 

Ani Munirah Mohamad is a senior lecturer at the School of Law, and research 

fellow at Center for Testing, Measurement and Appraisal (CeTMA), Universiti Utara 

iJIM ‒ Vol. 14, No. 17, 2020 139

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https://doi.org/10.3991/ijim.v13i04.10547
faizal_omar@uum.edu.my
nasrun@uum.edu.my
mailto:jastini@uum.edu.my
mailto:jastini@uum.edu.my


Paper—Research Design of Mobile Based Decision Support for Early Flood Warning System 

 

Malaysia, Kedah, Malaysia. She holds a PhD in Law from Universiti Teknologi MARA 

Selangor, Malaysia, Chartered Islamic Finance Professional (CIFP) from INCEIF, 

Kuala Lumpur, Malaysia, and Master of Comparative Law (MCL), Bachelor of Law 

(Hons) (LLB) and Diploma in Shariah law and Practice (DSLP) from International Is-

lamic University Malaysia, Selangor, Malaysia. She frequently publishes in local and 

international journals in the area of cyber law and information technology law. Today, 

she is actively engaged in the research area of information and communication technol-

ogy laws. Email: animunirah@uum.edu.my 

Saslina Kamaruddin is a senior lecturer at the Faculty of Management & Econom-

ics, Universiti Pendidikan Sultan Idris. She obtained her Bachelor of Law & Commerce 

(Hons.) from the Management & Science University, her Master of Laws and, and her 

Ph.D. in Law from the University Teknologi MARA. Currently, she teaches Legal Re-

search Project, Employment Law, Business Law, and Securities Law and International 

Trade Law for undergraduate students. Her area of interest is the 

Anti-money laundering and Anti-terrorist financing laws, criminal law, and preven-

tion/countering of violent extremism related laws. She frequently publishes in local and 

international journals in the area of anti-money laundering laws and other areas of laws 

too. Email: saslina@fpe.upsi.edu.my 

Article submitted 2020-06-25. Resubmitted 2020-07-26. Final acceptance 2020-07-28. Final version pub-
lished as submitted by the authors. 

140 http://www.i-jim.org

mailto:animunirah@uum.edu.my
mailto:saslina@fpe.upsi.edu.my